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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/>.
#![cfg_attr(not(feature = "std"), no_std)]
use parity_scale_codec::{Decode, Encode};
use sp_core::defer;
use sp_io::hashing::blake2_128;
use sp_std::{fmt::Debug, marker::PhantomData, prelude::*};
validate_export, AssetExchange, AssetLock, CallDispatcher, ClaimAssets, ConvertOrigin,
DropAssets, Enact, ExportXcm, FeeManager, FeeReason, OnResponse, Properties, ShouldExecute,
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TransactAsset, VersionChangeNotifier, WeightBounds, WeightTrader, XcmAssetTransfers,
pub use config::Config;
/// A struct to specify how fees are being paid.
#[derive(Copy, Clone, Debug, PartialEq, Eq)]
pub struct FeesMode {
/// If true, then the fee assets are taken directly from the origin's on-chain account,
/// otherwise the fee assets are taken from the holding register.
///
/// Defaults to false.
pub jit_withdraw: bool,
}
const RECURSION_LIMIT: u8 = 10;
environmental::environmental!(recursion_count: u8);
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pub struct XcmExecutor<Config: config::Config> {
holding: Assets,
holding_limit: usize,
context: XcmContext,
original_origin: MultiLocation,
trader: Config::Trader,
/// The most recent error result and instruction index into the fragment in which it occurred,
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/// if any.
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/// The surplus weight, defined as the amount by which `max_weight` is
/// an over-estimate of the actual weight consumed. We do it this way to avoid needing the
/// execution engine to keep track of all instructions' weights (it only needs to care about
/// the weight of dynamically determined instructions such as `Transact`).
total_surplus: Weight,
total_refunded: Weight,
error_handler: Xcm<Config::RuntimeCall>,
error_handler_weight: Weight,
appendix: Xcm<Config::RuntimeCall>,
appendix_weight: Weight,
transact_status: MaybeErrorCode,
fees_mode: FeesMode,
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_config: PhantomData<Config>,
}
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#[cfg(feature = "runtime-benchmarks")]
impl<Config: config::Config> XcmExecutor<Config> {
pub fn holding(&self) -> &Assets {
&self.holding
}
pub fn set_holding(&mut self, v: Assets) {
self.holding = v
}
pub fn holding_limit(&self) -> &usize {
&self.holding_limit
}
pub fn set_holding_limit(&mut self, v: usize) {
self.holding_limit = v
}
pub fn origin(&self) -> &Option<MultiLocation> {
&self.context.origin
}
pub fn set_origin(&mut self, v: Option<MultiLocation>) {
self.context.origin = v
}
pub fn original_origin(&self) -> &MultiLocation {
&self.original_origin
}
pub fn set_original_origin(&mut self, v: MultiLocation) {
self.original_origin = v
}
pub fn trader(&self) -> &Config::Trader {
&self.trader
}
pub fn set_trader(&mut self, v: Config::Trader) {
self.trader = v
}
pub fn error(&self) -> &Option<(u32, XcmError)> {
&self.error
}
pub fn set_error(&mut self, v: Option<(u32, XcmError)>) {
self.error = v
}
pub fn total_surplus(&self) -> &Weight {
&self.total_surplus
}
pub fn set_total_surplus(&mut self, v: Weight) {
self.total_surplus = v
}
pub fn total_refunded(&self) -> &Weight {
&self.total_refunded
}
pub fn set_total_refunded(&mut self, v: Weight) {
self.total_refunded = v
}
pub fn error_handler(&self) -> &Xcm<Config::RuntimeCall> {
&self.error_handler
}
pub fn set_error_handler(&mut self, v: Xcm<Config::RuntimeCall>) {
self.error_handler = v
}
pub fn error_handler_weight(&self) -> &Weight {
&self.error_handler_weight
}
pub fn set_error_handler_weight(&mut self, v: Weight) {
self.error_handler_weight = v
}
pub fn appendix(&self) -> &Xcm<Config::RuntimeCall> {
&self.appendix
}
pub fn set_appendix(&mut self, v: Xcm<Config::RuntimeCall>) {
self.appendix = v
}
pub fn appendix_weight(&self) -> &Weight {
&self.appendix_weight
}
pub fn set_appendix_weight(&mut self, v: Weight) {
self.appendix_weight = v
}
pub fn transact_status(&self) -> &MaybeErrorCode {
&self.transact_status
}
pub fn set_transact_status(&mut self, v: MaybeErrorCode) {
self.transact_status = v
}
pub fn fees_mode(&self) -> &FeesMode {
&self.fees_mode
}
pub fn set_fees_mode(&mut self, v: FeesMode) {
self.fees_mode = v
}
pub fn topic(&self) -> &Option<[u8; 32]> {
&self.context.topic
}
pub fn set_topic(&mut self, v: Option<[u8; 32]>) {
self.context.topic = v;
}
}
pub struct WeighedMessage<Call>(Weight, Xcm<Call>);
impl<C> PreparedMessage for WeighedMessage<C> {
fn weight_of(&self) -> Weight {
self.0
}
}
impl<Config: config::Config> ExecuteXcm<Config::RuntimeCall> for XcmExecutor<Config> {
type Prepared = WeighedMessage<Config::RuntimeCall>;
fn prepare(
) -> Result<Self::Prepared, Xcm<Config::RuntimeCall>> {
match Config::Weigher::weight(&mut message) {
Ok(weight) => Ok(WeighedMessage(weight, message)),
Err(_) => Err(message),
}
}
fn execute(
origin: impl Into<MultiLocation>,
WeighedMessage(xcm_weight, mut message): WeighedMessage<Config::RuntimeCall>,
id: &mut XcmHash,
weight_credit: Weight,
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let origin = origin.into();
log::trace!(
target: "xcm::execute_xcm_in_credit",
"origin: {origin:?}, message: {message:?}, weight_credit: {weight_credit:?}",
let mut properties = Properties { weight_credit, message_id: None };
if let Err(e) = Config::Barrier::should_execute(
&origin,
message.inner_mut(),
xcm_weight,
"Barrier blocked execution! Error: {e:?}. \
(origin: {origin:?}, message: {message:?}, properties: {properties:?})",
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return Outcome::Error(XcmError::Barrier)
}
*id = properties.message_id.unwrap_or(*id);
let mut vm = Self::new(origin, *id);
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while !message.0.is_empty() {
log::trace!(target: "xcm::execute_xcm_in_credit", "result: {result:?}");
message = if let Err(error) = result {
vm.total_surplus.saturating_accrue(error.weight);
vm.error = Some((error.index, error.xcm_error));
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vm.take_error_handler().or_else(|| vm.take_appendix())
} else {
vm.drop_error_handler();
vm.take_appendix()
}
}
vm.post_process(xcm_weight)
}
fn charge_fees(origin: impl Into<MultiLocation>, fees: MultiAssets) -> XcmResult {
let origin = origin.into();
if !Config::FeeManager::is_waived(Some(&origin), FeeReason::ChargeFees) {
for asset in fees.inner() {
Config::AssetTransactor::withdraw_asset(&asset, &origin, None)?;
}
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Config::FeeManager::handle_fee(fees, None, FeeReason::ChargeFees);
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impl<Config: config::Config> XcmAssetTransfers for XcmExecutor<Config> {
type IsReserve = Config::IsReserve;
type IsTeleporter = Config::IsTeleporter;
type AssetTransactor = Config::AssetTransactor;
}
#[derive(Debug)]
pub struct ExecutorError {
pub index: u32,
pub xcm_error: XcmError,
}
#[cfg(feature = "runtime-benchmarks")]
impl From<ExecutorError> for frame_benchmarking::BenchmarkError {
fn from(error: ExecutorError) -> Self {
log::error!(
"XCM ERROR >> Index: {:?}, Error: {:?}, Weight: {:?}",
error.index,
error.xcm_error,
error.weight
);
Self::Stop("xcm executor error: see error logs")
}
}
pub fn new(origin: impl Into<MultiLocation>, message_id: XcmHash) -> Self {
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let origin = origin.into();
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Self {
holding: Assets::new(),
holding_limit: Config::MaxAssetsIntoHolding::get() as usize,
context: XcmContext { origin: Some(origin), message_id, topic: None },
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trader: Config::Trader::new(),
error: None,
total_surplus: Weight::zero(),
total_refunded: Weight::zero(),
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error_handler: Xcm(vec![]),
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appendix: Xcm(vec![]),
appendix_weight: Weight::zero(),
transact_status: Default::default(),
fees_mode: FeesMode { jit_withdraw: false },
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_config: PhantomData,
}
/// Execute any final operations after having executed the XCM message.
/// This includes refunding surplus weight, trapping extra holding funds, and returning any
/// errors during execution.
pub fn post_process(mut self, xcm_weight: Weight) -> Outcome {
// We silently drop any error from our attempt to refund the surplus as it's a charitable
// thing so best-effort is all we will do.
let _ = self.refund_surplus();
drop(self.trader);
let mut weight_used = xcm_weight.saturating_sub(self.total_surplus);
if !self.holding.is_empty() {
log::trace!(
target: "xcm::execute_xcm_in_credit",
"Trapping assets in holding register: {:?}, context: {:?} (original_origin: {:?})",
self.holding, self.context, self.original_origin,
);
let effective_origin = self.context.origin.as_ref().unwrap_or(&self.original_origin);
let trap_weight =
Config::AssetTrap::drop_assets(effective_origin, self.holding, &self.context);
weight_used.saturating_accrue(trap_weight);
};
match self.error {
None => Outcome::Complete(weight_used),
// TODO: #2841 #REALWEIGHT We should deduct the cost of any instructions following
// the error which didn't end up being executed.
Some((_i, e)) => {
log::trace!(target: "xcm::execute_xcm_in_credit", "Execution errored at {:?}: {:?} (original_origin: {:?})", _i, e, self.original_origin);
Outcome::Incomplete(weight_used, e)
},
}
}
fn origin_ref(&self) -> Option<&MultiLocation> {
self.context.origin.as_ref()
}
fn cloned_origin(&self) -> Option<MultiLocation> {
self.context.origin
}
/// Send an XCM, charging fees from Holding as needed.
fn send(
&mut self,
dest: MultiLocation,
msg: Xcm<()>,
reason: FeeReason,
) -> Result<XcmHash, XcmError> {
let (ticket, fee) = validate_send::<Config::XcmSender>(dest, msg)?;
self.take_fee(fee, reason)?;
Config::XcmSender::deliver(ticket).map_err(Into::into)
}
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/// Remove the registered error handler and return it. Do not refund its weight.
fn take_error_handler(&mut self) -> Xcm<Config::RuntimeCall> {
let mut r = Xcm::<Config::RuntimeCall>(vec![]);
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sp_std::mem::swap(&mut self.error_handler, &mut r);
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r
}
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/// Drop the registered error handler and refund its weight.
fn drop_error_handler(&mut self) {
self.error_handler = Xcm::<Config::RuntimeCall>(vec![]);
self.total_surplus.saturating_accrue(self.error_handler_weight);
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}
/// Remove the registered appendix and return it.
fn take_appendix(&mut self) -> Xcm<Config::RuntimeCall> {
let mut r = Xcm::<Config::RuntimeCall>(vec![]);
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sp_std::mem::swap(&mut self.appendix, &mut r);
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r
}
fn subsume_asset(&mut self, asset: MultiAsset) -> Result<(), XcmError> {
// worst-case, holding.len becomes 2 * holding_limit.
ensure!(self.holding.len() < self.holding_limit * 2, XcmError::HoldingWouldOverflow);
self.holding.subsume(asset);
Ok(())
}
fn subsume_assets(&mut self, assets: Assets) -> Result<(), XcmError> {
// worst-case, holding.len becomes 2 * holding_limit.
// this guarantees that if holding.len() == holding_limit and you have holding_limit more
// items (which has a best case outcome of holding.len() == holding_limit), then you'll
// be guaranteed of making the operation.
let worst_case_holding_len = self.holding.len() + assets.len();
ensure!(worst_case_holding_len <= self.holding_limit * 2, XcmError::HoldingWouldOverflow);
self.holding.subsume_assets(assets);
Ok(())
}
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/// Refund any unused weight.
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let current_surplus = self.total_surplus.saturating_sub(self.total_refunded);
self.total_refunded.saturating_accrue(current_surplus);
if let Some(w) = self.trader.refund_weight(current_surplus, &self.context) {
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}
}
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}
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fn take_fee(&mut self, fee: MultiAssets, reason: FeeReason) -> XcmResult {
if Config::FeeManager::is_waived(self.origin_ref(), reason) {
return Ok(())
}
log::trace!(
target: "xcm::fees",
"taking fee: {:?} from origin_ref: {:?} in fees_mode: {:?} for a reason: {:?}",
fee,
self.origin_ref(),
self.fees_mode,
reason,
);
let paid = if self.fees_mode.jit_withdraw {
let origin = self.origin_ref().ok_or(XcmError::BadOrigin)?;
for asset in fee.inner() {
Config::AssetTransactor::withdraw_asset(&asset, origin, Some(&self.context))?;
}
fee
} else {
self.holding.try_take(fee.into()).map_err(|_| XcmError::NotHoldingFees)?.into()
};
Config::FeeManager::handle_fee(paid, Some(&self.context), reason);
Ok(())
}
/// Calculates what `local_querier` would be from the perspective of `destination`.
fn to_querier(
local_querier: Option<MultiLocation>,
destination: &MultiLocation,
) -> Result<Option<MultiLocation>, XcmError> {
Ok(match local_querier {
None => None,
Some(q) => Some(
q.reanchored(&destination, Config::UniversalLocation::get())
.map_err(|_| XcmError::ReanchorFailed)?,
),
})
}
/// Send a bare `QueryResponse` message containing `response` informed by the given `info`.
///
/// The `local_querier` argument is the querier (if any) specified from the *local* perspective.
fn respond(
&mut self,
local_querier: Option<MultiLocation>,
response: Response,
info: QueryResponseInfo,
fee_reason: FeeReason,
) -> Result<XcmHash, XcmError> {
let querier = Self::to_querier(local_querier, &info.destination)?;
let QueryResponseInfo { destination, query_id, max_weight } = info;
let instruction = QueryResponse { query_id, response, max_weight, querier };
let message = Xcm(vec![instruction]);
self.send(destination, message, fee_reason)
}
fn try_reanchor(
asset: MultiAsset,
destination: &MultiLocation,
) -> Result<(MultiAsset, InteriorMultiLocation), XcmError> {
let reanchor_context = Config::UniversalLocation::get();
let asset = asset
.reanchored(&destination, reanchor_context)
.map_err(|()| XcmError::ReanchorFailed)?;
Ok((asset, reanchor_context))
}
fn try_reanchor_multilocation(
location: MultiLocation,
destination: &MultiLocation,
) -> Result<(MultiLocation, InteriorMultiLocation), XcmError> {
let reanchor_context = Config::UniversalLocation::get();
let location = location
.reanchored(&destination, reanchor_context)
.map_err(|_| XcmError::ReanchorFailed)?;
Ok((location, reanchor_context))
}
/// NOTE: Any assets which were unable to be reanchored are introduced into `failed_bin`.
fn reanchored(
mut assets: Assets,
dest: &MultiLocation,
maybe_failed_bin: Option<&mut Assets>,
) -> MultiAssets {
let reanchor_context = Config::UniversalLocation::get();
assets.reanchor(dest, reanchor_context, maybe_failed_bin);
assets.into_assets_iter().collect::<Vec<_>>().into()
}
#[cfg(feature = "runtime-benchmarks")]
pub fn bench_process(&mut self, xcm: Xcm<Config::RuntimeCall>) -> Result<(), ExecutorError> {
self.process(xcm)
}
fn process(&mut self, xcm: Xcm<Config::RuntimeCall>) -> Result<(), ExecutorError> {
log::trace!(
target: "xcm::process",
"origin: {:?}, total_surplus/refunded: {:?}/{:?}, error_handler_weight: {:?}",
self.origin_ref(),
self.total_surplus,
self.total_refunded,
self.error_handler_weight,
);
let mut result = Ok(());
for (i, instr) in xcm.0.into_iter().enumerate() {
match &mut result {
r @ Ok(()) => {
// Initialize the recursion count only the first time we hit this code in our
// potential recursive execution.
let inst_res = recursion_count::using_once(&mut 1, || {
recursion_count::with(|count| {
if *count > RECURSION_LIMIT {
return Err(XcmError::ExceedsStackLimit)
}
*count = count.saturating_add(1);
Ok(())
})
// This should always return `Some`, but let's play it safe.
.unwrap_or(Ok(()))?;
// Ensure that we always decrement the counter whenever we finish processing
// the instruction.
defer! {
recursion_count::with(|count| {
*count = count.saturating_sub(1);
});
}
self.process_instruction(instr)
});
if let Err(e) = inst_res {
log::trace!(target: "xcm::execute", "!!! ERROR: {:?}", e);
*r = Err(ExecutorError {
index: i as u32,
xcm_error: e,
weight: Weight::zero(),
});
}
},
Err(ref mut error) =>
if let Ok(x) = Config::Weigher::instr_weight(&instr) {
error.weight.saturating_accrue(x)
},
}
}
result
}
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/// Process a single XCM instruction, mutating the state of the XCM virtual machine.
fn process_instruction(
&mut self,
instr: Instruction<Config::RuntimeCall>,
) -> Result<(), XcmError> {
log::trace!(
target: "xcm::process_instruction",
"=== {:?}",
instr
);
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match instr {
WithdrawAsset(assets) => {
// Take `assets` from the origin account (on-chain) and place in holding.
let origin = *self.origin_ref().ok_or(XcmError::BadOrigin)?;
for asset in assets.into_inner().into_iter() {
Config::AssetTransactor::withdraw_asset(&asset, &origin, Some(&self.context))?;
self.subsume_asset(asset)?;
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Ok(())
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ReserveAssetDeposited(assets) => {
// check whether we trust origin to be our reserve location for this asset.
let origin = *self.origin_ref().ok_or(XcmError::BadOrigin)?;
for asset in assets.into_inner().into_iter() {
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// Must ensure that we recognise the asset as being managed by the origin.
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Ok(())
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TransferAsset { assets, beneficiary } => {
// Take `assets` from the origin account (on-chain) and place into dest account.
Config::AssetTransactor::transfer_asset(
&asset,
origin,
&beneficiary,
&self.context,
)?;
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Ok(())
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TransferReserveAsset { mut assets, dest, xcm } => {
// Take `assets` from the origin account (on-chain) and place into dest account.
Config::AssetTransactor::transfer_asset(asset, origin, &dest, &self.context)?;
let reanchor_context = Config::UniversalLocation::get();
assets.reanchor(&dest, reanchor_context).map_err(|()| XcmError::LocationFull)?;
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let mut message = vec![ReserveAssetDeposited(assets), ClearOrigin];
message.extend(xcm.0.into_iter());
self.send(dest, Xcm(message), FeeReason::TransferReserveAsset)?;
Ok(())
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ReceiveTeleportedAsset(assets) => {
let origin = *self.origin_ref().ok_or(XcmError::BadOrigin)?;
// check whether we trust origin to teleport this asset to us via config trait.
// We only trust the origin to send us assets that they identify as their
// sovereign assets.
// We should check that the asset can actually be teleported in (for this to be
// in error, there would need to be an accounting violation by one of the
// trusted chains, so it's unlikely, but we don't want to punish a possibly
// innocent chain/user).
Config::AssetTransactor::can_check_in(&origin, asset, &self.context)?;
for asset in assets.into_inner().into_iter() {
Config::AssetTransactor::check_in(&origin, &asset, &self.context);
self.subsume_asset(asset)?;
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Ok(())
Transact { origin_kind, require_weight_at_most, mut call } => {
// We assume that the Relay-chain is allowed to use transact on this parachain.
let origin = *self.origin_ref().ok_or_else(|| {
log::trace!(
target: "xcm::process_instruction::transact",
"No origin provided",
);
XcmError::BadOrigin
})?;
// TODO: #2841 #TRANSACTFILTER allow the trait to issue filters for the relay-chain
let message_call = call.take_decoded().map_err(|_| {
log::trace!(
target: "xcm::process_instruction::transact",
"Failed to decode call",
);
XcmError::FailedToDecode
})?;
log::trace!(
target: "xcm::process_instruction::transact",
"Processing call: {message_call:?}",
);
if !Config::SafeCallFilter::contains(&message_call) {
log::trace!(
target: "xcm::process_instruction::transact",
"Call filtered by `SafeCallFilter`",
);
return Err(XcmError::NoPermission)
}
let dispatch_origin = Config::OriginConverter::convert_origin(origin, origin_kind)
.map_err(|_| {
log::trace!(
target: "xcm::process_instruction::transact",
"Failed to convert origin {origin:?} and origin kind {origin_kind:?} to a local origin."
);
XcmError::BadOrigin
})?;
log::trace!(
target: "xcm::process_instruction::transact",
"Dispatching with origin: {dispatch_origin:?}",
);
if !weight.all_lte(require_weight_at_most) {
log::trace!(
target: "xcm::process_instruction::transact",
"Max {weight} bigger than require at most {require_weight_at_most}",
);
return Err(XcmError::MaxWeightInvalid)
}
let maybe_actual_weight =
match Config::CallDispatcher::dispatch(message_call, dispatch_origin) {
Ok(post_info) => {
log::trace!(
target: "xcm::process_instruction::transact",
"Dispatch successful: {post_info:?}"
);
self.transact_status = MaybeErrorCode::Success;
post_info.actual_weight
},
Err(error_and_info) => {
log::trace!(
target: "xcm::process_instruction::transact",
"Dispatch failed {error_and_info:?}"
);
self.transact_status = error_and_info.error.encode().into();
error_and_info.post_info.actual_weight
},
};
let actual_weight = maybe_actual_weight.unwrap_or(weight);
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// We assume that the `Config::Weigher` will counts the `require_weight_at_most`
// for the estimate of how much weight this instruction will take. Now that we know
// that it's less, we credit it.
//
// We make the adjustment for the total surplus, which is used eventually
// reported back to the caller and this ensures that they account for the total
// weight consumed correctly (potentially allowing them to do more operations in a
// block than they otherwise would).
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Ok(())
QueryResponse { query_id, response, max_weight, querier } => {
let origin = self.origin_ref().ok_or(XcmError::BadOrigin)?;
Config::ResponseHandler::on_response(
origin,
query_id,
querier.as_ref(),
response,
max_weight,
&self.context,
);
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Ok(())
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DescendOrigin(who) => self
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.origin
.as_mut()
.ok_or(XcmError::BadOrigin)?
.append_with(who)
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ClearOrigin => {
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Ok(())
// Report the given result by sending a QueryResponse XCM to a previously given
// outcome destination if one was registered.
self.respond(
self.cloned_origin(),
Response::ExecutionResult(self.error),
response_info,
FeeReason::Report,
)?;
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Ok(())
},
DepositAsset { assets, beneficiary } => {
let deposited = self.holding.saturating_take(assets);
for asset in deposited.into_assets_iter() {
Config::AssetTransactor::deposit_asset(
&asset,
&beneficiary,
Some(&self.context),
)?;
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Ok(())
DepositReserveAsset { assets, dest, xcm } => {
let deposited = self.holding.saturating_take(assets);
for asset in deposited.assets_iter() {
Config::AssetTransactor::deposit_asset(&asset, &dest, Some(&self.context))?;
// Note that we pass `None` as `maybe_failed_bin` and drop any assets which cannot
// be reanchored because we have already called `deposit_asset` on all assets.
let assets = Self::reanchored(deposited, &dest, None);
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let mut message = vec![ReserveAssetDeposited(assets), ClearOrigin];
message.extend(xcm.0.into_iter());
self.send(dest, Xcm(message), FeeReason::DepositReserveAsset)?;
Ok(())
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InitiateReserveWithdraw { assets, reserve, xcm } => {
// Note that here we are able to place any assets which could not be reanchored
// back into Holding.
let assets = Self::reanchored(
self.holding.saturating_take(assets),
&reserve,
Some(&mut self.holding),
);
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let mut message = vec![WithdrawAsset(assets), ClearOrigin];
message.extend(xcm.0.into_iter());
self.send(reserve, Xcm(message), FeeReason::InitiateReserveWithdraw)?;
Ok(())
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InitiateTeleport { assets, dest, xcm } => {
// We must do this first in order to resolve wildcards.
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let assets = self.holding.saturating_take(assets);
for asset in assets.assets_iter() {
// We should check that the asset can actually be teleported out (for this to
// be in error, there would need to be an accounting violation by ourselves,
// so it's unlikely, but we don't want to allow that kind of bug to leak into
// a trusted chain.
Config::AssetTransactor::can_check_out(&dest, &asset, &self.context)?;
}
for asset in assets.assets_iter() {
Config::AssetTransactor::check_out(&dest, &asset, &self.context);
// Note that we pass `None` as `maybe_failed_bin` and drop any assets which cannot
// be reanchored because we have already checked all assets out.
let assets = Self::reanchored(assets, &dest, None);
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let mut message = vec![ReceiveTeleportedAsset(assets), ClearOrigin];
message.extend(xcm.0.into_iter());
self.send(dest, Xcm(message), FeeReason::InitiateTeleport)?;
Ok(())
// Note that we pass `None` as `maybe_failed_bin` since no assets were ever removed
// from Holding.
let assets =
Self::reanchored(self.holding.min(&assets), &response_info.destination, None);
self.respond(
self.cloned_origin(),
Response::Assets(assets),
response_info,
FeeReason::Report,
)?;
Ok(())
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BuyExecution { fees, weight_limit } => {
// There is no need to buy any weight is `weight_limit` is `Unlimited` since it
// would indicate that `AllowTopLevelPaidExecutionFrom` was unused for execution
// and thus there is some other reason why it has been determined that this XCM
// should be executed.
if let Some(weight) = Option::<Weight>::from(weight_limit) {
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// pay for `weight` using up to `fees` of the holding register.
let max_fee =
self.holding.try_take(fees.into()).map_err(|_| XcmError::NotHoldingFees)?;
let unspent = self.trader.buy_weight(weight, max_fee, &self.context)?;
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Ok(())
},
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SetErrorHandler(mut handler) => {
let handler_weight = Config::Weigher::weight(&mut handler)
.map_err(|()| XcmError::WeightNotComputable)?;
self.total_surplus.saturating_accrue(self.error_handler_weight);
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self.error_handler = handler;
self.error_handler_weight = handler_weight;
Ok(())
},
SetAppendix(mut appendix) => {
let appendix_weight = Config::Weigher::weight(&mut appendix)
.map_err(|()| XcmError::WeightNotComputable)?;
self.total_surplus.saturating_accrue(self.appendix_weight);
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self.appendix = appendix;
self.appendix_weight = appendix_weight;
Ok(())
},
ClearError => {
self.error = None;
Ok(())
},
ClaimAsset { assets, ticket } => {
let origin = self.origin_ref().ok_or(XcmError::BadOrigin)?;
let ok = Config::AssetClaims::claim_assets(origin, &ticket, &assets, &self.context);
ensure!(ok, XcmError::UnknownClaim);
for asset in assets.into_inner().into_iter() {
self.subsume_asset(asset)?;
}
Ok(())
},
Trap(code) => Err(XcmError::Trap(code)),
SubscribeVersion { query_id, max_response_weight } => {
// We don't allow derivative origins to subscribe since it would otherwise pose a
// DoS risk.
ensure!(&self.original_origin == origin, XcmError::BadOrigin);
Config::SubscriptionService::start(
origin,
query_id,
max_response_weight,
&self.context,
)
ensure!(&self.original_origin == origin, XcmError::BadOrigin);
Config::SubscriptionService::stop(origin, &self.context)
},
BurnAsset(assets) => {
self.holding.saturating_take(assets.into());
Ok(())
},
ExpectAsset(assets) =>
self.holding.ensure_contains(&assets).map_err(|_| XcmError::ExpectationFalse),
ExpectOrigin(origin) => {
ensure!(self.context.origin == origin, XcmError::ExpectationFalse);
Ok(())
},
ExpectError(error) => {
ensure!(self.error == error, XcmError::ExpectationFalse);
Ok(())
},
ExpectTransactStatus(transact_status) => {
ensure!(self.transact_status == transact_status, XcmError::ExpectationFalse);
Ok(())
},
QueryPallet { module_name, response_info } => {
let pallets = Config::PalletInstancesInfo::infos()
.into_iter()
.filter(|x| x.module_name.as_bytes() == &module_name[..])
.map(|x| {
PalletInfo::new(
x.index as u32,
x.name.as_bytes().into(),
x.module_name.as_bytes().into(),
x.crate_version.major as u32,
x.crate_version.minor as u32,
x.crate_version.patch as u32,
)
})
.collect::<Result<Vec<_>, XcmError>>()?;
let QueryResponseInfo { destination, query_id, max_weight } = response_info;
let response =
Response::PalletsInfo(pallets.try_into().map_err(|_| XcmError::Overflow)?);
932
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let querier = Self::to_querier(self.cloned_origin(), &destination)?;
let instruction = QueryResponse { query_id, response, max_weight, querier };
let message = Xcm(vec![instruction]);
self.send(destination, message, FeeReason::QueryPallet)?;
Ok(())
},
ExpectPallet { index, name, module_name, crate_major, min_crate_minor } => {
let pallet = Config::PalletInstancesInfo::infos()
.into_iter()
.find(|x| x.index == index as usize)
.ok_or(XcmError::PalletNotFound)?;
ensure!(pallet.name.as_bytes() == &name[..], XcmError::NameMismatch);
ensure!(pallet.module_name.as_bytes() == &module_name[..], XcmError::NameMismatch);
let major = pallet.crate_version.major as u32;
ensure!(major == crate_major, XcmError::VersionIncompatible);
let minor = pallet.crate_version.minor as u32;
ensure!(minor >= min_crate_minor, XcmError::VersionIncompatible);
Ok(())
},
ReportTransactStatus(response_info) => {
self.respond(
self.cloned_origin(),
Response::DispatchResult(self.transact_status.clone()),
response_info,
FeeReason::Report,
)?;
Ok(())
},
ClearTransactStatus => {
self.transact_status = Default::default();
Ok(())
},
UniversalOrigin(new_global) => {
let universal_location = Config::UniversalLocation::get();
ensure!(universal_location.first() != Some(&new_global), XcmError::InvalidLocation);
let origin = *self.origin_ref().ok_or(XcmError::BadOrigin)?;
let origin_xform = (origin, new_global);
let ok = Config::UniversalAliases::contains(&origin_xform);
ensure!(ok, XcmError::InvalidLocation);
let (_, new_global) = origin_xform;
let new_origin = X1(new_global).relative_to(&universal_location);
self.context.origin = Some(new_origin);
Ok(())
},
ExportMessage { network, destination, xcm } => {
// The actual message sent to the bridge for forwarding is prepended with
// `UniversalOrigin` and `DescendOrigin` in order to ensure that the message is
// executed with this Origin.
// Prepend the desired message with instructions which effectively rewrite the
// origin.
//
// This only works because the remote chain empowers the bridge
// to speak for the local network.
let origin = self.context.origin.ok_or(XcmError::BadOrigin)?;
let universal_source = Config::UniversalLocation::get()
.within_global(origin)
.map_err(|()| XcmError::Unanchored)?;
let hash = (self.origin_ref(), &destination).using_encoded(blake2_128);
let channel = u32::decode(&mut hash.as_ref()).unwrap_or(0);
// Hash identifies the lane on the exporter which we use. We use the pairwise
// combination of the origin and destination to ensure origin/destination pairs will
// generally have their own lanes.
let (ticket, fee) = validate_export::<Config::MessageExporter>(
network,
channel,
universal_source,
destination,
xcm,