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pezkuwi-subxt/polkadot/xcm/src/v1/multilocation.rs
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Gavin Wood 32bb94afff Reanchor should return canonical location (#4470)
* Reanchor should return canonical

* Formatting

* Formatting

* Update xcm/src/v1/multilocation.rs

* Formatting

* Fixes

* Don't discard unreanchorable assets

* Formatting

* Docs

* Fixes

* Fixes

* tidy
2021-12-14 09:21:34 +01:00

1053 lines
37 KiB
Rust

// Copyright 2020-2021 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/>.
//! Cross-Consensus Message format data structures.
use super::Junction;
use core::{convert::TryFrom, mem, result};
use parity_scale_codec::{Decode, Encode};
use scale_info::TypeInfo;
/// A relative path between state-bearing consensus systems.
///
/// A location in a consensus system is defined as an *isolatable state machine* held within global
/// consensus. The location in question need not have a sophisticated consensus algorithm of its
/// own; a single account within Ethereum, for example, could be considered a location.
///
/// A very-much non-exhaustive list of types of location include:
/// - A (normal, layer-1) block chain, e.g. the Bitcoin mainnet or a parachain.
/// - A layer-0 super-chain, e.g. the Polkadot Relay chain.
/// - A layer-2 smart contract, e.g. an ERC-20 on Ethereum.
/// - A logical functional component of a chain, e.g. a single instance of a pallet on a Frame-based
/// Substrate chain.
/// - An account.
///
/// A `MultiLocation` is a *relative identifier*, meaning that it can only be used to define the
/// relative path between two locations, and cannot generally be used to refer to a location
/// universally. It is comprised of an integer number of parents specifying the number of times to
/// "escape" upwards into the containing consensus system and then a number of *junctions*, each
/// diving down and specifying some interior portion of state (which may be considered a
/// "sub-consensus" system).
///
/// This specific `MultiLocation` implementation uses a `Junctions` datatype which is a Rust `enum`
/// in order to make pattern matching easier. There are occasions where it is important to ensure
/// that a value is strictly an interior location, in those cases, `Junctions` may be used.
///
/// The `MultiLocation` value of `Null` simply refers to the interpreting consensus system.
#[derive(Clone, Decode, Encode, Eq, PartialEq, Ord, PartialOrd, Debug, TypeInfo)]
pub struct MultiLocation {
/// The number of parent junctions at the beginning of this `MultiLocation`.
pub parents: u8,
/// The interior (i.e. non-parent) junctions that this `MultiLocation` contains.
pub interior: Junctions,
}
impl Default for MultiLocation {
fn default() -> Self {
Self { parents: 0, interior: Junctions::Here }
}
}
/// A relative location which is constrained to be an interior location of the context.
///
/// See also `MultiLocation`.
pub type InteriorMultiLocation = Junctions;
impl MultiLocation {
/// Creates a new `MultiLocation` with the given number of parents and interior junctions.
pub fn new(parents: u8, junctions: Junctions) -> MultiLocation {
MultiLocation { parents, interior: junctions }
}
/// Consume `self` and return the equivalent `VersionedMultiLocation` value.
pub fn versioned(self) -> crate::VersionedMultiLocation {
self.into()
}
/// Creates a new `MultiLocation` with 0 parents and a `Here` interior.
///
/// The resulting `MultiLocation` can be interpreted as the "current consensus system".
pub const fn here() -> MultiLocation {
MultiLocation { parents: 0, interior: Junctions::Here }
}
/// Creates a new `MultiLocation` which evaluates to the parent context.
pub const fn parent() -> MultiLocation {
MultiLocation { parents: 1, interior: Junctions::Here }
}
/// Creates a new `MultiLocation` which evaluates to the grand parent context.
pub const fn grandparent() -> MultiLocation {
MultiLocation { parents: 2, interior: Junctions::Here }
}
/// Creates a new `MultiLocation` with `parents` and an empty (`Here`) interior.
pub const fn ancestor(parents: u8) -> MultiLocation {
MultiLocation { parents, interior: Junctions::Here }
}
/// Whether the `MultiLocation` has no parents and has a `Here` interior.
pub const fn is_here(&self) -> bool {
self.parents == 0 && self.interior.len() == 0
}
/// Return a reference to the interior field.
pub fn interior(&self) -> &Junctions {
&self.interior
}
/// Return a mutable reference to the interior field.
pub fn interior_mut(&mut self) -> &mut Junctions {
&mut self.interior
}
/// Returns the number of `Parent` junctions at the beginning of `self`.
pub const fn parent_count(&self) -> u8 {
self.parents
}
/// Returns boolean indicating whether `self` contains only the specified amount of
/// parents and no interior junctions.
pub const fn contains_parents_only(&self, count: u8) -> bool {
matches!(self.interior, Junctions::Here) && self.parents == count
}
/// Returns the number of parents and junctions in `self`.
pub const fn len(&self) -> usize {
self.parent_count() as usize + self.interior.len()
}
/// Returns the first interior junction, or `None` if the location is empty or contains only
/// parents.
pub fn first_interior(&self) -> Option<&Junction> {
self.interior.first()
}
/// Returns last junction, or `None` if the location is empty or contains only parents.
pub fn last(&self) -> Option<&Junction> {
self.interior.last()
}
/// Splits off the first interior junction, returning the remaining suffix (first item in tuple)
/// and the first element (second item in tuple) or `None` if it was empty.
pub fn split_first_interior(self) -> (MultiLocation, Option<Junction>) {
let MultiLocation { parents, interior: junctions } = self;
let (suffix, first) = junctions.split_first();
let multilocation = MultiLocation { parents, interior: suffix };
(multilocation, first)
}
/// Splits off the last interior junction, returning the remaining prefix (first item in tuple)
/// and the last element (second item in tuple) or `None` if it was empty or if `self` only
/// contains parents.
pub fn split_last_interior(self) -> (MultiLocation, Option<Junction>) {
let MultiLocation { parents, interior: junctions } = self;
let (prefix, last) = junctions.split_last();
let multilocation = MultiLocation { parents, interior: prefix };
(multilocation, last)
}
/// Mutates `self`, suffixing its interior junctions with `new`. Returns `Err` with `new` in
/// case of overflow.
pub fn push_interior(&mut self, new: Junction) -> result::Result<(), Junction> {
self.interior.push(new)
}
/// Mutates `self`, prefixing its interior junctions with `new`. Returns `Err` with `new` in
/// case of overflow.
pub fn push_front_interior(&mut self, new: Junction) -> result::Result<(), Junction> {
self.interior.push_front(new)
}
/// Consumes `self` and returns a `MultiLocation` suffixed with `new`, or an `Err` with theoriginal value of
/// `self` in case of overflow.
pub fn pushed_with_interior(self, new: Junction) -> result::Result<Self, (Self, Junction)> {
match self.interior.pushed_with(new) {
Ok(i) => Ok(MultiLocation { interior: i, parents: self.parents }),
Err((i, j)) => Err((MultiLocation { interior: i, parents: self.parents }, j)),
}
}
/// Consumes `self` and returns a `MultiLocation` prefixed with `new`, or an `Err` with the original value of
/// `self` in case of overflow.
pub fn pushed_front_with_interior(
self,
new: Junction,
) -> result::Result<Self, (Self, Junction)> {
match self.interior.pushed_front_with(new) {
Ok(i) => Ok(MultiLocation { interior: i, parents: self.parents }),
Err((i, j)) => Err((MultiLocation { interior: i, parents: self.parents }, j)),
}
}
/// Returns the junction at index `i`, or `None` if the location is a parent or if the location
/// does not contain that many elements.
pub fn at(&self, i: usize) -> Option<&Junction> {
let num_parents = self.parents as usize;
if i < num_parents {
return None
}
self.interior.at(i - num_parents)
}
/// Returns a mutable reference to the junction at index `i`, or `None` if the location is a
/// parent or if it doesn't contain that many elements.
pub fn at_mut(&mut self, i: usize) -> Option<&mut Junction> {
let num_parents = self.parents as usize;
if i < num_parents {
return None
}
self.interior.at_mut(i - num_parents)
}
/// Decrements the parent count by 1.
pub fn dec_parent(&mut self) {
self.parents = self.parents.saturating_sub(1);
}
/// Removes the first interior junction from `self`, returning it
/// (or `None` if it was empty or if `self` contains only parents).
pub fn take_first_interior(&mut self) -> Option<Junction> {
self.interior.take_first()
}
/// Removes the last element from `interior`, returning it (or `None` if it was empty or if
/// `self` only contains parents).
pub fn take_last(&mut self) -> Option<Junction> {
self.interior.take_last()
}
/// Ensures that `self` has the same number of parents as `prefix`, its junctions begins with
/// the junctions of `prefix` and that it has a single `Junction` item following.
/// If so, returns a reference to this `Junction` item.
///
/// # Example
/// ```rust
/// # use xcm::v1::{Junctions::*, Junction::*, MultiLocation};
/// # fn main() {
/// let mut m = MultiLocation::new(1, X2(PalletInstance(3), OnlyChild));
/// assert_eq!(
/// m.match_and_split(&MultiLocation::new(1, X1(PalletInstance(3)))),
/// Some(&OnlyChild),
/// );
/// assert_eq!(m.match_and_split(&MultiLocation::new(1, Here)), None);
/// # }
/// ```
pub fn match_and_split(&self, prefix: &MultiLocation) -> Option<&Junction> {
if self.parents != prefix.parents {
return None
}
self.interior.match_and_split(&prefix.interior)
}
/// Mutate `self` so that it is suffixed with `suffix`.
///
/// Does not modify `self` and returns `Err` with `suffix` in case of overflow.
///
/// # Example
/// ```rust
/// # use xcm::v1::{Junctions::*, Junction::*, MultiLocation};
/// # fn main() {
/// let mut m = MultiLocation::new(1, X1(Parachain(21)));
/// assert_eq!(m.append_with(X1(PalletInstance(3))), Ok(()));
/// assert_eq!(m, MultiLocation::new(1, X2(Parachain(21), PalletInstance(3))));
/// # }
/// ```
pub fn append_with(&mut self, suffix: Junctions) -> Result<(), Junctions> {
if self.interior.len().saturating_add(suffix.len()) > MAX_JUNCTIONS {
return Err(suffix)
}
for j in suffix.into_iter() {
self.interior.push(j).expect("Already checked the sum of the len()s; qed")
}
Ok(())
}
/// Mutate `self` so that it is prefixed with `prefix`.
///
/// Does not modify `self` and returns `Err` with `prefix` in case of overflow.
///
/// # Example
/// ```rust
/// # use xcm::v1::{Junctions::*, Junction::*, MultiLocation};
/// # fn main() {
/// let mut m = MultiLocation::new(2, X1(PalletInstance(3)));
/// assert_eq!(m.prepend_with(MultiLocation::new(1, X2(Parachain(21), OnlyChild))), Ok(()));
/// assert_eq!(m, MultiLocation::new(1, X1(PalletInstance(3))));
/// # }
/// ```
pub fn prepend_with(&mut self, mut prefix: MultiLocation) -> Result<(), MultiLocation> {
// prefix self (suffix)
// P .. P I .. I p .. p i .. i
let prepend_interior = prefix.interior.len().saturating_sub(self.parents as usize);
let final_interior = self.interior.len().saturating_add(prepend_interior);
if final_interior > MAX_JUNCTIONS {
return Err(prefix)
}
let suffix_parents = (self.parents as usize).saturating_sub(prefix.interior.len());
let final_parents = (prefix.parents as usize).saturating_add(suffix_parents);
if final_parents > 255 {
return Err(prefix)
}
// cancel out the final item on the prefix interior for one of the suffix's parents.
while self.parents > 0 && prefix.take_last().is_some() {
self.dec_parent();
}
// now we have either removed all suffix's parents or prefix interior.
// this means we can combine the prefix's and suffix's remaining parents/interior since
// we know that with at least one empty, the overall order will be respected:
// prefix self (suffix)
// P .. P (I) p .. p i .. i => P + p .. (no I) i
// -- or --
// P .. P I .. I (p) i .. i => P (no p) .. I + i
self.parents = self.parents.saturating_add(prefix.parents);
for j in prefix.interior.into_iter().rev() {
self.push_front_interior(j)
.expect("final_interior no greater than MAX_JUNCTIONS; qed");
}
Ok(())
}
/// Mutate `self` so that it represents the same location from the point of view of `target`.
/// The context of `self` is provided as `ancestry`.
///
/// Does not modify `self` in case of overflow.
pub fn reanchor(&mut self, target: &MultiLocation, ancestry: &MultiLocation) -> Result<(), ()> {
// TODO: https://github.com/paritytech/polkadot/issues/4489 Optimize this.
// 1. Use our `ancestry` to figure out how the `target` would address us.
let inverted_target = ancestry.inverted(target)?;
// 2. Prepend `inverted_target` to `self` to get self's location from the perspective of
// `target`.
self.prepend_with(inverted_target).map_err(|_| ())?;
// 3. Given that we know some of `target` ancestry, ensure that any parents in `self` are
// strictly needed.
self.simplify(target.interior());
Ok(())
}
/// Treating `self` as a context, determine how it would be referenced by a `target` location.
pub fn inverted(&self, target: &MultiLocation) -> Result<MultiLocation, ()> {
use Junction::OnlyChild;
let mut ancestry = self.clone();
let mut junctions = Junctions::Here;
for _ in 0..target.parent_count() {
junctions = junctions
.pushed_front_with(ancestry.interior.take_last().unwrap_or(OnlyChild))
.map_err(|_| ())?;
}
let parents = target.interior().len() as u8;
Ok(MultiLocation::new(parents, junctions))
}
/// Remove any unneeded parents/junctions in `self` based on the given context it will be
/// interpreted in.
pub fn simplify(&mut self, context: &Junctions) {
if context.len() < self.parents as usize {
// Not enough context
return
}
while self.parents > 0 {
let maybe = context.at(context.len() - (self.parents as usize));
match (self.interior.first(), maybe) {
(Some(i), Some(j)) if i == j => {
self.interior.take_first();
self.parents -= 1;
},
_ => break,
}
}
}
}
/// A unit struct which can be converted into a `MultiLocation` of `parents` value 1.
#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Debug)]
pub struct Parent;
impl From<Parent> for MultiLocation {
fn from(_: Parent) -> Self {
MultiLocation { parents: 1, interior: Junctions::Here }
}
}
/// A tuple struct which can be converted into a `MultiLocation` of `parents` value 1 with the inner interior.
#[derive(Clone, PartialEq, Eq, PartialOrd, Ord, Debug)]
pub struct ParentThen(Junctions);
impl From<ParentThen> for MultiLocation {
fn from(ParentThen(interior): ParentThen) -> Self {
MultiLocation { parents: 1, interior }
}
}
/// A unit struct which can be converted into a `MultiLocation` of the inner `parents` value.
#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Debug)]
pub struct Ancestor(u8);
impl From<Ancestor> for MultiLocation {
fn from(Ancestor(parents): Ancestor) -> Self {
MultiLocation { parents, interior: Junctions::Here }
}
}
/// A unit struct which can be converted into a `MultiLocation` of the inner `parents` value and the inner interior.
#[derive(Clone, PartialEq, Eq, PartialOrd, Ord, Debug)]
pub struct AncestorThen(u8, Junctions);
impl From<AncestorThen> for MultiLocation {
fn from(AncestorThen(parents, interior): AncestorThen) -> Self {
MultiLocation { parents, interior }
}
}
xcm_procedural::impl_conversion_functions_for_multilocation_v1!();
/// Maximum number of `Junction`s that a `Junctions` can contain.
const MAX_JUNCTIONS: usize = 8;
/// Non-parent junctions that can be constructed, up to the length of 8. This specific `Junctions`
/// implementation uses a Rust `enum` in order to make pattern matching easier.
///
/// Parent junctions cannot be constructed with this type. Refer to `MultiLocation` for
/// instructions on constructing parent junctions.
#[derive(Clone, Eq, PartialEq, Ord, PartialOrd, Encode, Decode, Debug, TypeInfo)]
pub enum Junctions {
/// The interpreting consensus system.
Here,
/// A relative path comprising 1 junction.
X1(Junction),
/// A relative path comprising 2 junctions.
X2(Junction, Junction),
/// A relative path comprising 3 junctions.
X3(Junction, Junction, Junction),
/// A relative path comprising 4 junctions.
X4(Junction, Junction, Junction, Junction),
/// A relative path comprising 5 junctions.
X5(Junction, Junction, Junction, Junction, Junction),
/// A relative path comprising 6 junctions.
X6(Junction, Junction, Junction, Junction, Junction, Junction),
/// A relative path comprising 7 junctions.
X7(Junction, Junction, Junction, Junction, Junction, Junction, Junction),
/// A relative path comprising 8 junctions.
X8(Junction, Junction, Junction, Junction, Junction, Junction, Junction, Junction),
}
pub struct JunctionsIterator(Junctions);
impl Iterator for JunctionsIterator {
type Item = Junction;
fn next(&mut self) -> Option<Junction> {
self.0.take_first()
}
}
impl DoubleEndedIterator for JunctionsIterator {
fn next_back(&mut self) -> Option<Junction> {
self.0.take_last()
}
}
pub struct JunctionsRefIterator<'a> {
junctions: &'a Junctions,
next: usize,
back: usize,
}
impl<'a> Iterator for JunctionsRefIterator<'a> {
type Item = &'a Junction;
fn next(&mut self) -> Option<&'a Junction> {
if self.next.saturating_add(self.back) >= self.junctions.len() {
return None
}
let result = self.junctions.at(self.next);
self.next += 1;
result
}
}
impl<'a> DoubleEndedIterator for JunctionsRefIterator<'a> {
fn next_back(&mut self) -> Option<&'a Junction> {
let next_back = self.back.saturating_add(1);
// checked_sub here, because if the result is less than 0, we end iteration
let index = self.junctions.len().checked_sub(next_back)?;
if self.next > index {
return None
}
self.back = next_back;
self.junctions.at(index)
}
}
impl<'a> IntoIterator for &'a Junctions {
type Item = &'a Junction;
type IntoIter = JunctionsRefIterator<'a>;
fn into_iter(self) -> Self::IntoIter {
JunctionsRefIterator { junctions: self, next: 0, back: 0 }
}
}
impl IntoIterator for Junctions {
type Item = Junction;
type IntoIter = JunctionsIterator;
fn into_iter(self) -> Self::IntoIter {
JunctionsIterator(self)
}
}
impl Junctions {
/// Convert `self` into a `MultiLocation` containing 0 parents.
///
/// Similar to `Into::into`, except that this method can be used in a const evaluation context.
pub const fn into(self) -> MultiLocation {
MultiLocation { parents: 0, interior: self }
}
/// Convert `self` into a `MultiLocation` containing `n` parents.
///
/// Similar to `Self::into`, with the added ability to specify the number of parent junctions.
pub const fn into_exterior(self, n: u8) -> MultiLocation {
MultiLocation { parents: n, interior: self }
}
/// Returns first junction, or `None` if the location is empty.
pub fn first(&self) -> Option<&Junction> {
match &self {
Junctions::Here => None,
Junctions::X1(ref a) => Some(a),
Junctions::X2(ref a, ..) => Some(a),
Junctions::X3(ref a, ..) => Some(a),
Junctions::X4(ref a, ..) => Some(a),
Junctions::X5(ref a, ..) => Some(a),
Junctions::X6(ref a, ..) => Some(a),
Junctions::X7(ref a, ..) => Some(a),
Junctions::X8(ref a, ..) => Some(a),
}
}
/// Returns last junction, or `None` if the location is empty.
pub fn last(&self) -> Option<&Junction> {
match &self {
Junctions::Here => None,
Junctions::X1(ref a) => Some(a),
Junctions::X2(.., ref a) => Some(a),
Junctions::X3(.., ref a) => Some(a),
Junctions::X4(.., ref a) => Some(a),
Junctions::X5(.., ref a) => Some(a),
Junctions::X6(.., ref a) => Some(a),
Junctions::X7(.., ref a) => Some(a),
Junctions::X8(.., ref a) => Some(a),
}
}
/// Splits off the first junction, returning the remaining suffix (first item in tuple) and the first element
/// (second item in tuple) or `None` if it was empty.
pub fn split_first(self) -> (Junctions, Option<Junction>) {
match self {
Junctions::Here => (Junctions::Here, None),
Junctions::X1(a) => (Junctions::Here, Some(a)),
Junctions::X2(a, b) => (Junctions::X1(b), Some(a)),
Junctions::X3(a, b, c) => (Junctions::X2(b, c), Some(a)),
Junctions::X4(a, b, c, d) => (Junctions::X3(b, c, d), Some(a)),
Junctions::X5(a, b, c, d, e) => (Junctions::X4(b, c, d, e), Some(a)),
Junctions::X6(a, b, c, d, e, f) => (Junctions::X5(b, c, d, e, f), Some(a)),
Junctions::X7(a, b, c, d, e, f, g) => (Junctions::X6(b, c, d, e, f, g), Some(a)),
Junctions::X8(a, b, c, d, e, f, g, h) => (Junctions::X7(b, c, d, e, f, g, h), Some(a)),
}
}
/// Splits off the last junction, returning the remaining prefix (first item in tuple) and the last element
/// (second item in tuple) or `None` if it was empty.
pub fn split_last(self) -> (Junctions, Option<Junction>) {
match self {
Junctions::Here => (Junctions::Here, None),
Junctions::X1(a) => (Junctions::Here, Some(a)),
Junctions::X2(a, b) => (Junctions::X1(a), Some(b)),
Junctions::X3(a, b, c) => (Junctions::X2(a, b), Some(c)),
Junctions::X4(a, b, c, d) => (Junctions::X3(a, b, c), Some(d)),
Junctions::X5(a, b, c, d, e) => (Junctions::X4(a, b, c, d), Some(e)),
Junctions::X6(a, b, c, d, e, f) => (Junctions::X5(a, b, c, d, e), Some(f)),
Junctions::X7(a, b, c, d, e, f, g) => (Junctions::X6(a, b, c, d, e, f), Some(g)),
Junctions::X8(a, b, c, d, e, f, g, h) => (Junctions::X7(a, b, c, d, e, f, g), Some(h)),
}
}
/// Removes the first element from `self`, returning it (or `None` if it was empty).
pub fn take_first(&mut self) -> Option<Junction> {
let mut d = Junctions::Here;
mem::swap(&mut *self, &mut d);
let (tail, head) = d.split_first();
*self = tail;
head
}
/// Removes the last element from `self`, returning it (or `None` if it was empty).
pub fn take_last(&mut self) -> Option<Junction> {
let mut d = Junctions::Here;
mem::swap(&mut *self, &mut d);
let (head, tail) = d.split_last();
*self = head;
tail
}
/// Mutates `self` to be appended with `new` or returns an `Err` with `new` if would overflow.
pub fn push(&mut self, new: Junction) -> result::Result<(), Junction> {
let mut dummy = Junctions::Here;
mem::swap(self, &mut dummy);
match dummy.pushed_with(new) {
Ok(s) => {
*self = s;
Ok(())
},
Err((s, j)) => {
*self = s;
Err(j)
},
}
}
/// Mutates `self` to be prepended with `new` or returns an `Err` with `new` if would overflow.
pub fn push_front(&mut self, new: Junction) -> result::Result<(), Junction> {
let mut dummy = Junctions::Here;
mem::swap(self, &mut dummy);
match dummy.pushed_front_with(new) {
Ok(s) => {
*self = s;
Ok(())
},
Err((s, j)) => {
*self = s;
Err(j)
},
}
}
/// Consumes `self` and returns a `Junctions` suffixed with `new`, or an `Err` with the
/// original value of `self` and `new` in case of overflow.
pub fn pushed_with(self, new: Junction) -> result::Result<Self, (Self, Junction)> {
Ok(match self {
Junctions::Here => Junctions::X1(new),
Junctions::X1(a) => Junctions::X2(a, new),
Junctions::X2(a, b) => Junctions::X3(a, b, new),
Junctions::X3(a, b, c) => Junctions::X4(a, b, c, new),
Junctions::X4(a, b, c, d) => Junctions::X5(a, b, c, d, new),
Junctions::X5(a, b, c, d, e) => Junctions::X6(a, b, c, d, e, new),
Junctions::X6(a, b, c, d, e, f) => Junctions::X7(a, b, c, d, e, f, new),
Junctions::X7(a, b, c, d, e, f, g) => Junctions::X8(a, b, c, d, e, f, g, new),
s => Err((s, new))?,
})
}
/// Consumes `self` and returns a `Junctions` prefixed with `new`, or an `Err` with the
/// original value of `self` and `new` in case of overflow.
pub fn pushed_front_with(self, new: Junction) -> result::Result<Self, (Self, Junction)> {
Ok(match self {
Junctions::Here => Junctions::X1(new),
Junctions::X1(a) => Junctions::X2(new, a),
Junctions::X2(a, b) => Junctions::X3(new, a, b),
Junctions::X3(a, b, c) => Junctions::X4(new, a, b, c),
Junctions::X4(a, b, c, d) => Junctions::X5(new, a, b, c, d),
Junctions::X5(a, b, c, d, e) => Junctions::X6(new, a, b, c, d, e),
Junctions::X6(a, b, c, d, e, f) => Junctions::X7(new, a, b, c, d, e, f),
Junctions::X7(a, b, c, d, e, f, g) => Junctions::X8(new, a, b, c, d, e, f, g),
s => Err((s, new))?,
})
}
/// Returns the number of junctions in `self`.
pub const fn len(&self) -> usize {
match &self {
Junctions::Here => 0,
Junctions::X1(..) => 1,
Junctions::X2(..) => 2,
Junctions::X3(..) => 3,
Junctions::X4(..) => 4,
Junctions::X5(..) => 5,
Junctions::X6(..) => 6,
Junctions::X7(..) => 7,
Junctions::X8(..) => 8,
}
}
/// Returns the junction at index `i`, or `None` if the location doesn't contain that many elements.
pub fn at(&self, i: usize) -> Option<&Junction> {
Some(match (i, self) {
(0, Junctions::X1(ref a)) => a,
(0, Junctions::X2(ref a, ..)) => a,
(0, Junctions::X3(ref a, ..)) => a,
(0, Junctions::X4(ref a, ..)) => a,
(0, Junctions::X5(ref a, ..)) => a,
(0, Junctions::X6(ref a, ..)) => a,
(0, Junctions::X7(ref a, ..)) => a,
(0, Junctions::X8(ref a, ..)) => a,
(1, Junctions::X2(_, ref a)) => a,
(1, Junctions::X3(_, ref a, ..)) => a,
(1, Junctions::X4(_, ref a, ..)) => a,
(1, Junctions::X5(_, ref a, ..)) => a,
(1, Junctions::X6(_, ref a, ..)) => a,
(1, Junctions::X7(_, ref a, ..)) => a,
(1, Junctions::X8(_, ref a, ..)) => a,
(2, Junctions::X3(_, _, ref a)) => a,
(2, Junctions::X4(_, _, ref a, ..)) => a,
(2, Junctions::X5(_, _, ref a, ..)) => a,
(2, Junctions::X6(_, _, ref a, ..)) => a,
(2, Junctions::X7(_, _, ref a, ..)) => a,
(2, Junctions::X8(_, _, ref a, ..)) => a,
(3, Junctions::X4(_, _, _, ref a)) => a,
(3, Junctions::X5(_, _, _, ref a, ..)) => a,
(3, Junctions::X6(_, _, _, ref a, ..)) => a,
(3, Junctions::X7(_, _, _, ref a, ..)) => a,
(3, Junctions::X8(_, _, _, ref a, ..)) => a,
(4, Junctions::X5(_, _, _, _, ref a)) => a,
(4, Junctions::X6(_, _, _, _, ref a, ..)) => a,
(4, Junctions::X7(_, _, _, _, ref a, ..)) => a,
(4, Junctions::X8(_, _, _, _, ref a, ..)) => a,
(5, Junctions::X6(_, _, _, _, _, ref a)) => a,
(5, Junctions::X7(_, _, _, _, _, ref a, ..)) => a,
(5, Junctions::X8(_, _, _, _, _, ref a, ..)) => a,
(6, Junctions::X7(_, _, _, _, _, _, ref a)) => a,
(6, Junctions::X8(_, _, _, _, _, _, ref a, ..)) => a,
(7, Junctions::X8(_, _, _, _, _, _, _, ref a)) => a,
_ => return None,
})
}
/// Returns a mutable reference to the junction at index `i`, or `None` if the location doesn't contain that many
/// elements.
pub fn at_mut(&mut self, i: usize) -> Option<&mut Junction> {
Some(match (i, self) {
(0, Junctions::X1(ref mut a)) => a,
(0, Junctions::X2(ref mut a, ..)) => a,
(0, Junctions::X3(ref mut a, ..)) => a,
(0, Junctions::X4(ref mut a, ..)) => a,
(0, Junctions::X5(ref mut a, ..)) => a,
(0, Junctions::X6(ref mut a, ..)) => a,
(0, Junctions::X7(ref mut a, ..)) => a,
(0, Junctions::X8(ref mut a, ..)) => a,
(1, Junctions::X2(_, ref mut a)) => a,
(1, Junctions::X3(_, ref mut a, ..)) => a,
(1, Junctions::X4(_, ref mut a, ..)) => a,
(1, Junctions::X5(_, ref mut a, ..)) => a,
(1, Junctions::X6(_, ref mut a, ..)) => a,
(1, Junctions::X7(_, ref mut a, ..)) => a,
(1, Junctions::X8(_, ref mut a, ..)) => a,
(2, Junctions::X3(_, _, ref mut a)) => a,
(2, Junctions::X4(_, _, ref mut a, ..)) => a,
(2, Junctions::X5(_, _, ref mut a, ..)) => a,
(2, Junctions::X6(_, _, ref mut a, ..)) => a,
(2, Junctions::X7(_, _, ref mut a, ..)) => a,
(2, Junctions::X8(_, _, ref mut a, ..)) => a,
(3, Junctions::X4(_, _, _, ref mut a)) => a,
(3, Junctions::X5(_, _, _, ref mut a, ..)) => a,
(3, Junctions::X6(_, _, _, ref mut a, ..)) => a,
(3, Junctions::X7(_, _, _, ref mut a, ..)) => a,
(3, Junctions::X8(_, _, _, ref mut a, ..)) => a,
(4, Junctions::X5(_, _, _, _, ref mut a)) => a,
(4, Junctions::X6(_, _, _, _, ref mut a, ..)) => a,
(4, Junctions::X7(_, _, _, _, ref mut a, ..)) => a,
(4, Junctions::X8(_, _, _, _, ref mut a, ..)) => a,
(5, Junctions::X6(_, _, _, _, _, ref mut a)) => a,
(5, Junctions::X7(_, _, _, _, _, ref mut a, ..)) => a,
(5, Junctions::X8(_, _, _, _, _, ref mut a, ..)) => a,
(6, Junctions::X7(_, _, _, _, _, _, ref mut a)) => a,
(6, Junctions::X8(_, _, _, _, _, _, ref mut a, ..)) => a,
(7, Junctions::X8(_, _, _, _, _, _, _, ref mut a)) => a,
_ => return None,
})
}
/// Returns a reference iterator over the junctions.
pub fn iter(&self) -> JunctionsRefIterator {
JunctionsRefIterator { junctions: self, next: 0, back: 0 }
}
/// Returns a reference iterator over the junctions in reverse.
#[deprecated(note = "Please use iter().rev()")]
pub fn iter_rev(&self) -> impl Iterator + '_ {
self.iter().rev()
}
/// Consumes `self` and returns an iterator over the junctions in reverse.
#[deprecated(note = "Please use into_iter().rev()")]
pub fn into_iter_rev(self) -> impl Iterator {
self.into_iter().rev()
}
/// Ensures that self begins with `prefix` and that it has a single `Junction` item following.
/// If so, returns a reference to this `Junction` item.
///
/// # Example
/// ```rust
/// # use xcm::v1::{Junctions::*, Junction::*};
/// # fn main() {
/// let mut m = X3(Parachain(2), PalletInstance(3), OnlyChild);
/// assert_eq!(m.match_and_split(&X2(Parachain(2), PalletInstance(3))), Some(&OnlyChild));
/// assert_eq!(m.match_and_split(&X1(Parachain(2))), None);
/// # }
/// ```
pub fn match_and_split(&self, prefix: &Junctions) -> Option<&Junction> {
if prefix.len() + 1 != self.len() {
return None
}
for i in 0..prefix.len() {
if prefix.at(i) != self.at(i) {
return None
}
}
return self.at(prefix.len())
}
}
impl TryFrom<MultiLocation> for Junctions {
type Error = ();
fn try_from(x: MultiLocation) -> result::Result<Self, ()> {
if x.parents > 0 {
Err(())
} else {
Ok(x.interior)
}
}
}
#[cfg(test)]
mod tests {
use super::{Ancestor, AncestorThen, Junctions::*, MultiLocation, Parent, ParentThen};
use crate::opaque::v1::{Junction::*, NetworkId::*};
use parity_scale_codec::{Decode, Encode};
#[test]
fn inverted_works() {
let ancestry: MultiLocation = (Parachain(1000), PalletInstance(42)).into();
let target = (Parent, PalletInstance(69)).into();
let expected = (Parent, PalletInstance(42)).into();
let inverted = ancestry.inverted(&target).unwrap();
assert_eq!(inverted, expected);
let ancestry: MultiLocation = (Parachain(1000), PalletInstance(42), GeneralIndex(1)).into();
let target = (Parent, Parent, PalletInstance(69), GeneralIndex(2)).into();
let expected = (Parent, Parent, PalletInstance(42), GeneralIndex(1)).into();
let inverted = ancestry.inverted(&target).unwrap();
assert_eq!(inverted, expected);
}
#[test]
fn simplify_basic_works() {
let mut location: MultiLocation =
(Parent, Parent, Parachain(1000), PalletInstance(42), GeneralIndex(69)).into();
let context = X2(Parachain(1000), PalletInstance(42));
let expected = GeneralIndex(69).into();
location.simplify(&context);
assert_eq!(location, expected);
let mut location: MultiLocation = (Parent, PalletInstance(42), GeneralIndex(69)).into();
let context = X1(PalletInstance(42));
let expected = GeneralIndex(69).into();
location.simplify(&context);
assert_eq!(location, expected);
let mut location: MultiLocation = (Parent, PalletInstance(42), GeneralIndex(69)).into();
let context = X2(Parachain(1000), PalletInstance(42));
let expected = GeneralIndex(69).into();
location.simplify(&context);
assert_eq!(location, expected);
let mut location: MultiLocation =
(Parent, Parent, Parachain(1000), PalletInstance(42), GeneralIndex(69)).into();
let context = X3(OnlyChild, Parachain(1000), PalletInstance(42));
let expected = GeneralIndex(69).into();
location.simplify(&context);
assert_eq!(location, expected);
}
#[test]
fn simplify_incompatible_location_fails() {
let mut location: MultiLocation =
(Parent, Parent, Parachain(1000), PalletInstance(42), GeneralIndex(69)).into();
let context = X3(Parachain(1000), PalletInstance(42), GeneralIndex(42));
let expected =
(Parent, Parent, Parachain(1000), PalletInstance(42), GeneralIndex(69)).into();
location.simplify(&context);
assert_eq!(location, expected);
let mut location: MultiLocation =
(Parent, Parent, Parachain(1000), PalletInstance(42), GeneralIndex(69)).into();
let context = X1(Parachain(1000));
let expected =
(Parent, Parent, Parachain(1000), PalletInstance(42), GeneralIndex(69)).into();
location.simplify(&context);
assert_eq!(location, expected);
}
#[test]
fn reanchor_works() {
let mut id: MultiLocation = (Parent, Parachain(1000), GeneralIndex(42)).into();
let ancestry = Parachain(2000).into();
let target = (Parent, Parachain(1000)).into();
let expected = GeneralIndex(42).into();
id.reanchor(&target, &ancestry).unwrap();
assert_eq!(id, expected);
}
#[test]
fn encode_and_decode_works() {
let m = MultiLocation {
parents: 1,
interior: X2(Parachain(42), AccountIndex64 { network: Any, index: 23 }),
};
let encoded = m.encode();
assert_eq!(encoded, [1, 2, 0, 168, 2, 0, 92].to_vec());
let decoded = MultiLocation::decode(&mut &encoded[..]);
assert_eq!(decoded, Ok(m));
}
#[test]
fn match_and_split_works() {
let m = MultiLocation {
parents: 1,
interior: X2(Parachain(42), AccountIndex64 { network: Any, index: 23 }),
};
assert_eq!(m.match_and_split(&MultiLocation { parents: 1, interior: Here }), None);
assert_eq!(
m.match_and_split(&MultiLocation { parents: 1, interior: X1(Parachain(42)) }),
Some(&AccountIndex64 { network: Any, index: 23 })
);
assert_eq!(m.match_and_split(&m), None);
}
#[test]
fn append_with_works() {
let acc = AccountIndex64 { network: Any, index: 23 };
let mut m = MultiLocation { parents: 1, interior: X1(Parachain(42)) };
assert_eq!(m.append_with(X2(PalletInstance(3), acc.clone())), Ok(()));
assert_eq!(
m,
MultiLocation {
parents: 1,
interior: X3(Parachain(42), PalletInstance(3), acc.clone())
}
);
// cannot append to create overly long multilocation
let acc = AccountIndex64 { network: Any, index: 23 };
let m = MultiLocation {
parents: 254,
interior: X5(Parachain(42), OnlyChild, OnlyChild, OnlyChild, OnlyChild),
};
let suffix = X4(PalletInstance(3), acc.clone(), OnlyChild, OnlyChild);
assert_eq!(m.clone().append_with(suffix.clone()), Err(suffix));
}
#[test]
fn prepend_with_works() {
let mut m = MultiLocation {
parents: 1,
interior: X2(Parachain(42), AccountIndex64 { network: Any, index: 23 }),
};
assert_eq!(m.prepend_with(MultiLocation { parents: 1, interior: X1(OnlyChild) }), Ok(()));
assert_eq!(
m,
MultiLocation {
parents: 1,
interior: X2(Parachain(42), AccountIndex64 { network: Any, index: 23 })
}
);
// cannot prepend to create overly long multilocation
let mut m = MultiLocation { parents: 254, interior: X1(Parachain(42)) };
let prefix = MultiLocation { parents: 2, interior: Here };
assert_eq!(m.prepend_with(prefix.clone()), Err(prefix));
let prefix = MultiLocation { parents: 1, interior: Here };
assert_eq!(m.prepend_with(prefix), Ok(()));
assert_eq!(m, MultiLocation { parents: 255, interior: X1(Parachain(42)) });
}
#[test]
fn double_ended_ref_iteration_works() {
let m = X3(Parachain(1000), Parachain(3), PalletInstance(5));
let mut iter = m.iter();
let first = iter.next().unwrap();
assert_eq!(first, &Parachain(1000));
let third = iter.next_back().unwrap();
assert_eq!(third, &PalletInstance(5));
let second = iter.next_back().unwrap();
assert_eq!(iter.next(), None);
assert_eq!(iter.next_back(), None);
assert_eq!(second, &Parachain(3));
let res = Here
.pushed_with(first.clone())
.unwrap()
.pushed_with(second.clone())
.unwrap()
.pushed_with(third.clone())
.unwrap();
assert_eq!(m, res);
// make sure there's no funny business with the 0 indexing
let m = Here;
let mut iter = m.iter();
assert_eq!(iter.next(), None);
assert_eq!(iter.next_back(), None);
}
#[test]
fn conversion_from_other_types_works() {
use crate::v0;
use core::convert::TryInto;
fn takes_multilocation<Arg: Into<MultiLocation>>(_arg: Arg) {}
takes_multilocation(Parent);
takes_multilocation(Here);
takes_multilocation(X1(Parachain(42)));
takes_multilocation((255, PalletInstance(8)));
takes_multilocation((Ancestor(5), Parachain(1), PalletInstance(3)));
takes_multilocation((Ancestor(2), Here));
takes_multilocation(AncestorThen(
3,
X2(Parachain(43), AccountIndex64 { network: Any, index: 155 }),
));
takes_multilocation((Parent, AccountId32 { network: Any, id: [0; 32] }));
takes_multilocation((Parent, Here));
takes_multilocation(ParentThen(X1(Parachain(75))));
takes_multilocation([Parachain(100), PalletInstance(3)]);
assert_eq!(v0::MultiLocation::Null.try_into(), Ok(MultiLocation::here()));
assert_eq!(
v0::MultiLocation::X1(v0::Junction::Parent).try_into(),
Ok(MultiLocation::parent())
);
assert_eq!(
v0::MultiLocation::X2(v0::Junction::Parachain(88), v0::Junction::Parent).try_into(),
Ok(MultiLocation::here()),
);
assert_eq!(
v0::MultiLocation::X3(
v0::Junction::Parent,
v0::Junction::Parent,
v0::Junction::GeneralKey(b"foo".to_vec()),
)
.try_into(),
Ok(MultiLocation { parents: 2, interior: X1(GeneralKey(b"foo".to_vec())) }),
);
}
}