// 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 .
//! Primitives of messages module.
#![cfg_attr(not(feature = "std"), no_std)]
// RuntimeApi generated functions
#![allow(clippy::too_many_arguments)]
use bp_runtime::{BasicOperatingMode, OperatingMode};
use codec::{Decode, Encode, MaxEncodedLen};
use frame_support::RuntimeDebug;
use scale_info::TypeInfo;
use sp_std::{collections::vec_deque::VecDeque, prelude::*};
pub mod source_chain;
pub mod storage_keys;
pub mod target_chain;
use bp_runtime::messages::MessageDispatchResult;
// Weight is reexported to avoid additional frame-support dependencies in related crates.
pub use frame_support::weights::Weight;
/// Messages pallet operating mode.
#[derive(Encode, Decode, Clone, Copy, PartialEq, Eq, RuntimeDebug, TypeInfo, MaxEncodedLen)]
#[cfg_attr(feature = "std", derive(serde::Serialize, serde::Deserialize))]
pub enum MessagesOperatingMode {
/// Basic operating mode (Normal/Halted)
Basic(BasicOperatingMode),
/// The pallet is not accepting outbound messages. Inbound messages and receiving proofs
/// are still accepted.
///
/// This mode may be used e.g. when bridged chain expects upgrade. Then to avoid dispatch
/// failures, the pallet owner may stop accepting new messages, while continuing to deliver
/// queued messages to the bridged chain. Once upgrade is completed, the mode may be switched
/// back to `Normal`.
RejectingOutboundMessages,
}
impl Default for MessagesOperatingMode {
fn default() -> Self {
MessagesOperatingMode::Basic(BasicOperatingMode::Normal)
}
}
impl OperatingMode for MessagesOperatingMode {
fn is_halted(&self) -> bool {
match self {
Self::Basic(operating_mode) => operating_mode.is_halted(),
_ => false,
}
}
}
/// Lane identifier.
pub type LaneId = [u8; 4];
/// Message nonce. Valid messages will never have 0 nonce.
pub type MessageNonce = u64;
/// Message id as a tuple.
pub type BridgeMessageId = (LaneId, MessageNonce);
/// Opaque message payload. We only decode this payload when it is dispatched.
pub type MessagePayload = Vec;
/// Message key (unique message identifier) as it is stored in the storage.
#[derive(Encode, Decode, Clone, PartialEq, Eq, RuntimeDebug, TypeInfo, MaxEncodedLen)]
pub struct MessageKey {
/// ID of the message lane.
pub lane_id: LaneId,
/// Message nonce.
pub nonce: MessageNonce,
}
/// Message as it is stored in the storage.
#[derive(Encode, Decode, Clone, PartialEq, Eq, RuntimeDebug, TypeInfo)]
pub struct Message {
/// Message key.
pub key: MessageKey,
/// Message payload.
pub payload: MessagePayload,
}
/// Inbound lane data.
#[derive(Encode, Decode, Clone, RuntimeDebug, PartialEq, Eq, TypeInfo)]
pub struct InboundLaneData {
/// Identifiers of relayers and messages that they have delivered to this lane (ordered by
/// message nonce).
///
/// This serves as a helper storage item, to allow the source chain to easily pay rewards
/// to the relayers who successfully delivered messages to the target chain (inbound lane).
///
/// It is guaranteed to have at most N entries, where N is configured at the module level.
/// If there are N entries in this vec, then:
/// 1) all incoming messages are rejected if they're missing corresponding
/// `proof-of(outbound-lane.state)`; 2) all incoming messages are rejected if
/// `proof-of(outbound-lane.state).last_delivered_nonce` is equal to
/// `self.last_confirmed_nonce`. Given what is said above, all nonces in this queue are in
/// range: `(self.last_confirmed_nonce; self.last_delivered_nonce()]`.
///
/// When a relayer sends a single message, both of MessageNonces are the same.
/// When relayer sends messages in a batch, the first arg is the lowest nonce, second arg the
/// highest nonce. Multiple dispatches from the same relayer are allowed.
pub relayers: VecDeque>,
/// Nonce of the last message that
/// a) has been delivered to the target (this) chain and
/// b) the delivery has been confirmed on the source chain
///
/// that the target chain knows of.
///
/// This value is updated indirectly when an `OutboundLane` state of the source
/// chain is received alongside with new messages delivery.
pub last_confirmed_nonce: MessageNonce,
}
impl Default for InboundLaneData {
fn default() -> Self {
InboundLaneData { relayers: VecDeque::new(), last_confirmed_nonce: 0 }
}
}
impl InboundLaneData {
/// Returns approximate size of the struct, given a number of entries in the `relayers` set and
/// size of each entry.
///
/// Returns `None` if size overflows `usize` limits.
pub fn encoded_size_hint(relayers_entries: usize) -> Option
where
RelayerId: MaxEncodedLen,
{
let message_nonce_size = MessageNonce::max_encoded_len();
let relayer_id_encoded_size = RelayerId::max_encoded_len();
let relayers_entry_size = relayer_id_encoded_size.checked_add(2 * message_nonce_size)?;
let relayers_size = relayers_entries.checked_mul(relayers_entry_size)?;
relayers_size.checked_add(message_nonce_size)
}
/// Returns the approximate size of the struct as u32, given a number of entries in the
/// `relayers` set and the size of each entry.
///
/// Returns `u32::MAX` if size overflows `u32` limits.
pub fn encoded_size_hint_u32(relayers_entries: usize) -> u32
where
RelayerId: MaxEncodedLen,
{
Self::encoded_size_hint(relayers_entries)
.and_then(|x| u32::try_from(x).ok())
.unwrap_or(u32::MAX)
}
/// Nonce of the last message that has been delivered to this (target) chain.
pub fn last_delivered_nonce(&self) -> MessageNonce {
self.relayers
.back()
.map(|entry| entry.messages.end)
.unwrap_or(self.last_confirmed_nonce)
}
}
/// Outbound message details, returned by runtime APIs.
#[derive(Clone, Encode, Decode, RuntimeDebug, PartialEq, Eq)]
pub struct OutboundMessageDetails {
/// Nonce assigned to the message.
pub nonce: MessageNonce,
/// Message dispatch weight.
///
/// Depending on messages pallet configuration, it may be declared by the message submitter,
/// computed automatically or just be zero if dispatch fee is paid at the target chain.
pub dispatch_weight: Weight,
/// Size of the encoded message.
pub size: u32,
}
/// Inbound message details, returned by runtime APIs.
#[derive(Clone, Encode, Decode, RuntimeDebug, PartialEq, Eq)]
pub struct InboundMessageDetails {
/// Computed message dispatch weight.
///
/// Runtime API guarantees that it will match the value, returned by
/// `target_chain::MessageDispatch::dispatch_weight`. This means that if the runtime
/// has failed to decode the message, it will be zero - that's because `undecodable`
/// message cannot be dispatched.
pub dispatch_weight: Weight,
}
/// Unrewarded relayer entry stored in the inbound lane data.
///
/// This struct represents a continuous range of messages that have been delivered by the same
/// relayer and whose confirmations are still pending.
#[derive(Encode, Decode, Clone, RuntimeDebug, PartialEq, Eq, TypeInfo)]
pub struct UnrewardedRelayer {
/// Identifier of the relayer.
pub relayer: RelayerId,
/// Messages range, delivered by this relayer.
pub messages: DeliveredMessages,
}
/// Received messages with their dispatch result.
#[derive(Clone, Default, Encode, Decode, RuntimeDebug, PartialEq, Eq, TypeInfo)]
pub struct ReceivedMessages {
/// Id of the lane which is receiving messages.
pub lane: LaneId,
/// Result of messages which we tried to dispatch
pub receive_results: Vec<(MessageNonce, ReceivalResult)>,
/// Messages which were skipped and never dispatched
pub skipped_for_not_enough_weight: Vec,
}
impl ReceivedMessages {
pub fn new(
lane: LaneId,
receive_results: Vec<(MessageNonce, ReceivalResult)>,
) -> Self {
ReceivedMessages { lane, receive_results, skipped_for_not_enough_weight: Vec::new() }
}
pub fn push(&mut self, message: MessageNonce, result: ReceivalResult) {
self.receive_results.push((message, result));
}
pub fn push_skipped_for_not_enough_weight(&mut self, message: MessageNonce) {
self.skipped_for_not_enough_weight.push(message);
}
}
/// Result of single message receival.
#[derive(RuntimeDebug, Encode, Decode, PartialEq, Eq, Clone, TypeInfo)]
pub enum ReceivalResult {
/// Message has been received and dispatched. Note that we don't care whether dispatch has
/// been successful or not - in both case message falls into this category.
///
/// The message dispatch result is also returned.
Dispatched(MessageDispatchResult),
/// Message has invalid nonce and lane has rejected to accept this message.
InvalidNonce,
/// There are too many unrewarded relayer entries at the lane.
TooManyUnrewardedRelayers,
/// There are too many unconfirmed messages at the lane.
TooManyUnconfirmedMessages,
}
/// Delivered messages with their dispatch result.
#[derive(Clone, Default, Encode, Decode, RuntimeDebug, PartialEq, Eq, TypeInfo)]
pub struct DeliveredMessages {
/// Nonce of the first message that has been delivered (inclusive).
pub begin: MessageNonce,
/// Nonce of the last message that has been delivered (inclusive).
pub end: MessageNonce,
}
impl DeliveredMessages {
/// Create new `DeliveredMessages` struct that confirms delivery of single nonce with given
/// dispatch result.
pub fn new(nonce: MessageNonce) -> Self {
DeliveredMessages { begin: nonce, end: nonce }
}
/// Return total count of delivered messages.
pub fn total_messages(&self) -> MessageNonce {
if self.end >= self.begin {
self.end - self.begin + 1
} else {
0
}
}
/// Note new dispatched message.
pub fn note_dispatched_message(&mut self) {
self.end += 1;
}
/// Returns true if delivered messages contain message with given nonce.
pub fn contains_message(&self, nonce: MessageNonce) -> bool {
(self.begin..=self.end).contains(&nonce)
}
}
/// Gist of `InboundLaneData::relayers` field used by runtime APIs.
#[derive(Clone, Default, Encode, Decode, RuntimeDebug, PartialEq, Eq, TypeInfo)]
pub struct UnrewardedRelayersState {
/// Number of entries in the `InboundLaneData::relayers` set.
pub unrewarded_relayer_entries: MessageNonce,
/// Number of messages in the oldest entry of `InboundLaneData::relayers`. This is the
/// minimal number of reward proofs required to push out this entry from the set.
pub messages_in_oldest_entry: MessageNonce,
/// Total number of messages in the relayers vector.
pub total_messages: MessageNonce,
/// Nonce of the latest message that has been delivered to the target chain.
///
/// This corresponds to the result of the `InboundLaneData::last_delivered_nonce` call
/// at the bridged chain.
pub last_delivered_nonce: MessageNonce,
}
/// Outbound lane data.
#[derive(Encode, Decode, Clone, RuntimeDebug, PartialEq, Eq, TypeInfo, MaxEncodedLen)]
pub struct OutboundLaneData {
/// Nonce of the oldest message that we haven't yet pruned. May point to not-yet-generated
/// message if all sent messages are already pruned.
pub oldest_unpruned_nonce: MessageNonce,
/// Nonce of the latest message, received by bridged chain.
pub latest_received_nonce: MessageNonce,
/// Nonce of the latest message, generated by us.
pub latest_generated_nonce: MessageNonce,
}
impl Default for OutboundLaneData {
fn default() -> Self {
OutboundLaneData {
// it is 1 because we're pruning everything in [oldest_unpruned_nonce;
// latest_received_nonce]
oldest_unpruned_nonce: 1,
latest_received_nonce: 0,
latest_generated_nonce: 0,
}
}
}
/// Returns total number of messages in the `InboundLaneData::relayers` vector.
///
/// Returns `None` if there are more messages that `MessageNonce` may fit (i.e. `MessageNonce + 1`).
pub fn total_unrewarded_messages(
relayers: &VecDeque>,
) -> Option {
match (relayers.front(), relayers.back()) {
(Some(front), Some(back)) => {
if let Some(difference) = back.messages.end.checked_sub(front.messages.begin) {
difference.checked_add(1)
} else {
Some(0)
}
},
_ => Some(0),
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn total_unrewarded_messages_does_not_overflow() {
assert_eq!(
total_unrewarded_messages(
&vec![
UnrewardedRelayer { relayer: 1, messages: DeliveredMessages::new(0) },
UnrewardedRelayer {
relayer: 2,
messages: DeliveredMessages::new(MessageNonce::MAX)
},
]
.into_iter()
.collect()
),
None,
);
}
#[test]
fn inbound_lane_data_returns_correct_hint() {
let test_cases = vec![
// single relayer, multiple messages
(1, 128u8),
// multiple relayers, single message per relayer
(128u8, 128u8),
// several messages per relayer
(13u8, 128u8),
];
for (relayer_entries, messages_count) in test_cases {
let expected_size = InboundLaneData::::encoded_size_hint(relayer_entries as _);
let actual_size = InboundLaneData {
relayers: (1u8..=relayer_entries)
.map(|i| UnrewardedRelayer {
relayer: i,
messages: DeliveredMessages::new(i as _),
})
.collect(),
last_confirmed_nonce: messages_count as _,
}
.encode()
.len();
let difference = (expected_size.unwrap() as f64 - actual_size as f64).abs();
assert!(
difference / (std::cmp::min(actual_size, expected_size.unwrap()) as f64) < 0.1,
"Too large difference between actual ({}) and expected ({:?}) inbound lane data size. Test case: {}+{}",
actual_size,
expected_size,
relayer_entries,
messages_count,
);
}
}
#[test]
fn contains_result_works() {
let delivered_messages = DeliveredMessages { begin: 100, end: 150 };
assert!(!delivered_messages.contains_message(99));
assert!(delivered_messages.contains_message(100));
assert!(delivered_messages.contains_message(150));
assert!(!delivered_messages.contains_message(151));
}
}