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// Copyright (C) Parity Technologies (UK) Ltd.
// This file is part of Polkadot.
// Polkadot 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.
// Polkadot 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 Polkadot. If not, see <http://www.gnu.org/licenses/>.
//! Traits and utilities to help with origin mutation and bridging.
use frame_support::{ensure, traits::Get};
use parity_scale_codec::{Decode, Encode};
use sp_std::{convert::TryInto, marker::PhantomData, prelude::*};
use xcm::prelude::*;
use xcm_executor::traits::{validate_export, ExportXcm};
use SendError::*;
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/// Returns the network ID and consensus location within that network of the remote
/// location `dest` which is itself specified as a location relative to the local
/// chain, itself situated at `universal_local` within the consensus universe. If
/// `dest` is not a location in remote consensus, then an error is returned.
pub fn ensure_is_remote(
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universal_local: impl Into<InteriorMultiLocation>,
dest: impl Into<MultiLocation>,
) -> Result<(NetworkId, InteriorMultiLocation), MultiLocation> {
let dest = dest.into();
let universal_local = universal_local.into();
let local_net = match universal_local.global_consensus() {
Ok(x) => x,
Err(_) => return Err(dest),
};
let universal_destination: InteriorMultiLocation = universal_local
.into_location()
.appended_with(dest)
.map_err(|x| x.1)?
.try_into()?;
let (remote_dest, remote_net) = match universal_destination.split_first() {
(d, Some(GlobalConsensus(n))) if n != local_net => (d, n),
_ => return Err(dest),
};
Ok((remote_net, remote_dest))
}
/// Implementation of `SendXcm` which uses the given `ExportXcm` implementation in order to forward
/// the message over a bridge.
///
/// No effort is made to charge for any bridge fees, so this can only be used when it is known
/// that the message sending cannot be abused in any way.
///
/// This is only useful when the local chain has bridging capabilities.
pub struct UnpaidLocalExporter<Exporter, UniversalLocation>(
PhantomData<(Exporter, UniversalLocation)>,
);
impl<Exporter: ExportXcm, UniversalLocation: Get<InteriorMultiLocation>> SendXcm
for UnpaidLocalExporter<Exporter, UniversalLocation>
{
type Ticket = Exporter::Ticket;
fn validate(
dest: &mut Option<MultiLocation>,
xcm: &mut Option<Xcm<()>>,
) -> SendResult<Exporter::Ticket> {
let d = dest.take().ok_or(MissingArgument)?;
let universal_source = UniversalLocation::get();
let devolved = match ensure_is_remote(universal_source, d) {
Ok(x) => x,
Err(d) => {
*dest = Some(d);
return Err(NotApplicable)
},
};
let (network, destination) = devolved;
let xcm = xcm.take().ok_or(SendError::MissingArgument)?;
validate_export::<Exporter>(network, 0, universal_source, destination, xcm)
}
fn deliver(ticket: Exporter::Ticket) -> Result<XcmHash, SendError> {
Exporter::deliver(ticket)
}
}
pub trait ExporterFor {
/// Return the locally-routable bridge (if any) capable of forwarding `message` to the
/// `remote_location` on the remote `network`, together with the payment which is required.
///
/// The payment is specified from the local context, not the bridge chain. This is the
/// total amount to withdraw in to Holding and should cover both payment for the execution on
/// the bridge chain as well as payment for the use of the `ExportMessage` instruction.
fn exporter_for(
network: &NetworkId,
remote_location: &InteriorMultiLocation,
message: &Xcm<()>,
) -> Option<(MultiLocation, Option<MultiAsset>)>;
}
#[impl_trait_for_tuples::impl_for_tuples(30)]
impl ExporterFor for Tuple {
fn exporter_for(
network: &NetworkId,
remote_location: &InteriorMultiLocation,
message: &Xcm<()>,
) -> Option<(MultiLocation, Option<MultiAsset>)> {
for_tuples!( #(
if let Some(r) = Tuple::exporter_for(network, remote_location, message) {
return Some(r);
}
)* );
None
}
}
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/// Configuration item representing a single exporter in the `NetworkExportTable`.
pub struct NetworkExportTableItem {
/// Supported remote network.
pub remote_network: NetworkId,
/// Remote location filter.
/// If `Some`, the requested remote location must be equal to one of the items in the vector.
/// These are locations in the remote network.
/// If `None`, then the check is skipped.
pub remote_location_filter: Option<Vec<InteriorMultiLocation>>,
/// Locally-routable bridge with bridging capabilities to the `remote_network` and
/// `remote_location`. See [`ExporterFor`] for more details.
pub bridge: MultiLocation,
/// The local payment.
/// See [`ExporterFor`] for more details.
pub payment: Option<MultiAsset>,
}
impl NetworkExportTableItem {
pub fn new(
remote_network: NetworkId,
remote_location_filter: Option<Vec<InteriorMultiLocation>>,
bridge: MultiLocation,
payment: Option<MultiAsset>,
) -> Self {
Self { remote_network, remote_location_filter, bridge, payment }
}
}
/// An adapter for the implementation of `ExporterFor`, which attempts to find the
/// `(bridge_location, payment)` for the requested `network` and `remote_location` in the provided
/// `T` table containing various exporters.
pub struct NetworkExportTable<T>(sp_std::marker::PhantomData<T>);
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impl<T: Get<Vec<NetworkExportTableItem>>> ExporterFor for NetworkExportTable<T> {
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remote_location: &InteriorMultiLocation,
_: &Xcm<()>,
) -> Option<(MultiLocation, Option<MultiAsset>)> {
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T::get()
.into_iter()
.find(|item| {
&item.remote_network == network &&
item.remote_location_filter
.as_ref()
.map(|filters| filters.iter().any(|filter| filter == remote_location))
.unwrap_or(true)
})
.map(|item| (item.bridge, item.payment))
pub fn forward_id_for(original_id: &XcmHash) -> XcmHash {
(b"forward_id_for", original_id).using_encoded(sp_io::hashing::blake2_256)
}
/// Implementation of `SendXcm` which wraps the message inside an `ExportMessage` instruction
/// and sends it to a destination known to be able to handle it.
///
/// No effort is made to make payment to the bridge for its services, so the bridge location
/// must have been configured with a barrier rule allowing unpaid execution for this message
/// coming from our origin.
///
/// This is only useful if we have special dispensation by the remote bridges to have the
/// `ExportMessage` instruction executed without payment.
///
/// The `XcmHash` value returned by `deliver` will always be the same as that returned by the
/// message exporter (`Bridges`). Generally this should take notice of the message should it
/// end with the `SetTopic` instruction.
///
/// In the case that the message ends with a `SetTopic(T)` (as should be the case if the top-level
/// router is `EnsureUniqueTopic`), then the forwarding message (i.e. the one carrying the
/// export instruction *to* the bridge in local consensus) will also end with a `SetTopic` whose
/// inner is `forward_id_for(T)`. If this is not the case then the onward message will not be given
/// the `SetTopic` afterword.
pub struct UnpaidRemoteExporter<Bridges, Router, UniversalLocation>(
PhantomData<(Bridges, Router, UniversalLocation)>,
);
impl<Bridges: ExporterFor, Router: SendXcm, UniversalLocation: Get<InteriorMultiLocation>> SendXcm
for UnpaidRemoteExporter<Bridges, Router, UniversalLocation>
{
type Ticket = Router::Ticket;
fn validate(
dest: &mut Option<MultiLocation>,
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msg: &mut Option<Xcm<()>>,
) -> SendResult<Router::Ticket> {
let d = dest.ok_or(MissingArgument)?;
let devolved = ensure_is_remote(UniversalLocation::get(), d).map_err(|_| NotApplicable)?;
let (remote_network, remote_location) = devolved;
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let xcm = msg.take().ok_or(MissingArgument)?;
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// find exporter
let Some((bridge, maybe_payment)) =
Bridges::exporter_for(&remote_network, &remote_location, &xcm)
else {
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// We need to make sure that msg is not consumed in case of `NotApplicable`.
*msg = Some(xcm);
return Err(SendError::NotApplicable)
};
// `xcm` should already end with `SetTopic` - if it does, then extract and derive into
// an onward topic ID.
let maybe_forward_id = match xcm.last() {
Some(SetTopic(t)) => Some(forward_id_for(t)),
_ => None,
};
// We then send a normal message to the bridge asking it to export the prepended
// message to the remote chain. This will only work if the bridge will do the message
// export for free. Common-good chains will typically be afforded this.
let mut message = Xcm(vec![
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UnpaidExecution { weight_limit: Unlimited, check_origin: None },
ExportMessage { network: remote_network, destination: remote_location, xcm },
]);
if let Some(forward_id) = maybe_forward_id {
message.0.push(SetTopic(forward_id));
}
fn deliver(validation: Self::Ticket) -> Result<XcmHash, SendError> {
Router::deliver(validation)
}
}
/// Implementation of `SendXcm` which wraps the message inside an `ExportMessage` instruction
/// and sends it to a destination known to be able to handle it.
///
/// The `ExportMessage` instruction on the bridge is paid for from the local chain's sovereign
/// account on the bridge. The amount paid is determined through the `ExporterFor` trait.
///
/// The `XcmHash` value returned by `deliver` will always be the same as that returned by the
/// message exporter (`Bridges`). Generally this should take notice of the message should it
/// end with the `SetTopic` instruction.
///
/// In the case that the message ends with a `SetTopic(T)` (as should be the case if the top-level
/// router is `EnsureUniqueTopic`), then the forwarding message (i.e. the one carrying the
/// export instruction *to* the bridge in local consensus) will also end with a `SetTopic` whose
/// inner is `forward_id_for(T)`. If this is not the case then the onward message will not be given
/// the `SetTopic` afterword.
pub struct SovereignPaidRemoteExporter<Bridges, Router, UniversalLocation>(
PhantomData<(Bridges, Router, UniversalLocation)>,
);
impl<Bridges: ExporterFor, Router: SendXcm, UniversalLocation: Get<InteriorMultiLocation>> SendXcm
for SovereignPaidRemoteExporter<Bridges, Router, UniversalLocation>
{
type Ticket = Router::Ticket;
fn validate(
dest: &mut Option<MultiLocation>,
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msg: &mut Option<Xcm<()>>,
) -> SendResult<Router::Ticket> {
let d = *dest.as_ref().ok_or(MissingArgument)?;
let devolved = ensure_is_remote(UniversalLocation::get(), d).map_err(|_| NotApplicable)?;
let (remote_network, remote_location) = devolved;
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let xcm = msg.take().ok_or(MissingArgument)?;
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// find exporter
let Some((bridge, maybe_payment)) =
Bridges::exporter_for(&remote_network, &remote_location, &xcm)
else {
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// We need to make sure that msg is not consumed in case of `NotApplicable`.
*msg = Some(xcm);
return Err(SendError::NotApplicable)
};
// `xcm` should already end with `SetTopic` - if it does, then extract and derive into
// an onward topic ID.
let maybe_forward_id = match xcm.last() {
Some(SetTopic(t)) => Some(forward_id_for(t)),
_ => None,
};
let local_from_bridge =
UniversalLocation::get().invert_target(&bridge).map_err(|_| Unroutable)?;
let export_instruction =
ExportMessage { network: remote_network, destination: remote_location, xcm };
let mut message = Xcm(if let Some(ref payment) = maybe_payment {
let fees = payment
.clone()
.reanchored(&bridge, UniversalLocation::get())
.map_err(|_| Unroutable)?;
vec![
WithdrawAsset(fees.clone().into()),
BuyExecution { fees, weight_limit: Unlimited },
export_instruction,
DepositAsset { assets: All.into(), beneficiary: local_from_bridge },
]
} else {
vec![export_instruction]
});
if let Some(forward_id) = maybe_forward_id {
message.0.push(SetTopic(forward_id));
}
// We then send a normal message to the bridge asking it to export the prepended
// message to the remote chain.
let (v, mut cost) = validate_send::<Router>(bridge, message)?;
if let Some(bridge_payment) = maybe_payment {
cost.push(bridge_payment);
}
Ok((v, cost))
}
fn deliver(ticket: Router::Ticket) -> Result<XcmHash, SendError> {
Router::deliver(ticket)
}
}
pub trait DispatchBlob {
/// Takes an incoming blob from over some point-to-point link (usually from some sort of
/// inter-consensus bridge) and then does what needs to be done with it. Usually this means
/// forwarding it on into some other location sharing our consensus or possibly just enqueuing
/// it for execution locally if it is destined for the local chain.
///
/// NOTE: The API does not provide for any kind of weight or fee management; the size of the
/// `blob` is known to the caller and so the operation must have a linear weight relative to
/// `blob`'s length. This means that you will generally only want to **enqueue** the blob, not
/// enact it. Fees must be handled by the caller.
fn dispatch_blob(blob: Vec<u8>) -> Result<(), DispatchBlobError>;
}
pub trait HaulBlob {
/// Sends a blob over some point-to-point link. This will generally be implemented by a bridge.
fn haul_blob(blob: Vec<u8>) -> Result<(), HaulBlobError>;
}
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum HaulBlobError {
/// Represents point-to-point link failure with a human-readable explanation of the specific
/// issue is provided.
Transport(&'static str),
}
impl From<HaulBlobError> for SendError {
fn from(err: HaulBlobError) -> Self {
match err {
HaulBlobError::Transport(reason) => SendError::Transport(reason),
}
}
}
#[derive(Clone, Encode, Decode)]
pub struct BridgeMessage {
/// The message destination as a *Universal Location*. This means it begins with a
/// `GlobalConsensus` junction describing the network under which global consensus happens.
/// If this does not match our global consensus then it's a fatal error.
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pub universal_dest: VersionedInteriorMultiLocation,
pub message: VersionedXcm<()>,
}
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum DispatchBlobError {
Unbridgable,
InvalidEncoding,
UnsupportedLocationVersion,
UnsupportedXcmVersion,
RoutingError,
NonUniversalDestination,
WrongGlobal,
}
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pub struct BridgeBlobDispatcher<Router, OurPlace, OurPlaceBridgeInstance>(
PhantomData<(Router, OurPlace, OurPlaceBridgeInstance)>,
);
impl<
Router: SendXcm,
OurPlace: Get<InteriorMultiLocation>,
OurPlaceBridgeInstance: Get<Option<InteriorMultiLocation>>,
> DispatchBlob for BridgeBlobDispatcher<Router, OurPlace, OurPlaceBridgeInstance>
{
fn dispatch_blob(blob: Vec<u8>) -> Result<(), DispatchBlobError> {
let our_universal = OurPlace::get();
let our_global =
our_universal.global_consensus().map_err(|()| DispatchBlobError::Unbridgable)?;
let BridgeMessage { universal_dest, message } =
Decode::decode(&mut &blob[..]).map_err(|_| DispatchBlobError::InvalidEncoding)?;
let universal_dest: InteriorMultiLocation = universal_dest
.try_into()
.map_err(|_| DispatchBlobError::UnsupportedLocationVersion)?;
// `universal_dest` is the desired destination within the universe: first we need to check
// we're in the right global consensus.
let intended_global = universal_dest
.global_consensus()
.map_err(|()| DispatchBlobError::NonUniversalDestination)?;
ensure!(intended_global == our_global, DispatchBlobError::WrongGlobal);
let dest = universal_dest.relative_to(&our_universal);
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let mut message: Xcm<()> =
message.try_into().map_err(|_| DispatchBlobError::UnsupportedXcmVersion)?;
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// Prepend our bridge instance discriminator.
// Can be used for fine-grained control of origin on destination in case of multiple bridge
// instances, e.g. restrict `type UniversalAliases` and `UniversalOrigin` instruction to
// trust just particular bridge instance for `NetworkId`.
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if let Some(bridge_instance) = OurPlaceBridgeInstance::get() {
message.0.insert(0, DescendOrigin(bridge_instance));
}
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let _ = send_xcm::<Router>(dest, message).map_err(|_| DispatchBlobError::RoutingError)?;
Ok(())
}
}
pub struct HaulBlobExporter<Bridge, BridgedNetwork, Price>(
PhantomData<(Bridge, BridgedNetwork, Price)>,
);
impl<Bridge: HaulBlob, BridgedNetwork: Get<NetworkId>, Price: Get<MultiAssets>> ExportXcm
for HaulBlobExporter<Bridge, BridgedNetwork, Price>
{
type Ticket = (Vec<u8>, XcmHash);
fn validate(
network: NetworkId,
_channel: u32,
universal_source: &mut Option<InteriorMultiLocation>,
destination: &mut Option<InteriorMultiLocation>,
message: &mut Option<Xcm<()>>,
) -> Result<((Vec<u8>, XcmHash), MultiAssets), SendError> {
let bridged_network = BridgedNetwork::get();
ensure!(&network == &bridged_network, SendError::NotApplicable);
// We don't/can't use the `channel` for this adapter.
let dest = destination.take().ok_or(SendError::MissingArgument)?;
let universal_dest = match dest.pushed_front_with(GlobalConsensus(bridged_network)) {
Ok(d) => d.into(),
Err((dest, _)) => {
*destination = Some(dest);
return Err(SendError::NotApplicable)
},
};
let (local_net, local_sub) = universal_source
.take()
.ok_or(SendError::MissingArgument)?
.split_global()
.map_err(|()| SendError::Unroutable)?;
let mut message = message.take().ok_or(SendError::MissingArgument)?;
let maybe_id = match message.last() {
Some(SetTopic(t)) => Some(*t),
_ => None,
};
message.0.insert(0, UniversalOrigin(GlobalConsensus(local_net)));
message.0.insert(1, DescendOrigin(local_sub));
let message = VersionedXcm::from(message);
let id = maybe_id.unwrap_or_else(|| message.using_encoded(sp_io::hashing::blake2_256));
let blob = BridgeMessage { universal_dest, message }.encode();
Ok(((blob, id), Price::get()))
fn deliver((blob, id): (Vec<u8>, XcmHash)) -> Result<XcmHash, SendError> {
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}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn ensure_is_remote_works() {
// A Kusama parachain is remote from the Polkadot Relay.
let x = ensure_is_remote(Polkadot, (Parent, Kusama, Parachain(1000)));
assert_eq!(x, Ok((Kusama, Parachain(1000).into())));
// Polkadot Relay is remote from a Kusama parachain.
let x = ensure_is_remote((Kusama, Parachain(1000)), (Parent, Parent, Polkadot));
assert_eq!(x, Ok((Polkadot, Here)));
// Our own parachain is local.
let x = ensure_is_remote(Polkadot, Parachain(1000));
assert_eq!(x, Err(Parachain(1000).into()));
// Polkadot's parachain is not remote if we are Polkadot.
let x = ensure_is_remote(Polkadot, (Parent, Polkadot, Parachain(1000)));
assert_eq!(x, Err((Parent, Polkadot, Parachain(1000)).into()));
// If we don't have a consensus ancestor, then we cannot determine remoteness.
let x = ensure_is_remote((), (Parent, Polkadot, Parachain(1000)));
assert_eq!(x, Err((Parent, Polkadot, Parachain(1000)).into()));
}
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pub struct OkSender;
impl SendXcm for OkSender {
type Ticket = ();
fn validate(
_destination: &mut Option<MultiLocation>,
_message: &mut Option<Xcm<()>>,
) -> SendResult<Self::Ticket> {
Ok(((), MultiAssets::new()))
}
fn deliver(_ticket: Self::Ticket) -> Result<XcmHash, SendError> {
Ok([0; 32])
}
}
/// Generic test case asserting that dest and msg is not consumed by `validate` implementation
/// of `SendXcm` in case of expected result.
fn ensure_validate_does_not_consume_dest_or_msg<S: SendXcm>(
dest: MultiLocation,
assert_result: impl Fn(SendResult<S::Ticket>),
) {
let mut dest_wrapper = Some(dest);
let msg = Xcm::<()>::new();
let mut msg_wrapper = Some(msg.clone());
assert_result(S::validate(&mut dest_wrapper, &mut msg_wrapper));
// ensure dest and msg are untouched
assert_eq!(Some(dest), dest_wrapper);
assert_eq!(Some(msg), msg_wrapper);
}
#[test]
fn remote_exporters_does_not_consume_dest_or_msg_on_not_applicable() {
frame_support::parameter_types! {
pub Local: NetworkId = ByGenesis([0; 32]);
pub UniversalLocation: InteriorMultiLocation = X2(GlobalConsensus(Local::get()), Parachain(1234));
pub DifferentRemote: NetworkId = ByGenesis([22; 32]);
// no routers
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pub BridgeTable: Vec<NetworkExportTableItem> = vec![];
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}
// check with local destination (should be remote)
let local_dest = (Parent, Parachain(5678)).into();
assert!(ensure_is_remote(UniversalLocation::get(), local_dest).is_err());
ensure_validate_does_not_consume_dest_or_msg::<
UnpaidRemoteExporter<NetworkExportTable<BridgeTable>, OkSender, UniversalLocation>,
>(local_dest, |result| assert_eq!(Err(NotApplicable), result));
ensure_validate_does_not_consume_dest_or_msg::<
SovereignPaidRemoteExporter<
NetworkExportTable<BridgeTable>,
OkSender,
UniversalLocation,
>,
>(local_dest, |result| assert_eq!(Err(NotApplicable), result));
// check with not applicable destination
let remote_dest = (Parent, Parent, DifferentRemote::get()).into();
assert!(ensure_is_remote(UniversalLocation::get(), remote_dest).is_ok());
ensure_validate_does_not_consume_dest_or_msg::<
UnpaidRemoteExporter<NetworkExportTable<BridgeTable>, OkSender, UniversalLocation>,
>(remote_dest, |result| assert_eq!(Err(NotApplicable), result));
ensure_validate_does_not_consume_dest_or_msg::<
SovereignPaidRemoteExporter<
NetworkExportTable<BridgeTable>,
OkSender,
UniversalLocation,
>,
>(remote_dest, |result| assert_eq!(Err(NotApplicable), result));
}
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#[test]
fn network_export_table_works() {
frame_support::parameter_types! {
pub NetworkA: NetworkId = ByGenesis([0; 32]);
pub Parachain1000InNetworkA: InteriorMultiLocation = X1(Parachain(1000));
pub Parachain2000InNetworkA: InteriorMultiLocation = X1(Parachain(2000));
pub NetworkB: NetworkId = ByGenesis([1; 32]);
pub BridgeToALocation: MultiLocation = MultiLocation::new(1, X1(Parachain(1234)));
pub BridgeToBLocation: MultiLocation = MultiLocation::new(1, X1(Parachain(4321)));
pub PaymentForNetworkAAndParachain2000: MultiAsset = (MultiLocation::parent(), 150).into();
pub BridgeTable: sp_std::vec::Vec<NetworkExportTableItem> = sp_std::vec![
// NetworkA allows `Parachain(1000)` as remote location WITHOUT payment.
NetworkExportTableItem::new(
NetworkA::get(),
Some(vec![Parachain1000InNetworkA::get()]),
BridgeToALocation::get(),
None
),
// NetworkA allows `Parachain(2000)` as remote location WITH payment.
NetworkExportTableItem::new(
NetworkA::get(),
Some(vec![Parachain2000InNetworkA::get()]),
BridgeToALocation::get(),
Some(PaymentForNetworkAAndParachain2000::get())
),
// NetworkB allows all remote location.
NetworkExportTableItem::new(
NetworkB::get(),
None,
BridgeToBLocation::get(),
None
)
];
}
let test_data = vec![
(NetworkA::get(), X1(Parachain(1000)), Some((BridgeToALocation::get(), None))),
(NetworkA::get(), X2(Parachain(1000), GeneralIndex(1)), None),
(
NetworkA::get(),
X1(Parachain(2000)),
Some((BridgeToALocation::get(), Some(PaymentForNetworkAAndParachain2000::get()))),
),
(NetworkA::get(), X2(Parachain(2000), GeneralIndex(1)), None),
(NetworkA::get(), X1(Parachain(3000)), None),
(NetworkB::get(), X1(Parachain(1000)), Some((BridgeToBLocation::get(), None))),
(NetworkB::get(), X1(Parachain(2000)), Some((BridgeToBLocation::get(), None))),
(NetworkB::get(), X1(Parachain(3000)), Some((BridgeToBLocation::get(), None))),
];
for (network, remote_location, expected_result) in test_data {
assert_eq!(
NetworkExportTable::<BridgeTable>::exporter_for(
&network,
&remote_location,
&Xcm::default()
),
expected_result,
"expected_result: {:?} not matched for network: {:?} and remote_location: {:?}",
expected_result,
network,
remote_location,
)
}
}