modules/messages/src/lib.rs

// 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 <http://www.gnu.org/licenses/>.

//! 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::StoredMessageData;
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,
};

use crate::{
	inbound_lane::{InboundLane, InboundLaneStorage, ReceivalResult},
	outbound_lane::{OutboundLane, OutboundLaneStorage, ReceivalConfirmationResult},
};

use bp_messages::{
	source_chain::{
		LaneMessageVerifier, MessageDeliveryAndDispatchPayment, OnDeliveryConfirmed,
		OnMessageAccepted, RelayersRewards, SendMessageArtifacts, TargetHeaderChain,
	},
	target_chain::{
		DispatchMessage, MessageDispatch, ProvedLaneMessages, ProvedMessages, SourceHeaderChain,
	},
	total_unrewarded_messages, DeliveredMessages, InboundLaneData, InboundMessageDetails, LaneId,
	MessageData, MessageKey, MessageNonce, MessagePayload, MessagesOperatingMode, OutboundLaneData,
	OutboundMessageDetails, Parameter as MessagesParameter, UnrewardedRelayer,
	UnrewardedRelayersState,
};
use bp_runtime::{BasicOperatingMode, ChainId, OwnedBridgeModule, Size};
use codec::{Decode, Encode, MaxEncodedLen};
use frame_support::{
	ensure, fail,
	traits::Get,
	weights::{Pays, PostDispatchInfo},
};
use num_traits::{SaturatingAdd, Zero};
use sp_core::H256;
use sp_runtime::traits::Convert;
use sp_std::{
	cell::RefCell, cmp::PartialOrd, collections::vec_deque::VecDeque, marker::PhantomData,
	ops::RangeInclusive, 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.
const LOG_TARGET: &str = "runtime::bridge-messages";

#[frame_support::pallet]
pub mod pallet {
	use super::*;
	use frame_support::pallet_prelude::*;
	use frame_system::pallet_prelude::*;

	#[pallet::config]
	pub trait Config<I: 'static = ()>: frame_system::Config {
		// General types

		/// The overarching event type.
		type Event: From<Event<Self, I>> + IsType<<Self as frame_system::Config>::Event>;
		/// Benchmarks results from runtime we're plugged into.
		type WeightInfo: WeightInfoExt;

		/// Gets the chain id value from the instance.
		#[pallet::constant]
		type BridgedChainId: Get<ChainId>;
		/// Pallet parameter that is opaque to the pallet itself, but may be used by the runtime
		/// for integrating the pallet.
		///
		/// All pallet parameters may only be updated either by the root, or by the pallet owner.
		type Parameter: MessagesParameter;

		/// Maximal number of messages that may be pruned during maintenance. Maintenance occurs
		/// whenever new message is sent. The reason is that if you want to use lane, you should
		/// be ready to pay for its maintenance.
		type MaxMessagesToPruneAtOnce: Get<MessageNonce>;
		/// 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<MessageNonce>;
		/// 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<MessageNonce>;

		/// Maximal size of the outbound payload.
		#[pallet::constant]
		type MaximalOutboundPayloadSize: Get<u32>;
		/// Payload type of outbound messages. This payload is dispatched on the bridged chain.
		type OutboundPayload: Parameter + Size;
		/// Message fee type of outbound messages. This fee is paid on this chain.
		type OutboundMessageFee: Default
			+ From<u64>
			+ PartialOrd
			+ Parameter
			+ SaturatingAdd
			+ Zero
			+ Copy
			+ MaxEncodedLen;

		/// Payload type of inbound messages. This payload is dispatched on this chain.
		type InboundPayload: Decode;
		/// Message fee type of inbound messages. This fee is paid on the bridged chain.
		type InboundMessageFee: Decode + Zero;
		/// Identifier of relayer that deliver messages to this chain. Relayer reward is paid on the
		/// bridged chain.
		type InboundRelayer: Parameter + MaxEncodedLen;

		/// A type which can be turned into an AccountId from a 256-bit hash.
		///
		/// Used when deriving the shared relayer fund account.
		type AccountIdConverter: sp_runtime::traits::Convert<sp_core::hash::H256, Self::AccountId>;

		// Types that are used by outbound_lane (on source chain).

		/// Target header chain.
		type TargetHeaderChain: TargetHeaderChain<Self::OutboundPayload, Self::AccountId>;
		/// Message payload verifier.
		type LaneMessageVerifier: LaneMessageVerifier<
			Self::Origin,
			Self::AccountId,
			Self::OutboundPayload,
			Self::OutboundMessageFee,
		>;
		/// Message delivery payment.
		type MessageDeliveryAndDispatchPayment: MessageDeliveryAndDispatchPayment<
			Self::Origin,
			Self::AccountId,
			Self::OutboundMessageFee,
		>;
		/// Handler for accepted messages.
		type OnMessageAccepted: OnMessageAccepted;
		/// Handler for delivered messages.
		type OnDeliveryConfirmed: OnDeliveryConfirmed;

		// Types that are used by inbound_lane (on target chain).

		/// Source header chain, as it is represented on target chain.
		type SourceHeaderChain: SourceHeaderChain<Self::InboundMessageFee>;
		/// Message dispatch.
		type MessageDispatch: MessageDispatch<
			Self::AccountId,
			Self::InboundMessageFee,
			DispatchPayload = Self::InboundPayload,
		>;
	}

	/// Shortcut to messages proof type for Config.
	type MessagesProofOf<T, I> = <<T as Config<I>>::SourceHeaderChain as SourceHeaderChain<
		<T as Config<I>>::InboundMessageFee,
	>>::MessagesProof;
	/// Shortcut to messages delivery proof type for Config.
	type MessagesDeliveryProofOf<T, I> =
		<<T as Config<I>>::TargetHeaderChain as TargetHeaderChain<
			<T as Config<I>>::OutboundPayload,
			<T as frame_system::Config>::AccountId,
		>>::MessagesDeliveryProof;

	#[pallet::pallet]
	#[pallet::generate_store(pub(super) trait Store)]
	pub struct Pallet<T, I = ()>(PhantomData<(T, I)>);

	impl<T: Config<I>, I: 'static> OwnedBridgeModule<T> for Pallet<T, I> {
		const LOG_TARGET: &'static str = LOG_TARGET;
		type OwnerStorage = PalletOwner<T, I>;
		type OperatingMode = MessagesOperatingMode;
		type OperatingModeStorage = PalletOperatingMode<T, I>;
	}

	#[pallet::call]
	impl<T: Config<I>, I: 'static> Pallet<T, I> {
		/// Change `PalletOwner`.
		///
		/// May only be called either by root, or by `PalletOwner`.
		#[pallet::weight((T::DbWeight::get().reads_writes(1, 1), DispatchClass::Operational))]
		pub fn set_owner(origin: OriginFor<T>, new_owner: Option<T::AccountId>) -> DispatchResult {
			<Self as OwnedBridgeModule<_>>::set_owner(origin, new_owner)
		}

		/// Halt or resume all/some pallet operations.
		///
		/// May only be called either by root, or by `PalletOwner`.
		#[pallet::weight((T::DbWeight::get().reads_writes(1, 1), DispatchClass::Operational))]
		pub fn set_operating_mode(
			origin: OriginFor<T>,
			operating_mode: MessagesOperatingMode,
		) -> DispatchResult {
			<Self as OwnedBridgeModule<_>>::set_operating_mode(origin, operating_mode)
		}

		/// Update pallet parameter.
		///
		/// May only be called either by root, or by `PalletOwner`.
		///
		/// The weight is: single read for permissions check + 2 writes for parameter value and
		/// event.
		#[pallet::weight((T::DbWeight::get().reads_writes(1, 2), DispatchClass::Operational))]
		pub fn update_pallet_parameter(
			origin: OriginFor<T>,
			parameter: T::Parameter,
		) -> DispatchResult {
			Self::ensure_owner_or_root(origin)?;
			parameter.save();
			Self::deposit_event(Event::ParameterUpdated { parameter });
			Ok(())
		}

		/// Send message over lane.
		#[pallet::weight(T::WeightInfo::send_message_weight(payload, T::DbWeight::get()))]
		pub fn send_message(
			origin: OriginFor<T>,
			lane_id: LaneId,
			payload: T::OutboundPayload,
			delivery_and_dispatch_fee: T::OutboundMessageFee,
		) -> DispatchResultWithPostInfo {
			crate::send_message::<T, I>(origin, lane_id, payload, delivery_and_dispatch_fee).map(
				|sent_message| PostDispatchInfo {
					actual_weight: Some(sent_message.weight),
					pays_fee: Pays::Yes,
				},
			)
		}

		/// Pay additional fee for the message.
		#[pallet::weight(T::WeightInfo::maximal_increase_message_fee())]
		pub fn increase_message_fee(
			origin: OriginFor<T>,
			lane_id: LaneId,
			nonce: MessageNonce,
			additional_fee: T::OutboundMessageFee,
		) -> DispatchResultWithPostInfo {
			Self::ensure_not_halted().map_err(Error::<T, I>::BridgeModule)?;
			// if someone tries to pay for already-delivered message, we're rejecting this intention
			// (otherwise this additional fee will be locked forever in relayers fund)
			//
			// if someone tries to pay for not-yet-sent message, we're rejecting this intention, or
			// we're risking to have mess in the storage
			let lane = outbound_lane::<T, I>(lane_id);
			ensure!(
				nonce > lane.data().latest_received_nonce,
				Error::<T, I>::MessageIsAlreadyDelivered
			);
			ensure!(
				nonce <= lane.data().latest_generated_nonce,
				Error::<T, I>::MessageIsNotYetSent
			);

			// withdraw additional fee from submitter
			T::MessageDeliveryAndDispatchPayment::pay_delivery_and_dispatch_fee(
				&origin,
				&additional_fee,
				&relayer_fund_account_id::<T::AccountId, T::AccountIdConverter>(),
			)
			.map_err(|err| {
				log::trace!(
					target: LOG_TARGET,
					"Submitter can't pay additional fee {:?} for the message {:?}/{:?} to {:?}: {:?}",
					additional_fee,
					lane_id,
					nonce,
					relayer_fund_account_id::<T::AccountId, T::AccountIdConverter>(),
					err,
				);

				Error::<T, I>::FailedToWithdrawMessageFee
			})?;

			// and finally update fee in the storage
			let message_key = MessageKey { lane_id, nonce };
			let message_size = OutboundMessages::<T, I>::mutate(message_key, |message_data| {
				// saturating_add is fine here - overflow here means that someone controls all
				// chain funds, which shouldn't ever happen + `pay_delivery_and_dispatch_fee`
				// above will fail before we reach here
				let message_data = message_data.as_mut().expect(
					"the message is sent and not yet delivered; so it is in the storage; qed",
				);
				message_data.fee = message_data.fee.saturating_add(&additional_fee);
				message_data.payload.len()
			});

			// compute actual dispatch weight that depends on the stored message size
			let actual_weight = sp_std::cmp::min(
				T::WeightInfo::maximal_increase_message_fee(),
				T::WeightInfo::increase_message_fee(message_size as _),
			);

			Ok(PostDispatchInfo { actual_weight: Some(actual_weight), pays_fee: Pays::Yes })
		}

		/// 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.
		#[pallet::weight(T::WeightInfo::receive_messages_proof_weight(proof, *messages_count, *dispatch_weight))]
		pub fn receive_messages_proof(
			origin: OriginFor<T>,
			relayer_id_at_bridged_chain: T::InboundRelayer,
			proof: MessagesProofOf<T, I>,
			messages_count: u32,
			dispatch_weight: Weight,
		) -> DispatchResultWithPostInfo {
			Self::ensure_not_halted().map_err(Error::<T, I>::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::<T, I>::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::InboundMessageFee,
				T::InboundPayload,
			>(proof, messages_count)
			.map_err(|err| {
				log::trace!(target: LOG_TARGET, "Rejecting invalid messages proof: {:?}", err,);

				Error::<T, I>::InvalidMessagesProof
			})?;

			// dispatch messages and (optionally) update lane(s) state(s)
			let mut total_messages = 0;
			let mut valid_messages = 0;
			let mut dispatch_weight_left = dispatch_weight;
			for (lane_id, lane_data) in messages {
				let mut lane = inbound_lane::<T, I>(lane_id);

				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,
						);
					}
				}

				for mut message in lane_data.messages {
					debug_assert_eq!(message.key.lane_id, lane_id);

					// 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 dispatch_weight = T::MessageDispatch::dispatch_weight(&mut message);
					if dispatch_weight > dispatch_weight_left {
						log::trace!(
							target: LOG_TARGET,
							"Cannot dispatch any more messages on lane {:?}. Weight: declared={}, left={}",
							lane_id,
							dispatch_weight,
							dispatch_weight_left,
						);
						break
					}
					total_messages += 1;

					let receival_result = lane.receive_message::<T::MessageDispatch, T::AccountId>(
						&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, refund_pay_dispatch_fee) = match receival_result {
						ReceivalResult::Dispatched(dispatch_result) => {
							valid_messages += 1;
							(
								dispatch_result.unspent_weight,
								!dispatch_result.dispatch_fee_paid_during_dispatch,
							)
						},
						ReceivalResult::InvalidNonce |
						ReceivalResult::TooManyUnrewardedRelayers |
						ReceivalResult::TooManyUnconfirmedMessages => (dispatch_weight, true),
					};

					let unspent_weight = sp_std::cmp::min(unspent_weight, dispatch_weight);
					dispatch_weight_left -= dispatch_weight - unspent_weight;
					actual_weight = actual_weight.saturating_sub(unspent_weight).saturating_sub(
						// delivery call weight formula assumes that the fee is paid at
						// this (target) chain. If the message is prepaid at the source
						// chain, let's refund relayer with this extra cost.
						if refund_pay_dispatch_fee {
							T::WeightInfo::pay_inbound_dispatch_fee_overhead()
						} else {
							0
						},
					);
				}
			}

			log::trace!(
				target: LOG_TARGET,
				"Received messages: total={}, valid={}. Weight used: {}/{}",
				total_messages,
				valid_messages,
				actual_weight,
				declared_weight,
			);

			Ok(PostDispatchInfo { actual_weight: Some(actual_weight), pays_fee: Pays::Yes })
		}

		/// Receive messages delivery proof from bridged chain.
		#[pallet::weight(T::WeightInfo::receive_messages_delivery_proof_weight(
			proof,
			relayers_state,
			T::DbWeight::get(),
		))]
		pub fn receive_messages_delivery_proof(
			origin: OriginFor<T>,
			proof: MessagesDeliveryProofOf<T, I>,
			relayers_state: UnrewardedRelayersState,
		) -> DispatchResultWithPostInfo {
			Self::ensure_not_halted().map_err(Error::<T, I>::BridgeModule)?;

			// why do we need to know the weight of this (`receive_messages_delivery_proof`) call?
			// Because we may want to return some funds for messages that are not processed by the
			// delivery callback, or if their actual processing weight is less than accounted by
			// weight formula. So to refund relayer, we need to:
			//
			// ActualWeight = DeclaredWeight - UnspentCallbackWeight
			//
			// 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 single_message_callback_overhead =
				T::WeightInfo::single_message_callback_overhead(T::DbWeight::get());
			let declared_weight = T::WeightInfo::receive_messages_delivery_proof_weight(
				&proof,
				&relayers_state,
				T::DbWeight::get(),
			);
			let mut actual_weight = declared_weight;

			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::<T, I>::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::<T, I>::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::<T, I>::InvalidUnrewardedRelayersState
			);

			// mark messages as delivered
			let mut lane = outbound_lane::<T, I>(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::<T, I>::TryingToConfirmMoreMessagesThanExpected);
				},
				error => {
					log::trace!(
						target: LOG_TARGET,
						"Messages delivery proof contains invalid unrewarded relayers vec: {:?}",
						error,
					);

					fail!(Error::<T, I>::InvalidUnrewardedRelayers);
				},
			};

			if let Some(confirmed_messages) = confirmed_messages {
				// handle messages delivery confirmation
				let preliminary_callback_overhead =
					relayers_state.total_messages.saturating_mul(single_message_callback_overhead);
				let actual_callback_weight =
					T::OnDeliveryConfirmed::on_messages_delivered(&lane_id, &confirmed_messages);
				match preliminary_callback_overhead.checked_sub(actual_callback_weight) {
					Some(difference) if difference == 0 => (),
					Some(difference) => {
						log::trace!(
							target: LOG_TARGET,
							"T::OnDeliveryConfirmed callback has spent less weight than expected. Refunding: \
							{} - {} = {}",
							preliminary_callback_overhead,
							actual_callback_weight,
							difference,
						);
						actual_weight = actual_weight.saturating_sub(difference);
					},
					None => {
						debug_assert!(
							false,
							"T::OnDeliveryConfirmed callback consumed too much weight."
						);
						log::error!(
							target: LOG_TARGET,
							"T::OnDeliveryConfirmed callback has spent more weight that it is allowed to: \
							{} vs {}",
							preliminary_callback_overhead,
							actual_callback_weight,
						);
					},
				}

				// 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 relayer_fund_account =
					relayer_fund_account_id::<T::AccountId, T::AccountIdConverter>();
				<T as Config<I>>::MessageDeliveryAndDispatchPayment::pay_relayers_rewards(
					lane_id,
					lane_data.relayers,
					&confirmation_relayer,
					&received_range,
					&relayer_fund_account,
				);
			}

			log::trace!(
				target: LOG_TARGET,
				"Received messages delivery proof up to (and including) {} at lane {:?}",
				last_delivered_nonce,
				lane_id,
			);

			Ok(PostDispatchInfo { actual_weight: Some(actual_weight), pays_fee: Pays::Yes })
		}
	}

	#[pallet::event]
	#[pallet::generate_deposit(pub(super) fn deposit_event)]
	pub enum Event<T: Config<I>, I: 'static = ()> {
		/// Pallet parameter has been updated.
		ParameterUpdated { parameter: T::Parameter },
		/// Message has been accepted and is waiting to be delivered.
		MessageAccepted { lane_id: LaneId, nonce: MessageNonce },
		/// Messages in the inclusive range have been delivered to the bridged chain.
		MessagesDelivered { lane_id: LaneId, messages: DeliveredMessages },
	}

	#[pallet::error]
	pub enum Error<T, I = ()> {
		/// Pallet is not in Normal operating mode.
		NotOperatingNormally,
		/// 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 message someone is trying to work with (i.e. increase fee) is already-delivered.
		MessageIsAlreadyDelivered,
		/// 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<T: Config<I>, 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<T: Config<I>, I: 'static = ()> =
		StorageValue<_, MessagesOperatingMode, ValueQuery>;

	/// Map of lane id => inbound lane data.
	#[pallet::storage]
	pub type InboundLanes<T: Config<I>, I: 'static = ()> =
		StorageMap<_, Blake2_128Concat, LaneId, StoredInboundLaneData<T, I>, ValueQuery>;

	/// Map of lane id => outbound lane data.
	#[pallet::storage]
	pub type OutboundLanes<T: Config<I>, I: 'static = ()> =
		StorageMap<_, Blake2_128Concat, LaneId, OutboundLaneData, ValueQuery>;

	/// All queued outbound messages.
	#[pallet::storage]
	pub type OutboundMessages<T: Config<I>, I: 'static = ()> =
		StorageMap<_, Blake2_128Concat, MessageKey, StoredMessageData<T, I>>;

	#[pallet::genesis_config]
	pub struct GenesisConfig<T: Config<I>, I: 'static = ()> {
		/// Initial pallet operating mode.
		pub operating_mode: MessagesOperatingMode,
		/// Initial pallet owner.
		pub owner: Option<T::AccountId>,
		/// Dummy marker.
		pub phantom: sp_std::marker::PhantomData<I>,
	}

	#[cfg(feature = "std")]
	impl<T: Config<I>, I: 'static> Default for GenesisConfig<T, I> {
		fn default() -> Self {
			Self {
				operating_mode: Default::default(),
				owner: Default::default(),
				phantom: Default::default(),
			}
		}
	}

	#[pallet::genesis_build]
	impl<T: Config<I>, I: 'static> GenesisBuild<T, I> for GenesisConfig<T, I> {
		fn build(&self) {
			PalletOperatingMode::<T, I>::put(&self.operating_mode);
			if let Some(ref owner) = self.owner {
				PalletOwner::<T, I>::put(owner);
			}
		}
	}

	impl<T: Config<I>, I: 'static> Pallet<T, I> {
		/// Get stored data of the outbound message with given nonce.
		pub fn outbound_message_data(
			lane: LaneId,
			nonce: MessageNonce,
		) -> Option<MessageData<T::OutboundMessageFee>> {
			OutboundMessages::<T, I>::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<T::InboundMessageFee>,
		) -> InboundMessageDetails {
			let mut dispatch_message = DispatchMessage {
				key: MessageKey { lane_id: lane, nonce: outbound_details.nonce },
				data: MessageData { payload, fee: outbound_details.delivery_and_dispatch_fee }
					.into(),
			};
			InboundMessageDetails {
				dispatch_weight: T::MessageDispatch::dispatch_weight(&mut dispatch_message),
			}
		}
	}
}

/// AccountId of the shared relayer fund account.
///
/// This account is passed to `MessageDeliveryAndDispatchPayment` trait, and depending
/// on the implementation it can be used to store relayers rewards.
pub fn relayer_fund_account_id<AccountId, AccountIdConverter: Convert<H256, AccountId>>(
) -> AccountId {
	let encoded_id = bp_runtime::derive_relayer_fund_account_id(bp_runtime::NO_INSTANCE_ID);
	AccountIdConverter::convert(encoded_id)
}

impl<T, I>
	bp_messages::source_chain::MessagesBridge<
		T::Origin,
		T::AccountId,
		T::OutboundMessageFee,
		T::OutboundPayload,
	> for Pallet<T, I>
where
	T: Config<I>,
	I: 'static,
{
	type Error = sp_runtime::DispatchErrorWithPostInfo<PostDispatchInfo>;

	fn send_message(
		sender: T::Origin,
		lane: LaneId,
		message: T::OutboundPayload,
		delivery_and_dispatch_fee: T::OutboundMessageFee,
	) -> Result<SendMessageArtifacts, Self::Error> {
		crate::send_message::<T, I>(sender, lane, message, delivery_and_dispatch_fee)
	}
}

/// Function that actually sends message.
fn send_message<T: Config<I>, I: 'static>(
	submitter: T::Origin,
	lane_id: LaneId,
	payload: T::OutboundPayload,
	delivery_and_dispatch_fee: T::OutboundMessageFee,
) -> sp_std::result::Result<
	SendMessageArtifacts,
	sp_runtime::DispatchErrorWithPostInfo<PostDispatchInfo>,
> {
	ensure_normal_operating_mode::<T, I>()?;

	// the most lightweigh check is the message size check
	ensure!(
		payload.size() < T::MaximalOutboundPayloadSize::get(),
		Error::<T, I>::MessageIsTooLarge,
	);

	// initially, actual (post-dispatch) weight is equal to pre-dispatch weight
	let mut actual_weight = T::WeightInfo::send_message_weight(&payload, T::DbWeight::get());

	// let's first check if message can be delivered to target chain
	T::TargetHeaderChain::verify_message(&payload).map_err(|err| {
		log::trace!(
			target: LOG_TARGET,
			"Message to lane {:?} is rejected by target chain: {:?}",
			lane_id,
			err,
		);

		Error::<T, I>::MessageRejectedByChainVerifier
	})?;

	// now let's enforce any additional lane rules
	let mut lane = outbound_lane::<T, I>(lane_id);
	T::LaneMessageVerifier::verify_message(
		&submitter,
		&delivery_and_dispatch_fee,
		&lane_id,
		&lane.data(),
		&payload,
	)
	.map_err(|err| {
		log::trace!(
			target: LOG_TARGET,
			"Message to lane {:?} is rejected by lane verifier: {:?}",
			lane_id,
			err,
		);

		Error::<T, I>::MessageRejectedByLaneVerifier
	})?;

	// let's withdraw delivery and dispatch fee from submitter
	T::MessageDeliveryAndDispatchPayment::pay_delivery_and_dispatch_fee(
		&submitter,
		&delivery_and_dispatch_fee,
		&relayer_fund_account_id::<T::AccountId, T::AccountIdConverter>(),
	)
	.map_err(|err| {
		log::trace!(
			target: LOG_TARGET,
			"Message to lane {:?} is rejected because submitter is unable to pay fee {:?}: {:?}",
			lane_id,
			delivery_and_dispatch_fee,
			err,
		);

		Error::<T, I>::FailedToWithdrawMessageFee
	})?;

	// finally, save message in outbound storage and emit event
	let encoded_payload = payload.encode();
	let encoded_payload_len = encoded_payload.len();
	let nonce =
		lane.send_message(MessageData { payload: encoded_payload, fee: delivery_and_dispatch_fee });
	// Guaranteed to be called outside only when the message is accepted.
	// We assume that the maximum weight call back used is `single_message_callback_overhead`, so do
	// not perform complex db operation in callback. If you want to, put these magic logic in
	// outside pallet and control the weight there.
	let single_message_callback_overhead =
		T::WeightInfo::single_message_callback_overhead(T::DbWeight::get());
	let actual_callback_weight = T::OnMessageAccepted::on_messages_accepted(&lane_id, &nonce);
	match single_message_callback_overhead.checked_sub(actual_callback_weight) {
		Some(difference) if difference == 0 => (),
		Some(difference) => {
			log::trace!(
				target: LOG_TARGET,
				"T::OnMessageAccepted callback has spent less weight than expected. Refunding: \
				{} - {} = {}",
				single_message_callback_overhead,
				actual_callback_weight,
				difference,
			);
			actual_weight = actual_weight.saturating_sub(difference);
		},
		None => {
			debug_assert!(false, "T::OnMessageAccepted callback consumed too much weight.");
			log::error!(
				target: LOG_TARGET,
				"T::OnMessageAccepted callback has spent more weight that it is allowed to: \
				{} vs {}",
				single_message_callback_overhead,
				actual_callback_weight,
			);
		},
	}

	// message sender pays for pruning at most `MaxMessagesToPruneAtOnce` messages
	// the cost of pruning every message is roughly single db write
	// => lets refund sender if less than `MaxMessagesToPruneAtOnce` messages pruned
	let max_messages_to_prune = T::MaxMessagesToPruneAtOnce::get();
	let pruned_messages = lane.prune_messages(max_messages_to_prune);
	if let Some(extra_messages) = max_messages_to_prune.checked_sub(pruned_messages) {
		actual_weight = actual_weight.saturating_sub(T::DbWeight::get().writes(extra_messages));
	}

	log::trace!(
		target: LOG_TARGET,
		"Accepted message {} to lane {:?}. Message size: {:?}",
		nonce,
		lane_id,
		encoded_payload_len,
	);

	Pallet::<T, I>::deposit_event(Event::MessageAccepted { lane_id, nonce });

	Ok(SendMessageArtifacts { nonce, weight: actual_weight })
}

/// Calculate the relayers rewards
pub fn calc_relayers_rewards<T, I>(
	lane_id: LaneId,
	messages_relayers: VecDeque<UnrewardedRelayer<T::AccountId>>,
	received_range: &RangeInclusive<MessageNonce>,
) -> RelayersRewards<T::AccountId, T::OutboundMessageFee>
where
	T: frame_system::Config + crate::Config<I>,
	I: 'static,
{
	// remember to reward relayers that have delivered messages
	// this loop is bounded by `T::MaxUnrewardedRelayerEntriesAtInboundLane` on the bridged chain
	let mut relayers_rewards: RelayersRewards<_, T::OutboundMessageFee> = RelayersRewards::new();
	for entry in messages_relayers {
		let nonce_begin = sp_std::cmp::max(entry.messages.begin, *received_range.start());
		let nonce_end = sp_std::cmp::min(entry.messages.end, *received_range.end());

		// loop won't proceed if current entry is ahead of received range (begin > end).
		// this loop is bound by `T::MaxUnconfirmedMessagesAtInboundLane` on the bridged chain
		let mut relayer_reward = relayers_rewards.entry(entry.relayer).or_default();
		for nonce in nonce_begin..nonce_end + 1 {
			let key = MessageKey { lane_id, nonce };
			let message_data = OutboundMessages::<T, I>::get(key)
				.expect("message was just confirmed; we never prune unconfirmed messages; qed");
			relayer_reward.reward = relayer_reward.reward.saturating_add(&message_data.fee);
			relayer_reward.messages += 1;
		}
	}
	relayers_rewards
}

/// Ensure that the pallet is in normal operational mode.
fn ensure_normal_operating_mode<T: Config<I>, I: 'static>() -> Result<(), Error<T, I>> {
	if PalletOperatingMode::<T, I>::get() ==
		MessagesOperatingMode::Basic(BasicOperatingMode::Normal)
	{
		return Ok(())
	}

	Err(Error::<T, I>::NotOperatingNormally)
}

/// Creates new inbound lane object, backed by runtime storage.
fn inbound_lane<T: Config<I>, I: 'static>(
	lane_id: LaneId,
) -> InboundLane<RuntimeInboundLaneStorage<T, I>> {
	InboundLane::new(inbound_lane_storage::<T, I>(lane_id))
}

/// Creates new runtime inbound lane storage.
fn inbound_lane_storage<T: Config<I>, I: 'static>(
	lane_id: LaneId,
) -> RuntimeInboundLaneStorage<T, I> {
	RuntimeInboundLaneStorage {
		lane_id,
		cached_data: RefCell::new(None),
		_phantom: Default::default(),
	}
}

/// Creates new outbound lane object, backed by runtime storage.
fn outbound_lane<T: Config<I>, I: 'static>(
	lane_id: LaneId,
) -> OutboundLane<RuntimeOutboundLaneStorage<T, I>> {
	OutboundLane::new(RuntimeOutboundLaneStorage { lane_id, _phantom: Default::default() })
}

/// Runtime inbound lane storage.
struct RuntimeInboundLaneStorage<T: Config<I>, I: 'static = ()> {
	lane_id: LaneId,
	cached_data: RefCell<Option<InboundLaneData<T::InboundRelayer>>>,
	_phantom: PhantomData<I>,
}

impl<T: Config<I>, I: 'static> InboundLaneStorage for RuntimeInboundLaneStorage<T, I> {
	type MessageFee = T::InboundMessageFee;
	type Relayer = T::InboundRelayer;

	fn id(&self) -> LaneId {
		self.lane_id
	}

	fn max_unrewarded_relayer_entries(&self) -> MessageNonce {
		T::MaxUnrewardedRelayerEntriesAtInboundLane::get()
	}

	fn max_unconfirmed_messages(&self) -> MessageNonce {
		T::MaxUnconfirmedMessagesAtInboundLane::get()
	}

	fn data(&self) -> InboundLaneData<T::InboundRelayer> {
		match self.cached_data.clone().into_inner() {
			Some(data) => data,
			None => {
				let data: InboundLaneData<T::InboundRelayer> =
					InboundLanes::<T, I>::get(&self.lane_id).into();
				*self.cached_data.try_borrow_mut().expect(
					"we're in the single-threaded environment;\
						we have no recursive borrows; qed",
				) = Some(data.clone());
				data
			},
		}
	}

	fn set_data(&mut self, data: InboundLaneData<T::InboundRelayer>) {
		*self.cached_data.try_borrow_mut().expect(
			"we're in the single-threaded environment;\
				we have no recursive borrows; qed",
		) = Some(data.clone());
		InboundLanes::<T, I>::insert(&self.lane_id, StoredInboundLaneData::<T, I>(data))
	}
}

/// Runtime outbound lane storage.
struct RuntimeOutboundLaneStorage<T, I = ()> {
	lane_id: LaneId,
	_phantom: PhantomData<(T, I)>,
}

impl<T: Config<I>, I: 'static> OutboundLaneStorage for RuntimeOutboundLaneStorage<T, I> {
	type MessageFee = T::OutboundMessageFee;

	fn id(&self) -> LaneId {
		self.lane_id
	}

	fn data(&self) -> OutboundLaneData {
		OutboundLanes::<T, I>::get(&self.lane_id)
	}

	fn set_data(&mut self, data: OutboundLaneData) {
		OutboundLanes::<T, I>::insert(&self.lane_id, data)
	}

	#[cfg(test)]
	fn message(&self, nonce: &MessageNonce) -> Option<MessageData<T::OutboundMessageFee>> {
		OutboundMessages::<T, I>::get(MessageKey { lane_id: self.lane_id, nonce: *nonce })
			.map(Into::into)
	}

	fn save_message(
		&mut self,
		nonce: MessageNonce,
		mesage_data: MessageData<T::OutboundMessageFee>,
	) {
		OutboundMessages::<T, I>::insert(MessageKey { lane_id: self.lane_id, nonce }, mesage_data);
	}

	fn remove_message(&mut self, nonce: &MessageNonce) {
		OutboundMessages::<T, I>::remove(MessageKey { lane_id: self.lane_id, nonce: *nonce });
	}
}

/// Verify messages proof and return proved messages with decoded payload.
fn verify_and_decode_messages_proof<Chain: SourceHeaderChain<Fee>, Fee, DispatchPayload: Decode>(
	proof: Chain::MessagesProof,
	messages_count: u32,
) -> Result<ProvedMessages<DispatchMessage<DispatchPayload, Fee>>, Chain::Error> {
	// `receive_messages_proof` weight formula and `MaxUnconfirmedMessagesAtInboundLane` check
	// guarantees that the `message_count` is sane and Vec<Message> may be allocated.
	// (tx with too many messages will either be rejected from the pool, or will fail earlier)
	Chain::verify_messages_proof(proof, messages_count).map(|messages_by_lane| {
		messages_by_lane
			.into_iter()
			.map(|(lane, lane_data)| {
				(
					lane,
					ProvedLaneMessages {
						lane_state: lane_data.lane_state,
						messages: lane_data.messages.into_iter().map(Into::into).collect(),
					},
				)
			})
			.collect()
	})
}

#[cfg(test)]
mod tests {
	use super::*;
	use crate::mock::{
		message, message_payload, run_test, unrewarded_relayer, Event as TestEvent, Origin,
		TestMessageDeliveryAndDispatchPayment, TestMessagesDeliveryProof, TestMessagesParameter,
		TestMessagesProof, TestOnDeliveryConfirmed1, TestOnDeliveryConfirmed2,
		TestOnMessageAccepted, TestRuntime, TokenConversionRate, MAX_OUTBOUND_PAYLOAD_SIZE,
		PAYLOAD_REJECTED_BY_TARGET_CHAIN, REGULAR_PAYLOAD, TEST_LANE_ID, TEST_RELAYER_A,
		TEST_RELAYER_B,
	};
	use bp_messages::{UnrewardedRelayer, UnrewardedRelayersState};
	use bp_test_utils::generate_owned_bridge_module_tests;
	use frame_support::{
		assert_noop, assert_ok,
		storage::generator::{StorageMap, StorageValue},
		weights::Weight,
	};
	use frame_system::{EventRecord, Pallet as System, Phase};
	use sp_runtime::DispatchError;

	fn get_ready_for_events() {
		System::<TestRuntime>::set_block_number(1);
		System::<TestRuntime>::reset_events();
	}

	fn inbound_unrewarded_relayers_state(
		lane: bp_messages::LaneId,
	) -> bp_messages::UnrewardedRelayersState {
		let inbound_lane_data = InboundLanes::<TestRuntime, ()>::get(&lane).0;
		let last_delivered_nonce = inbound_lane_data.last_delivered_nonce();
		let relayers = inbound_lane_data.relayers;
		bp_messages::UnrewardedRelayersState {
			unrewarded_relayer_entries: relayers.len() as _,
			messages_in_oldest_entry: relayers
				.front()
				.map(|entry| 1 + entry.messages.end - entry.messages.begin)
				.unwrap_or(0),
			total_messages: total_unrewarded_messages(&relayers).unwrap_or(MessageNonce::MAX),
			last_delivered_nonce,
		}
	}

	fn send_regular_message() -> Weight {
		get_ready_for_events();

		let message_nonce =
			outbound_lane::<TestRuntime, ()>(TEST_LANE_ID).data().latest_generated_nonce + 1;
		let weight = Pallet::<TestRuntime>::send_message(
			Origin::signed(1),
			TEST_LANE_ID,
			REGULAR_PAYLOAD,
			REGULAR_PAYLOAD.declared_weight,
		)
		.expect("send_message has failed")
		.actual_weight
		.expect("send_message always returns Some");

		// check event with assigned nonce
		assert_eq!(
			System::<TestRuntime>::events(),
			vec![EventRecord {
				phase: Phase::Initialization,
				event: TestEvent::Messages(Event::MessageAccepted {
					lane_id: TEST_LANE_ID,
					nonce: message_nonce
				}),
				topics: vec![],
			}],
		);

		// check that fee has been withdrawn from submitter
		assert!(TestMessageDeliveryAndDispatchPayment::is_fee_paid(
			1,
			REGULAR_PAYLOAD.declared_weight
		));

		weight
	}

	fn receive_messages_delivery_proof() {
		System::<TestRuntime>::set_block_number(1);
		System::<TestRuntime>::reset_events();

		assert_ok!(Pallet::<TestRuntime>::receive_messages_delivery_proof(
			Origin::signed(1),
			TestMessagesDeliveryProof(Ok((
				TEST_LANE_ID,
				InboundLaneData {
					last_confirmed_nonce: 1,
					relayers: vec![UnrewardedRelayer {
						relayer: 0,
						messages: DeliveredMessages::new(1, true),
					}]
					.into_iter()
					.collect(),
				},
			))),
			UnrewardedRelayersState {
				unrewarded_relayer_entries: 1,
				total_messages: 1,
				last_delivered_nonce: 1,
				..Default::default()
			},
		));

		assert_eq!(
			System::<TestRuntime>::events(),
			vec![EventRecord {
				phase: Phase::Initialization,
				event: TestEvent::Messages(Event::MessagesDelivered {
					lane_id: TEST_LANE_ID,
					messages: DeliveredMessages::new(1, true),
				}),
				topics: vec![],
			}],
		);
	}

	#[test]
	fn pallet_parameter_may_be_updated_by_root() {
		run_test(|| {
			get_ready_for_events();

			let parameter = TestMessagesParameter::TokenConversionRate(10.into());
			assert_ok!(Pallet::<TestRuntime>::update_pallet_parameter(
				Origin::root(),
				parameter.clone(),
			));

			assert_eq!(TokenConversionRate::get(), 10.into());
			assert_eq!(
				System::<TestRuntime>::events(),
				vec![EventRecord {
					phase: Phase::Initialization,
					event: TestEvent::Messages(Event::ParameterUpdated { parameter }),
					topics: vec![],
				}],
			);
		});
	}

	#[test]
	fn pallet_parameter_may_be_updated_by_owner() {
		run_test(|| {
			PalletOwner::<TestRuntime>::put(2);
			get_ready_for_events();

			let parameter = TestMessagesParameter::TokenConversionRate(10.into());
			assert_ok!(Pallet::<TestRuntime>::update_pallet_parameter(
				Origin::signed(2),
				parameter.clone(),
			));

			assert_eq!(TokenConversionRate::get(), 10.into());
			assert_eq!(
				System::<TestRuntime>::events(),
				vec![EventRecord {
					phase: Phase::Initialization,
					event: TestEvent::Messages(Event::ParameterUpdated { parameter }),
					topics: vec![],
				}],
			);
		});
	}

	#[test]
	fn pallet_parameter_cant_be_updated_by_arbitrary_submitter() {
		run_test(|| {
			assert_noop!(
				Pallet::<TestRuntime>::update_pallet_parameter(
					Origin::signed(2),
					TestMessagesParameter::TokenConversionRate(10.into()),
				),
				DispatchError::BadOrigin,
			);

			PalletOwner::<TestRuntime>::put(2);

			assert_noop!(
				Pallet::<TestRuntime>::update_pallet_parameter(
					Origin::signed(1),
					TestMessagesParameter::TokenConversionRate(10.into()),
				),
				DispatchError::BadOrigin,
			);
		});
	}

	#[test]
	fn fixed_u128_works_as_i_think() {
		// this test is here just to be sure that conversion rate may be represented with FixedU128
		run_test(|| {
			use sp_runtime::{FixedPointNumber, FixedU128};

			// 1:1 conversion that we use by default for testnets
			let rialto_token = 1u64;
			let rialto_token_in_millau_tokens =
				TokenConversionRate::get().saturating_mul_int(rialto_token);
			assert_eq!(rialto_token_in_millau_tokens, 1);

			// let's say conversion rate is 1:1.7
			let conversion_rate = FixedU128::saturating_from_rational(170, 100);
			let rialto_tokens = 100u64;
			let rialto_tokens_in_millau_tokens = conversion_rate.saturating_mul_int(rialto_tokens);
			assert_eq!(rialto_tokens_in_millau_tokens, 170);

			// let's say conversion rate is 1:0.25
			let conversion_rate = FixedU128::saturating_from_rational(25, 100);
			let rialto_tokens = 100u64;
			let rialto_tokens_in_millau_tokens = conversion_rate.saturating_mul_int(rialto_tokens);
			assert_eq!(rialto_tokens_in_millau_tokens, 25);
		});
	}

	#[test]
	fn pallet_rejects_transactions_if_halted() {
		run_test(|| {
			// send message first to be able to check that delivery_proof fails later
			send_regular_message();

			PalletOperatingMode::<TestRuntime, ()>::put(MessagesOperatingMode::Basic(
				BasicOperatingMode::Halted,
			));

			assert_noop!(
				Pallet::<TestRuntime>::send_message(
					Origin::signed(1),
					TEST_LANE_ID,
					REGULAR_PAYLOAD,
					REGULAR_PAYLOAD.declared_weight,
				),
				Error::<TestRuntime, ()>::NotOperatingNormally,
			);

			assert_noop!(
				Pallet::<TestRuntime>::increase_message_fee(Origin::signed(1), TEST_LANE_ID, 1, 1,),
				Error::<TestRuntime, ()>::BridgeModule(bp_runtime::OwnedBridgeModuleError::Halted),
			);

			assert_noop!(
				Pallet::<TestRuntime>::receive_messages_proof(
					Origin::signed(1),
					TEST_RELAYER_A,
					Ok(vec![message(2, REGULAR_PAYLOAD)]).into(),
					1,
					REGULAR_PAYLOAD.declared_weight,
				),
				Error::<TestRuntime, ()>::BridgeModule(bp_runtime::OwnedBridgeModuleError::Halted),
			);

			assert_noop!(
				Pallet::<TestRuntime>::receive_messages_delivery_proof(
					Origin::signed(1),
					TestMessagesDeliveryProof(Ok((
						TEST_LANE_ID,
						InboundLaneData {
							last_confirmed_nonce: 1,
							relayers: vec![unrewarded_relayer(1, 1, TEST_RELAYER_A)]
								.into_iter()
								.collect(),
						},
					))),
					UnrewardedRelayersState {
						unrewarded_relayer_entries: 1,
						messages_in_oldest_entry: 1,
						total_messages: 1,
						last_delivered_nonce: 1,
					},
				),
				Error::<TestRuntime, ()>::BridgeModule(bp_runtime::OwnedBridgeModuleError::Halted),
			);
		});
	}

	#[test]
	fn pallet_rejects_new_messages_in_rejecting_outbound_messages_operating_mode() {
		run_test(|| {
			// send message first to be able to check that delivery_proof fails later
			send_regular_message();

			PalletOperatingMode::<TestRuntime, ()>::put(
				MessagesOperatingMode::RejectingOutboundMessages,
			);

			assert_noop!(
				Pallet::<TestRuntime>::send_message(
					Origin::signed(1),
					TEST_LANE_ID,
					REGULAR_PAYLOAD,
					REGULAR_PAYLOAD.declared_weight,
				),
				Error::<TestRuntime, ()>::NotOperatingNormally,
			);

			assert_ok!(Pallet::<TestRuntime>::increase_message_fee(
				Origin::signed(1),
				TEST_LANE_ID,
				1,
				1,
			));

			assert_ok!(Pallet::<TestRuntime>::receive_messages_proof(
				Origin::signed(1),
				TEST_RELAYER_A,
				Ok(vec![message(1, REGULAR_PAYLOAD)]).into(),
				1,
				REGULAR_PAYLOAD.declared_weight,
			),);

			assert_ok!(Pallet::<TestRuntime>::receive_messages_delivery_proof(
				Origin::signed(1),
				TestMessagesDeliveryProof(Ok((
					TEST_LANE_ID,
					InboundLaneData {
						last_confirmed_nonce: 1,
						relayers: vec![unrewarded_relayer(1, 1, TEST_RELAYER_A)]
							.into_iter()
							.collect(),
					},
				))),
				UnrewardedRelayersState {
					unrewarded_relayer_entries: 1,
					messages_in_oldest_entry: 1,
					total_messages: 1,
					last_delivered_nonce: 1,
				},
			));
		});
	}

	#[test]
	fn send_message_works() {
		run_test(|| {
			send_regular_message();
		});
	}

	#[test]
	fn send_message_rejects_too_large_message() {
		run_test(|| {
			let mut message_payload = message_payload(1, 0);
			// the payload isn't simply extra, so it'll definitely overflow
			// `MAX_OUTBOUND_PAYLOAD_SIZE` if we add `MAX_OUTBOUND_PAYLOAD_SIZE` bytes to extra
			message_payload
				.extra
				.extend_from_slice(&[0u8; MAX_OUTBOUND_PAYLOAD_SIZE as usize]);
			assert_noop!(
				Pallet::<TestRuntime>::send_message(
					Origin::signed(1),
					TEST_LANE_ID,
					message_payload,
					0,
				),
				Error::<TestRuntime, ()>::MessageIsTooLarge,
			);
		})
	}

	#[test]
	fn chain_verifier_rejects_invalid_message_in_send_message() {
		run_test(|| {
			// messages with this payload are rejected by target chain verifier
			assert_noop!(
				Pallet::<TestRuntime>::send_message(
					Origin::signed(1),
					TEST_LANE_ID,
					PAYLOAD_REJECTED_BY_TARGET_CHAIN,
					PAYLOAD_REJECTED_BY_TARGET_CHAIN.declared_weight
				),
				Error::<TestRuntime, ()>::MessageRejectedByChainVerifier,
			);
		});
	}

	#[test]
	fn lane_verifier_rejects_invalid_message_in_send_message() {
		run_test(|| {
			// messages with zero fee are rejected by lane verifier
			assert_noop!(
				Pallet::<TestRuntime>::send_message(
					Origin::signed(1),
					TEST_LANE_ID,
					REGULAR_PAYLOAD,
					0
				),
				Error::<TestRuntime, ()>::MessageRejectedByLaneVerifier,
			);
		});
	}

	#[test]
	fn message_send_fails_if_submitter_cant_pay_message_fee() {
		run_test(|| {
			TestMessageDeliveryAndDispatchPayment::reject_payments();
			assert_noop!(
				Pallet::<TestRuntime>::send_message(
					Origin::signed(1),
					TEST_LANE_ID,
					REGULAR_PAYLOAD,
					REGULAR_PAYLOAD.declared_weight
				),
				Error::<TestRuntime, ()>::FailedToWithdrawMessageFee,
			);
		});
	}

	#[test]
	fn receive_messages_proof_works() {
		run_test(|| {
			assert_ok!(Pallet::<TestRuntime>::receive_messages_proof(
				Origin::signed(1),
				TEST_RELAYER_A,
				Ok(vec![message(1, REGULAR_PAYLOAD)]).into(),
				1,
				REGULAR_PAYLOAD.declared_weight,
			));

			assert_eq!(InboundLanes::<TestRuntime>::get(TEST_LANE_ID).0.last_delivered_nonce(), 1);
		});
	}

	#[test]
	fn receive_messages_proof_updates_confirmed_message_nonce() {
		run_test(|| {
			// say we have received 10 messages && last confirmed message is 8
			InboundLanes::<TestRuntime, ()>::insert(
				TEST_LANE_ID,
				InboundLaneData {
					last_confirmed_nonce: 8,
					relayers: vec![
						unrewarded_relayer(9, 9, TEST_RELAYER_A),
						unrewarded_relayer(10, 10, TEST_RELAYER_B),
					]
					.into_iter()
					.collect(),
				},
			);
			assert_eq!(
				inbound_unrewarded_relayers_state(TEST_LANE_ID),
				UnrewardedRelayersState {
					unrewarded_relayer_entries: 2,
					messages_in_oldest_entry: 1,
					total_messages: 2,
					last_delivered_nonce: 10,
				},
			);

			// message proof includes outbound lane state with latest confirmed message updated to 9
			let mut message_proof: TestMessagesProof =
				Ok(vec![message(11, REGULAR_PAYLOAD)]).into();
			message_proof.result.as_mut().unwrap()[0].1.lane_state =
				Some(OutboundLaneData { latest_received_nonce: 9, ..Default::default() });

			assert_ok!(Pallet::<TestRuntime>::receive_messages_proof(
				Origin::signed(1),
				TEST_RELAYER_A,
				message_proof,
				1,
				REGULAR_PAYLOAD.declared_weight,
			));

			assert_eq!(
				InboundLanes::<TestRuntime>::get(TEST_LANE_ID).0,
				InboundLaneData {
					last_confirmed_nonce: 9,
					relayers: vec![
						unrewarded_relayer(10, 10, TEST_RELAYER_B),
						unrewarded_relayer(11, 11, TEST_RELAYER_A)
					]
					.into_iter()
					.collect(),
				},
			);
			assert_eq!(
				inbound_unrewarded_relayers_state(TEST_LANE_ID),
				UnrewardedRelayersState {
					unrewarded_relayer_entries: 2,
					messages_in_oldest_entry: 1,
					total_messages: 2,
					last_delivered_nonce: 11,
				},
			);
		});
	}

	#[test]
	fn receive_messages_proof_does_not_accept_message_if_dispatch_weight_is_not_enough() {
		run_test(|| {
			assert_ok!(Pallet::<TestRuntime>::receive_messages_proof(
				Origin::signed(1),
				TEST_RELAYER_A,
				Ok(vec![message(1, REGULAR_PAYLOAD)]).into(),
				1,
				REGULAR_PAYLOAD.declared_weight - 1,
			));
			assert_eq!(InboundLanes::<TestRuntime>::get(TEST_LANE_ID).last_delivered_nonce(), 0);
		});
	}

	#[test]
	fn receive_messages_proof_rejects_invalid_proof() {
		run_test(|| {
			assert_noop!(
				Pallet::<TestRuntime, ()>::receive_messages_proof(
					Origin::signed(1),
					TEST_RELAYER_A,
					Err(()).into(),
					1,
					0,
				),
				Error::<TestRuntime, ()>::InvalidMessagesProof,
			);
		});
	}

	#[test]
	fn receive_messages_proof_rejects_proof_with_too_many_messages() {
		run_test(|| {
			assert_noop!(
				Pallet::<TestRuntime, ()>::receive_messages_proof(
					Origin::signed(1),
					TEST_RELAYER_A,
					Ok(vec![message(1, REGULAR_PAYLOAD)]).into(),
					u32::MAX,
					0,
				),
				Error::<TestRuntime, ()>::TooManyMessagesInTheProof,
			);
		});
	}

	#[test]
	fn receive_messages_delivery_proof_works() {
		run_test(|| {
			send_regular_message();
			receive_messages_delivery_proof();

			assert_eq!(
				OutboundLanes::<TestRuntime, ()>::get(&TEST_LANE_ID).latest_received_nonce,
				1,
			);
		});
	}

	#[test]
	fn receive_messages_delivery_proof_rewards_relayers() {
		run_test(|| {
			assert_ok!(Pallet::<TestRuntime>::send_message(
				Origin::signed(1),
				TEST_LANE_ID,
				REGULAR_PAYLOAD,
				1000,
			));
			assert_ok!(Pallet::<TestRuntime>::send_message(
				Origin::signed(1),
				TEST_LANE_ID,
				REGULAR_PAYLOAD,
				2000,
			));

			// this reports delivery of message 1 => reward is paid to TEST_RELAYER_A
			assert_ok!(Pallet::<TestRuntime>::receive_messages_delivery_proof(
				Origin::signed(1),
				TestMessagesDeliveryProof(Ok((
					TEST_LANE_ID,
					InboundLaneData {
						relayers: vec![unrewarded_relayer(1, 1, TEST_RELAYER_A)]
							.into_iter()
							.collect(),
						..Default::default()
					}
				))),
				UnrewardedRelayersState {
					unrewarded_relayer_entries: 1,
					total_messages: 1,
					last_delivered_nonce: 1,
					..Default::default()
				},
			));
			assert!(TestMessageDeliveryAndDispatchPayment::is_reward_paid(TEST_RELAYER_A, 1000));
			assert!(!TestMessageDeliveryAndDispatchPayment::is_reward_paid(TEST_RELAYER_B, 2000));

			// this reports delivery of both message 1 and message 2 => reward is paid only to
			// TEST_RELAYER_B
			assert_ok!(Pallet::<TestRuntime>::receive_messages_delivery_proof(
				Origin::signed(1),
				TestMessagesDeliveryProof(Ok((
					TEST_LANE_ID,
					InboundLaneData {
						relayers: vec![
							unrewarded_relayer(1, 1, TEST_RELAYER_A),
							unrewarded_relayer(2, 2, TEST_RELAYER_B)
						]
						.into_iter()
						.collect(),
						..Default::default()
					}
				))),
				UnrewardedRelayersState {
					unrewarded_relayer_entries: 2,
					total_messages: 2,
					last_delivered_nonce: 2,
					..Default::default()
				},
			));
			assert!(!TestMessageDeliveryAndDispatchPayment::is_reward_paid(TEST_RELAYER_A, 1000));
			assert!(TestMessageDeliveryAndDispatchPayment::is_reward_paid(TEST_RELAYER_B, 2000));
		});
	}

	#[test]
	fn receive_messages_delivery_proof_rejects_invalid_proof() {
		run_test(|| {
			assert_noop!(
				Pallet::<TestRuntime>::receive_messages_delivery_proof(
					Origin::signed(1),
					TestMessagesDeliveryProof(Err(())),
					Default::default(),
				),
				Error::<TestRuntime, ()>::InvalidMessagesDeliveryProof,
			);
		});
	}

	#[test]
	fn receive_messages_delivery_proof_rejects_proof_if_declared_relayers_state_is_invalid() {
		run_test(|| {
			// when number of relayers entries is invalid
			assert_noop!(
				Pallet::<TestRuntime>::receive_messages_delivery_proof(
					Origin::signed(1),
					TestMessagesDeliveryProof(Ok((
						TEST_LANE_ID,
						InboundLaneData {
							relayers: vec![
								unrewarded_relayer(1, 1, TEST_RELAYER_A),
								unrewarded_relayer(2, 2, TEST_RELAYER_B)
							]
							.into_iter()
							.collect(),
							..Default::default()
						}
					))),
					UnrewardedRelayersState {
						unrewarded_relayer_entries: 1,
						total_messages: 2,
						last_delivered_nonce: 2,
						..Default::default()
					},
				),
				Error::<TestRuntime, ()>::InvalidUnrewardedRelayersState,
			);

			// when number of messages is invalid
			assert_noop!(
				Pallet::<TestRuntime>::receive_messages_delivery_proof(
					Origin::signed(1),
					TestMessagesDeliveryProof(Ok((
						TEST_LANE_ID,
						InboundLaneData {
							relayers: vec![
								unrewarded_relayer(1, 1, TEST_RELAYER_A),
								unrewarded_relayer(2, 2, TEST_RELAYER_B)
							]
							.into_iter()
							.collect(),
							..Default::default()
						}
					))),
					UnrewardedRelayersState {
						unrewarded_relayer_entries: 2,
						total_messages: 1,
						last_delivered_nonce: 2,
						..Default::default()
					},
				),
				Error::<TestRuntime, ()>::InvalidUnrewardedRelayersState,
			);

			// when last delivered nonce is invalid
			assert_noop!(
				Pallet::<TestRuntime>::receive_messages_delivery_proof(
					Origin::signed(1),
					TestMessagesDeliveryProof(Ok((
						TEST_LANE_ID,
						InboundLaneData {
							relayers: vec![
								unrewarded_relayer(1, 1, TEST_RELAYER_A),
								unrewarded_relayer(2, 2, TEST_RELAYER_B)
							]
							.into_iter()
							.collect(),
							..Default::default()
						}
					))),
					UnrewardedRelayersState {
						unrewarded_relayer_entries: 2,
						total_messages: 2,
						last_delivered_nonce: 8,
						..Default::default()
					},
				),
				Error::<TestRuntime, ()>::InvalidUnrewardedRelayersState,
			);
		});
	}

	#[test]
	fn receive_messages_accepts_single_message_with_invalid_payload() {
		run_test(|| {
			let mut invalid_message = message(1, REGULAR_PAYLOAD);
			invalid_message.data.payload = Vec::new();

			assert_ok!(Pallet::<TestRuntime, ()>::receive_messages_proof(
				Origin::signed(1),
				TEST_RELAYER_A,
				Ok(vec![invalid_message]).into(),
				1,
				0, // weight may be zero in this case (all messages are improperly encoded)
			),);

			assert_eq!(InboundLanes::<TestRuntime>::get(&TEST_LANE_ID).last_delivered_nonce(), 1,);
		});
	}

	#[test]
	fn receive_messages_accepts_batch_with_message_with_invalid_payload() {
		run_test(|| {
			let mut invalid_message = message(2, REGULAR_PAYLOAD);
			invalid_message.data.payload = Vec::new();

			assert_ok!(Pallet::<TestRuntime, ()>::receive_messages_proof(
				Origin::signed(1),
				TEST_RELAYER_A,
				Ok(
					vec![message(1, REGULAR_PAYLOAD), invalid_message, message(3, REGULAR_PAYLOAD),]
				)
				.into(),
				3,
				REGULAR_PAYLOAD.declared_weight + REGULAR_PAYLOAD.declared_weight,
			),);

			assert_eq!(InboundLanes::<TestRuntime>::get(&TEST_LANE_ID).last_delivered_nonce(), 3,);
		});
	}

	#[test]
	fn actual_dispatch_weight_does_not_overlow() {
		run_test(|| {
			let message1 = message(1, message_payload(0, Weight::MAX / 2));
			let message2 = message(2, message_payload(0, Weight::MAX / 2));
			let message3 = message(3, message_payload(0, Weight::MAX / 2));

			assert_ok!(Pallet::<TestRuntime, ()>::receive_messages_proof(
				Origin::signed(1),
				TEST_RELAYER_A,
				// this may cause overflow if source chain storage is invalid
				Ok(vec![message1, message2, message3]).into(),
				3,
				Weight::MAX,
			));
			assert_eq!(InboundLanes::<TestRuntime>::get(TEST_LANE_ID).last_delivered_nonce(), 2);
		});
	}

	#[test]
	fn increase_message_fee_fails_if_message_is_already_delivered() {
		run_test(|| {
			send_regular_message();
			receive_messages_delivery_proof();

			assert_noop!(
				Pallet::<TestRuntime, ()>::increase_message_fee(
					Origin::signed(1),
					TEST_LANE_ID,
					1,
					100,
				),
				Error::<TestRuntime, ()>::MessageIsAlreadyDelivered,
			);
		});
	}

	#[test]
	fn increase_message_fee_fails_if_message_is_not_yet_sent() {
		run_test(|| {
			assert_noop!(
				Pallet::<TestRuntime, ()>::increase_message_fee(
					Origin::signed(1),
					TEST_LANE_ID,
					1,
					100,
				),
				Error::<TestRuntime, ()>::MessageIsNotYetSent,
			);
		});
	}

	#[test]
	fn increase_message_fee_fails_if_submitter_cant_pay_additional_fee() {
		run_test(|| {
			send_regular_message();

			TestMessageDeliveryAndDispatchPayment::reject_payments();

			assert_noop!(
				Pallet::<TestRuntime, ()>::increase_message_fee(
					Origin::signed(1),
					TEST_LANE_ID,
					1,
					100,
				),
				Error::<TestRuntime, ()>::FailedToWithdrawMessageFee,
			);
		});
	}

	#[test]
	fn increase_message_fee_succeeds() {
		run_test(|| {
			send_regular_message();

			assert_ok!(Pallet::<TestRuntime, ()>::increase_message_fee(
				Origin::signed(1),
				TEST_LANE_ID,
				1,
				100,
			),);
			assert!(TestMessageDeliveryAndDispatchPayment::is_fee_paid(1, 100));
		});
	}

	#[test]
	fn weight_refund_from_receive_messages_proof_works() {
		run_test(|| {
			fn submit_with_unspent_weight(
				nonce: MessageNonce,
				unspent_weight: Weight,
				is_prepaid: bool,
			) -> (Weight, Weight) {
				let mut payload = REGULAR_PAYLOAD;
				payload.dispatch_result.unspent_weight = unspent_weight;
				payload.dispatch_result.dispatch_fee_paid_during_dispatch = !is_prepaid;
				let proof = Ok(vec![message(nonce, payload)]).into();
				let messages_count = 1;
				let pre_dispatch_weight =
					<TestRuntime as Config>::WeightInfo::receive_messages_proof_weight(
						&proof,
						messages_count,
						REGULAR_PAYLOAD.declared_weight,
					);
				let post_dispatch_weight = Pallet::<TestRuntime>::receive_messages_proof(
					Origin::signed(1),
					TEST_RELAYER_A,
					proof,
					messages_count,
					REGULAR_PAYLOAD.declared_weight,
				)
				.expect("delivery has failed")
				.actual_weight
				.expect("receive_messages_proof always returns Some");

				(pre_dispatch_weight, post_dispatch_weight)
			}

			// when dispatch is returning `unspent_weight < declared_weight`
			let (pre, post) = submit_with_unspent_weight(1, 1, false);
			assert_eq!(post, pre - 1);

			// when dispatch is returning `unspent_weight = declared_weight`
			let (pre, post) = submit_with_unspent_weight(2, REGULAR_PAYLOAD.declared_weight, false);
			assert_eq!(post, pre - REGULAR_PAYLOAD.declared_weight);

			// when dispatch is returning `unspent_weight > declared_weight`
			let (pre, post) =
				submit_with_unspent_weight(3, REGULAR_PAYLOAD.declared_weight + 1, false);
			assert_eq!(post, pre - REGULAR_PAYLOAD.declared_weight);

			// when there's no unspent weight
			let (pre, post) = submit_with_unspent_weight(4, 0, false);
			assert_eq!(post, pre);

			// when dispatch is returning `unspent_weight < declared_weight` AND message is prepaid
			let (pre, post) = submit_with_unspent_weight(5, 1, true);
			assert_eq!(
				post,
				pre - 1 - <TestRuntime as Config>::WeightInfo::pay_inbound_dispatch_fee_overhead()
			);
		});
	}

	#[test]
	fn messages_delivered_callbacks_are_called() {
		run_test(|| {
			send_regular_message();
			send_regular_message();
			send_regular_message();

			// messages 1+2 are confirmed in 1 tx, message 3 in a separate tx
			// dispatch of message 2 has failed
			let mut delivered_messages_1_and_2 = DeliveredMessages::new(1, true);
			delivered_messages_1_and_2.note_dispatched_message(false);
			let messages_1_and_2_proof = Ok((
				TEST_LANE_ID,
				InboundLaneData {
					last_confirmed_nonce: 0,
					relayers: vec![UnrewardedRelayer {
						relayer: 0,
						messages: delivered_messages_1_and_2.clone(),
					}]
					.into_iter()
					.collect(),
				},
			));
			let delivered_message_3 = DeliveredMessages::new(3, true);
			let messages_3_proof = Ok((
				TEST_LANE_ID,
				InboundLaneData {
					last_confirmed_nonce: 0,
					relayers: vec![UnrewardedRelayer {
						relayer: 0,
						messages: delivered_message_3.clone(),
					}]
					.into_iter()
					.collect(),
				},
			));

			// first tx with messages 1+2
			assert_ok!(Pallet::<TestRuntime>::receive_messages_delivery_proof(
				Origin::signed(1),
				TestMessagesDeliveryProof(messages_1_and_2_proof),
				UnrewardedRelayersState {
					unrewarded_relayer_entries: 1,
					total_messages: 2,
					last_delivered_nonce: 2,
					..Default::default()
				},
			));
			// second tx with message 3
			assert_ok!(Pallet::<TestRuntime>::receive_messages_delivery_proof(
				Origin::signed(1),
				TestMessagesDeliveryProof(messages_3_proof),
				UnrewardedRelayersState {
					unrewarded_relayer_entries: 1,
					total_messages: 1,
					last_delivered_nonce: 3,
					..Default::default()
				},
			));

			// ensure that both callbacks have been called twice: for 1+2, then for 3
			TestOnDeliveryConfirmed1::ensure_called(&TEST_LANE_ID, &delivered_messages_1_and_2);
			TestOnDeliveryConfirmed1::ensure_called(&TEST_LANE_ID, &delivered_message_3);
			TestOnDeliveryConfirmed2::ensure_called(&TEST_LANE_ID, &delivered_messages_1_and_2);
			TestOnDeliveryConfirmed2::ensure_called(&TEST_LANE_ID, &delivered_message_3);
		});
	}

	fn confirm_3_messages_delivery() -> (Weight, Weight) {
		send_regular_message();
		send_regular_message();
		send_regular_message();

		let proof = TestMessagesDeliveryProof(Ok((
			TEST_LANE_ID,
			InboundLaneData {
				last_confirmed_nonce: 0,
				relayers: vec![unrewarded_relayer(1, 3, TEST_RELAYER_A)].into_iter().collect(),
			},
		)));
		let relayers_state = UnrewardedRelayersState {
			unrewarded_relayer_entries: 1,
			total_messages: 3,
			last_delivered_nonce: 3,
			..Default::default()
		};
		let pre_dispatch_weight =
			<TestRuntime as Config>::WeightInfo::receive_messages_delivery_proof_weight(
				&proof,
				&relayers_state,
				crate::mock::DbWeight::get(),
			);
		let post_dispatch_weight = Pallet::<TestRuntime>::receive_messages_delivery_proof(
			Origin::signed(1),
			proof,
			relayers_state,
		)
		.expect("confirmation has failed")
		.actual_weight
		.expect("receive_messages_delivery_proof always returns Some");
		(pre_dispatch_weight, post_dispatch_weight)
	}

	#[test]
	fn receive_messages_delivery_proof_refunds_zero_weight() {
		run_test(|| {
			let (pre_dispatch_weight, post_dispatch_weight) = confirm_3_messages_delivery();
			assert_eq!(pre_dispatch_weight, post_dispatch_weight);
		});
	}

	#[test]
	fn receive_messages_delivery_proof_refunds_non_zero_weight() {
		run_test(|| {
			TestOnDeliveryConfirmed1::set_consumed_weight_per_message(
				crate::mock::DbWeight::get().writes(1),
			);

			let (pre_dispatch_weight, post_dispatch_weight) = confirm_3_messages_delivery();
			assert_eq!(
				pre_dispatch_weight.saturating_sub(post_dispatch_weight),
				crate::mock::DbWeight::get().reads(1) * 3
			);
		});
	}

	#[test]
	#[should_panic]
	#[cfg(debug_assertions)]
	fn receive_messages_panics_in_debug_mode_if_callback_is_wrong() {
		run_test(|| {
			TestOnDeliveryConfirmed1::set_consumed_weight_per_message(
				crate::mock::DbWeight::get().reads_writes(2, 2),
			);
			confirm_3_messages_delivery()
		});
	}

	#[test]
	fn receive_messages_delivery_proof_rejects_proof_if_trying_to_confirm_more_messages_than_expected(
	) {
		run_test(|| {
			// send message first to be able to check that delivery_proof fails later
			send_regular_message();

			// 1) InboundLaneData declares that the `last_confirmed_nonce` is 1;
			// 2) InboundLaneData has no entries => `InboundLaneData::last_delivered_nonce()`
			//    returns `last_confirmed_nonce`;
			// 3) it means that we're going to confirm delivery of messages 1..=1;
			// 4) so the number of declared messages (see `UnrewardedRelayersState`) is `0` and
			//    numer of actually confirmed messages is `1`.
			assert_noop!(
				Pallet::<TestRuntime>::receive_messages_delivery_proof(
					Origin::signed(1),
					TestMessagesDeliveryProof(Ok((
						TEST_LANE_ID,
						InboundLaneData { last_confirmed_nonce: 1, relayers: Default::default() },
					))),
					UnrewardedRelayersState { last_delivered_nonce: 1, ..Default::default() },
				),
				Error::<TestRuntime, ()>::TryingToConfirmMoreMessagesThanExpected,
			);
		});
	}

	#[test]
	fn increase_message_fee_weight_depends_on_message_size() {
		run_test(|| {
			let mut small_payload = message_payload(0, 100);
			let mut large_payload = message_payload(1, 100);
			small_payload.extra = vec![1; MAX_OUTBOUND_PAYLOAD_SIZE as usize / 10];
			large_payload.extra = vec![2; MAX_OUTBOUND_PAYLOAD_SIZE as usize / 5];

			assert_ok!(Pallet::<TestRuntime>::send_message(
				Origin::signed(1),
				TEST_LANE_ID,
				small_payload,
				100,
			));
			assert_ok!(Pallet::<TestRuntime>::send_message(
				Origin::signed(1),
				TEST_LANE_ID,
				large_payload,
				100,
			));

			let small_weight =
				Pallet::<TestRuntime>::increase_message_fee(Origin::signed(1), TEST_LANE_ID, 1, 1)
					.expect("increase_message_fee has failed")
					.actual_weight
					.expect("increase_message_fee always returns Some");

			let large_weight =
				Pallet::<TestRuntime>::increase_message_fee(Origin::signed(1), TEST_LANE_ID, 2, 1)
					.expect("increase_message_fee has failed")
					.actual_weight
					.expect("increase_message_fee always returns Some");

			assert!(
				large_weight > small_weight,
				"Actual post-dispatch weigth for larger message {} must be larger than {} for small message",
				large_weight,
				small_weight,
			);
		});
	}

	#[test]
	fn weight_is_refunded_for_messages_that_are_not_pruned() {
		run_test(|| {
			// send first MAX messages - no messages are pruned
			let max_messages_to_prune = crate::mock::MaxMessagesToPruneAtOnce::get();
			let when_zero_messages_are_pruned = send_regular_message();
			let mut delivered_messages = DeliveredMessages::new(1, true);
			for _ in 1..max_messages_to_prune {
				assert_eq!(send_regular_message(), when_zero_messages_are_pruned);
				delivered_messages.note_dispatched_message(true);
			}

			// confirm delivery of all sent messages
			assert_ok!(Pallet::<TestRuntime>::receive_messages_delivery_proof(
				Origin::signed(1),
				TestMessagesDeliveryProof(Ok((
					TEST_LANE_ID,
					InboundLaneData {
						last_confirmed_nonce: 1,
						relayers: vec![UnrewardedRelayer {
							relayer: 0,
							messages: delivered_messages,
						}]
						.into_iter()
						.collect(),
					},
				))),
				UnrewardedRelayersState {
					unrewarded_relayer_entries: 1,
					total_messages: max_messages_to_prune,
					last_delivered_nonce: max_messages_to_prune,
					..Default::default()
				},
			));

			// when next message is sent, MAX messages are pruned
			let weight_when_max_messages_are_pruned = send_regular_message();
			assert_eq!(
				weight_when_max_messages_are_pruned,
				when_zero_messages_are_pruned +
					crate::mock::DbWeight::get().writes(max_messages_to_prune),
			);
		});
	}

	#[test]
	fn message_accepted_callbacks_are_called() {
		run_test(|| {
			send_regular_message();
			TestOnMessageAccepted::ensure_called(&TEST_LANE_ID, &1);
		});
	}

	#[test]
	#[should_panic]
	#[cfg(debug_assertions)]
	fn message_accepted_panics_in_debug_mode_if_callback_is_wrong() {
		run_test(|| {
			TestOnMessageAccepted::set_consumed_weight_per_message(
				crate::mock::DbWeight::get().reads_writes(2, 2),
			);
			send_regular_message();
		});
	}

	#[test]
	fn message_accepted_refunds_non_zero_weight() {
		run_test(|| {
			TestOnMessageAccepted::set_consumed_weight_per_message(
				crate::mock::DbWeight::get().writes(1),
			);
			let actual_callback_weight = send_regular_message();
			let pre_dispatch_weight = <TestRuntime as Config>::WeightInfo::send_message_weight(
				&REGULAR_PAYLOAD,
				crate::mock::DbWeight::get(),
			);
			let prune_weight = crate::mock::DbWeight::get()
				.writes(<TestRuntime as Config>::MaxMessagesToPruneAtOnce::get());

			assert_eq!(
				pre_dispatch_weight.saturating_sub(actual_callback_weight),
				crate::mock::DbWeight::get().reads(1).saturating_add(prune_weight)
			);
		});
	}

	#[test]
	fn storage_keys_computed_properly() {
		assert_eq!(
			PalletOperatingMode::<TestRuntime>::storage_value_final_key().to_vec(),
			bp_messages::storage_keys::operating_mode_key("Messages").0,
		);

		assert_eq!(
			OutboundMessages::<TestRuntime>::storage_map_final_key(MessageKey {
				lane_id: TEST_LANE_ID,
				nonce: 42
			}),
			bp_messages::storage_keys::message_key("Messages", &TEST_LANE_ID, 42).0,
		);

		assert_eq!(
			OutboundLanes::<TestRuntime>::storage_map_final_key(TEST_LANE_ID),
			bp_messages::storage_keys::outbound_lane_data_key("Messages", &TEST_LANE_ID).0,
		);

		assert_eq!(
			InboundLanes::<TestRuntime>::storage_map_final_key(TEST_LANE_ID),
			bp_messages::storage_keys::inbound_lane_data_key("Messages", &TEST_LANE_ID).0,
		);
	}

	#[test]
	fn inbound_message_details_works() {
		run_test(|| {
			assert_eq!(
				Pallet::<TestRuntime>::inbound_message_data(
					TEST_LANE_ID,
					REGULAR_PAYLOAD.encode(),
					OutboundMessageDetails {
						nonce: 0,
						dispatch_weight: 0,
						size: 0,
						delivery_and_dispatch_fee: 0,
						dispatch_fee_payment:
							bp_runtime::messages::DispatchFeePayment::AtTargetChain,
					},
				),
				InboundMessageDetails { dispatch_weight: REGULAR_PAYLOAD.declared_weight },
			);
		});
	}

	generate_owned_bridge_module_tests!(
		MessagesOperatingMode::Basic(BasicOperatingMode::Normal),
		MessagesOperatingMode::Basic(BasicOperatingMode::Halted)
	);
}