Newer
Older
// Copyright (C) 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/>.
//! Module provides utilities for easier XCM handling, e.g:
//! `XcmExecutor` -> `MessageSender` -> `OutboundMessageQueue`
//! `XcmRouter` <- `MessageDispatch` <- `InboundMessageQueue`
use bp_messages::{
Branislav Kontur
committed
source_chain::OnMessagesDelivered,
target_chain::{DispatchMessage, MessageDispatch},
use bp_runtime::messages::MessageDispatchResult;
Branislav Kontur
committed
pub use bp_xcm_bridge_hub::XcmAsPlainPayload;
use bp_xcm_bridge_hub_router::XcmChannelStatusProvider;
use codec::{Decode, Encode};
use frame_support::{traits::Get, weights::Weight, CloneNoBound, EqNoBound, PartialEqNoBound};
Branislav Kontur
committed
Config as MessagesConfig, OutboundLanesCongestedSignals, WeightInfoExt as MessagesPalletWeights,
use scale_info::TypeInfo;
use sp_runtime::SaturatedConversion;
use sp_std::{fmt::Debug, marker::PhantomData};
use xcm::prelude::*;
Branislav Kontur
committed
use xcm_builder::{DispatchBlob, DispatchBlobError};
/// Message dispatch result type for single message.
#[derive(CloneNoBound, EqNoBound, PartialEqNoBound, Encode, Decode, Debug, TypeInfo)]
pub enum XcmBlobMessageDispatchResult {
/// We've been unable to decode message payload.
InvalidPayload,
/// Message has been dispatched.
/// Message has **NOT** been dispatched because of given error.
NotDispatched(#[codec(skip)] Option<DispatchBlobError>),
}
/// [`XcmBlobMessageDispatch`] is responsible for dispatching received messages
///
/// It needs to be used at the target bridge hub.
pub struct XcmBlobMessageDispatch<DispatchBlob, Weights, Channel> {
_marker: sp_std::marker::PhantomData<(DispatchBlob, Weights, Channel)>,
impl<
BlobDispatcher: DispatchBlob,
Weights: MessagesPalletWeights,
Channel: XcmChannelStatusProvider,
> MessageDispatch for XcmBlobMessageDispatch<BlobDispatcher, Weights, Channel>
{
type DispatchPayload = XcmAsPlainPayload;
type DispatchLevelResult = XcmBlobMessageDispatchResult;
fn is_active() -> bool {
!Channel::is_congested()
}
fn dispatch_weight(message: &mut DispatchMessage<Self::DispatchPayload>) -> Weight {
match message.data.payload {
Ok(ref payload) => {
let payload_size = payload.encoded_size().saturated_into();
Weights::message_dispatch_weight(payload_size)
},
Err(_) => Weight::zero(),
}
}
fn dispatch(
message: DispatchMessage<Self::DispatchPayload>,
) -> MessageDispatchResult<Self::DispatchLevelResult> {
let payload = match message.data.payload {
Ok(payload) => payload,
Err(e) => {
log::error!(
target: crate::LOG_TARGET_BRIDGE_DISPATCH,
"[XcmBlobMessageDispatch] payload error: {:?} - message_nonce: {:?}",
e,
message.key.nonce
);
return MessageDispatchResult {
unspent_weight: Weight::zero(),
dispatch_level_result: XcmBlobMessageDispatchResult::InvalidPayload,
}
},
};
let dispatch_level_result = match BlobDispatcher::dispatch_blob(payload) {
Ok(_) => {
log::debug!(
target: crate::LOG_TARGET_BRIDGE_DISPATCH,
"[XcmBlobMessageDispatch] DispatchBlob::dispatch_blob was ok - message_nonce: {:?}",
message.key.nonce
);
XcmBlobMessageDispatchResult::Dispatched
},
Err(e) => {
log::error!(
target: crate::LOG_TARGET_BRIDGE_DISPATCH,
"[XcmBlobMessageDispatch] DispatchBlob::dispatch_blob failed, error: {:?} - message_nonce: {:?}",
e, message.key.nonce
);
XcmBlobMessageDispatchResult::NotDispatched(Some(e))
},
};
MessageDispatchResult { unspent_weight: Weight::zero(), dispatch_level_result }
}
}
/// A pair of sending chain location and message lane, used by this chain to send messages
/// over the bridge.
Branislav Kontur
committed
#[cfg_attr(feature = "std", derive(Debug, Eq, PartialEq))]
pub struct SenderAndLane {
/// Sending chain relative location.
pub location: MultiLocation,
/// Message lane, used by the sending chain.
pub lane: LaneId,
}
impl SenderAndLane {
/// Create new object using provided location and lane.
pub fn new(location: MultiLocation, lane: LaneId) -> Self {
SenderAndLane { location, lane }
}
}
/// [`XcmBlobHauler`] is responsible for sending messages to the bridge "point-to-point link" from
/// one side, where on the other it can be dispatched by [`XcmBlobMessageDispatch`].
pub trait XcmBlobHauler {
/// Runtime that has messages pallet deployed.
type Runtime: MessagesConfig<Self::MessagesInstance>;
/// Instance of the messages pallet that is used to send messages.
type MessagesInstance: 'static;
/// Actual XCM message sender (`HRMP` or `UMP`) to the source chain
/// location (`Self::SenderAndLane::get().location`).
type ToSourceChainSender: SendXcm;
/// An XCM message that is sent to the sending chain when the bridge queue becomes congested.
type CongestedMessage: Get<Option<Xcm<()>>>;
/// An XCM message that is sent to the sending chain when the bridge queue becomes not
/// congested.
type UncongestedMessage: Get<Option<Xcm<()>>>;
/// Returns `true` if we want to handle congestion.
fn supports_congestion_detection() -> bool {
Self::CongestedMessage::get().is_some() || Self::UncongestedMessage::get().is_some()
}
/// XCM bridge adapter which connects [`XcmBlobHauler`] with [`pallet_bridge_messages`] and
/// makes sure that XCM blob is sent to the outbound lane to be relayed.
///
/// It needs to be used at the source bridge hub.
Branislav Kontur
committed
pub struct XcmBlobHaulerAdapter<XcmBlobHauler, Lanes>(
sp_std::marker::PhantomData<(XcmBlobHauler, Lanes)>,
);
Branislav Kontur
committed
impl<
H: XcmBlobHauler,
Lanes: Get<sp_std::vec::Vec<(SenderAndLane, (NetworkId, InteriorMultiLocation))>>,
> OnMessagesDelivered for XcmBlobHaulerAdapter<H, Lanes>
{
fn on_messages_delivered(lane: LaneId, enqueued_messages: MessageNonce) {
Branislav Kontur
committed
if let Some(sender_and_lane) =
Lanes::get().iter().find(|link| link.0.lane == lane).map(|link| &link.0)
{
// notify XCM queue manager about updated lane state
LocalXcmQueueManager::<H>::on_bridge_messages_delivered(
sender_and_lane,
enqueued_messages,
);
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
}
}
}
/// Manager of local XCM queues (and indirectly - underlying transport channels) that
/// controls the queue state.
///
/// It needs to be used at the source bridge hub.
pub struct LocalXcmQueueManager<H>(PhantomData<H>);
/// Maximal number of messages in the outbound bridge queue. Once we reach this limit, we
/// send a "congestion" XCM message to the sending chain.
const OUTBOUND_LANE_CONGESTED_THRESHOLD: MessageNonce = 8_192;
/// After we have sent "congestion" XCM message to the sending chain, we wait until number
/// of messages in the outbound bridge queue drops to this count, before sending `uncongestion`
/// XCM message.
const OUTBOUND_LANE_UNCONGESTED_THRESHOLD: MessageNonce = 1_024;
impl<H: XcmBlobHauler> LocalXcmQueueManager<H> {
/// Must be called whenever we push a message to the bridge lane.
pub fn on_bridge_message_enqueued(
sender_and_lane: &SenderAndLane,
enqueued_messages: MessageNonce,
) {
// skip if we dont want to handle congestion
if !H::supports_congestion_detection() {
return
}
// if we have already sent the congestion signal, we don't want to do anything
if Self::is_congested_signal_sent(sender_and_lane.lane) {
return
}
// if the bridge queue is not congested, we don't want to do anything
let is_congested = enqueued_messages > OUTBOUND_LANE_CONGESTED_THRESHOLD;
if !is_congested {
return
}
log::info!(
target: crate::LOG_TARGET_BRIDGE_DISPATCH,
"Sending 'congested' XCM message to {:?} to avoid overloading lane {:?}: there are\
{} messages queued at the bridge queue",
sender_and_lane.location,
sender_and_lane.lane,
enqueued_messages,
);
if let Err(e) = Self::send_congested_signal(sender_and_lane) {
log::info!(
target: crate::LOG_TARGET_BRIDGE_DISPATCH,
"Failed to send the 'congested' XCM message to {:?}: {:?}",
sender_and_lane.location,
e,
);
}
}
/// Must be called whenever we receive a message delivery confirmation.
pub fn on_bridge_messages_delivered(
sender_and_lane: &SenderAndLane,
enqueued_messages: MessageNonce,
) {
// skip if we dont want to handle congestion
if !H::supports_congestion_detection() {
return
}
// if we have not sent the congestion signal before, we don't want to do anything
if !Self::is_congested_signal_sent(sender_and_lane.lane) {
return
}
// if the bridge queue is still congested, we don't want to do anything
let is_congested = enqueued_messages > OUTBOUND_LANE_UNCONGESTED_THRESHOLD;
if is_congested {
return
}
log::info!(
target: crate::LOG_TARGET_BRIDGE_DISPATCH,
"Sending 'uncongested' XCM message to {:?}. Lane {:?}: there are\
{} messages queued at the bridge queue",
sender_and_lane.location,
sender_and_lane.lane,
enqueued_messages,
);
if let Err(e) = Self::send_uncongested_signal(sender_and_lane) {
log::info!(
target: crate::LOG_TARGET_BRIDGE_DISPATCH,
"Failed to send the 'uncongested' XCM message to {:?}: {:?}",
sender_and_lane.location,
e,
);
}
}
/// Returns true if we have sent "congested" signal to the `sending_chain_location`.
fn is_congested_signal_sent(lane: LaneId) -> bool {
OutboundLanesCongestedSignals::<H::Runtime, H::MessagesInstance>::get(lane)
}
/// Send congested signal to the `sending_chain_location`.
fn send_congested_signal(sender_and_lane: &SenderAndLane) -> Result<(), SendError> {
if let Some(msg) = H::CongestedMessage::get() {
send_xcm::<H::ToSourceChainSender>(sender_and_lane.location, msg)?;
OutboundLanesCongestedSignals::<H::Runtime, H::MessagesInstance>::insert(
sender_and_lane.lane,
true,
);
}
Ok(())
}
/// Send `uncongested` signal to the `sending_chain_location`.
fn send_uncongested_signal(sender_and_lane: &SenderAndLane) -> Result<(), SendError> {
if let Some(msg) = H::UncongestedMessage::get() {
send_xcm::<H::ToSourceChainSender>(sender_and_lane.location, msg)?;
OutboundLanesCongestedSignals::<H::Runtime, H::MessagesInstance>::remove(
sender_and_lane.lane,
);
}
Ok(())
}
}
/// Adapter for the implementation of `GetVersion`, which attempts to find the minimal
/// configured XCM version between the destination `dest` and the bridge hub location provided as
/// `Get<Location>`.
pub struct XcmVersionOfDestAndRemoteBridge<Version, RemoteBridge>(
sp_std::marker::PhantomData<(Version, RemoteBridge)>,
);
impl<Version: GetVersion, RemoteBridge: Get<MultiLocation>> GetVersion
for XcmVersionOfDestAndRemoteBridge<Version, RemoteBridge>
{
fn get_version_for(dest: &MultiLocation) -> Option<XcmVersion> {
let dest_version = Version::get_version_for(dest);
let bridge_hub_version = Version::get_version_for(&RemoteBridge::get());
match (dest_version, bridge_hub_version) {
(Some(dv), Some(bhv)) => Some(sp_std::cmp::min(dv, bhv)),
(Some(dv), None) => Some(dv),
(None, Some(bhv)) => Some(bhv),
(None, None) => None,
}
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::mock::*;
use bp_messages::OutboundLaneData;
use frame_support::parameter_types;
use pallet_bridge_messages::OutboundLanes;
parameter_types! {
pub TestSenderAndLane: SenderAndLane = SenderAndLane {
location: MultiLocation::new(1, X1(Parachain(1000))),
lane: TEST_LANE_ID,
};
Branislav Kontur
committed
pub TestLanes: sp_std::vec::Vec<(SenderAndLane, (NetworkId, InteriorMultiLocation))> = sp_std::vec![
(TestSenderAndLane::get(), (NetworkId::ByGenesis([0; 32]), InteriorMultiLocation::Here))
];
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
pub DummyXcmMessage: Xcm<()> = Xcm::new();
}
struct DummySendXcm;
impl DummySendXcm {
fn messages_sent() -> u32 {
frame_support::storage::unhashed::get(b"DummySendXcm").unwrap_or(0)
}
}
impl SendXcm for DummySendXcm {
type Ticket = ();
fn validate(
_destination: &mut Option<MultiLocation>,
_message: &mut Option<Xcm<()>>,
) -> SendResult<Self::Ticket> {
Ok(((), Default::default()))
}
fn deliver(_ticket: Self::Ticket) -> Result<XcmHash, SendError> {
let messages_sent: u32 = Self::messages_sent();
frame_support::storage::unhashed::put(b"DummySendXcm", &(messages_sent + 1));
Ok(XcmHash::default())
}
}
struct TestBlobHauler;
impl XcmBlobHauler for TestBlobHauler {
type Runtime = TestRuntime;
type MessagesInstance = ();
type ToSourceChainSender = DummySendXcm;
type CongestedMessage = DummyXcmMessage;
type UncongestedMessage = DummyXcmMessage;
}
Branislav Kontur
committed
type TestBlobHaulerAdapter = XcmBlobHaulerAdapter<TestBlobHauler, TestLanes>;
Branislav Kontur
committed
fn fill_up_lane_to_congestion() -> MessageNonce {
let latest_generated_nonce = OUTBOUND_LANE_CONGESTED_THRESHOLD;
OutboundLanes::<TestRuntime, ()>::insert(
TEST_LANE_ID,
OutboundLaneData {
oldest_unpruned_nonce: 0,
latest_received_nonce: 0,
Branislav Kontur
committed
latest_generated_nonce,
Branislav Kontur
committed
latest_generated_nonce
}
#[test]
fn congested_signal_is_not_sent_twice() {
run_test(|| {
Branislav Kontur
committed
let enqueued = fill_up_lane_to_congestion();
// next sent message leads to congested signal
Branislav Kontur
committed
LocalXcmQueueManager::<TestBlobHauler>::on_bridge_message_enqueued(
&TestSenderAndLane::get(),
enqueued + 1,
);
assert_eq!(DummySendXcm::messages_sent(), 1);
// next sent message => we don't sent another congested signal
Branislav Kontur
committed
LocalXcmQueueManager::<TestBlobHauler>::on_bridge_message_enqueued(
&TestSenderAndLane::get(),
enqueued,
);
assert_eq!(DummySendXcm::messages_sent(), 1);
});
}
#[test]
fn congested_signal_is_not_sent_when_outbound_lane_is_not_congested() {
run_test(|| {
Branislav Kontur
committed
LocalXcmQueueManager::<TestBlobHauler>::on_bridge_message_enqueued(
&TestSenderAndLane::get(),
1,
);
assert_eq!(DummySendXcm::messages_sent(), 0);
});
}
#[test]
fn congested_signal_is_sent_when_outbound_lane_is_congested() {
run_test(|| {
Branislav Kontur
committed
let enqueued = fill_up_lane_to_congestion();
// next sent message leads to congested signal
Branislav Kontur
committed
LocalXcmQueueManager::<TestBlobHauler>::on_bridge_message_enqueued(
&TestSenderAndLane::get(),
enqueued + 1,
);
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
assert_eq!(DummySendXcm::messages_sent(), 1);
assert!(LocalXcmQueueManager::<TestBlobHauler>::is_congested_signal_sent(TEST_LANE_ID));
});
}
#[test]
fn uncongested_signal_is_not_sent_when_messages_are_delivered_at_other_lane() {
run_test(|| {
LocalXcmQueueManager::<TestBlobHauler>::send_congested_signal(&TestSenderAndLane::get()).unwrap();
assert_eq!(DummySendXcm::messages_sent(), 1);
// when we receive a delivery report for other lane, we don't send an uncongested signal
TestBlobHaulerAdapter::on_messages_delivered(LaneId([42, 42, 42, 42]), 0);
assert_eq!(DummySendXcm::messages_sent(), 1);
});
}
#[test]
fn uncongested_signal_is_not_sent_when_we_havent_send_congested_signal_before() {
run_test(|| {
TestBlobHaulerAdapter::on_messages_delivered(TEST_LANE_ID, 0);
assert_eq!(DummySendXcm::messages_sent(), 0);
});
}
#[test]
fn uncongested_signal_is_not_sent_if_outbound_lane_is_still_congested() {
run_test(|| {
LocalXcmQueueManager::<TestBlobHauler>::send_congested_signal(&TestSenderAndLane::get()).unwrap();
assert_eq!(DummySendXcm::messages_sent(), 1);
TestBlobHaulerAdapter::on_messages_delivered(
TEST_LANE_ID,
OUTBOUND_LANE_UNCONGESTED_THRESHOLD + 1,
);
assert_eq!(DummySendXcm::messages_sent(), 1);
});
}
#[test]
fn uncongested_signal_is_sent_if_outbound_lane_is_uncongested() {
run_test(|| {
LocalXcmQueueManager::<TestBlobHauler>::send_congested_signal(&TestSenderAndLane::get()).unwrap();
assert_eq!(DummySendXcm::messages_sent(), 1);
TestBlobHaulerAdapter::on_messages_delivered(
TEST_LANE_ID,
OUTBOUND_LANE_UNCONGESTED_THRESHOLD,
);
assert_eq!(DummySendXcm::messages_sent(), 2);
});
}
}