Files
pezkuwi-subxt/substrate/primitives/merkle-mountain-range/src/lib.rs
T
Bigna Härdi 0e49ed72aa Add serde feature flag to primitives (#13027)
* add serde_full feature flag

add serde_full to sp_runtime

add space to toml

add serde_full to application-crypto

add serde_full to arithmetic

fix arithmetic

add serde full to beefy

add serde full to consensus

add serde_full to core

add serdefull to finality grandpa

add serde_full to several primitives crates

make rpc no_std compatible

add scale info to runtime

make serializer no_std compatible

add serde full to storage

add full serde to version

add serde full to weights

add all serde_full features

add . to comment

add missing impl-serde

fix no-std build

fix build

add full_crypto to serde_full

serde_full also implements crypto

full_serde does not work with full_crytpo. needs std

no no_std serde impl possible

also for crypto std is necessary

no serde full for application crypto

fix arithmetic

fix tomls

fix some things

impl fmt for Signature

add serialize to Public

add impl_maybe_marker_serde_full

fix sp-application-crypto toml

add serde feature flag

fix clippy

fix toml grandpa

fix grandpa

rename if_std to if_serde

keystore is not no_std compatible

make keystore vrf no_std compatible

fix nopos-elections

fix rpc

fix serializer

fix test-primitives

fix version

add comment

add serde full only import for format string

remove all(serde_full and full_crypot) as serde_full enforces full_crypto

make comment better readable

even better comment

clean up rpc toml

clean up toml

clean up serializer toml

clean up storage toml

fix std build

update .lock

fix sp-version

move sp_std import

test extern crate alloc

replace sp_std with core

add missing core

sp_core: serde feature do not enforce full crypto

application-crypto: serde feature do not enforce full crypto

rename serde_full to serde

add dep:serde and alloc to default feature

add full_crypto and remove unnecessary debu/fmt impls for serde

update comment

remove obolsete change in display AccountId32

remove extra changes

minimize diff

revert keystore changes

remove std from keystore

remove full-crypto feature

fix serde import

fix comment

fix feature = serde

* rename serde_full to serde

* move #[doc(hidden)] back

* remove feature = full crypto require frm MultiSigner

* reorder serde and scale_info import

* fix bs58 missing alloc import in serde feature

* add `from_string` to serde feature and add unimplemented

* remove serde feature from fixed_point display

* Remove serde/alloc

Co-authored-by: Davide Galassi <davxy@datawok.net>

* Update primitives/consensus/babe/Cargo.toml

Co-authored-by: Bastian Köcher <git@kchr.de>

* Update primitives/arithmetic/src/fixed_point.rs

Co-authored-by: Bastian Köcher <git@kchr.de>

* revert `from_string`fixed impl back to std only

* remove duplicate runtime string impl

* use sp_std::alloc

* remove no_std compatible rpc

* remove no_std compatibility from serializer

* rename mpl_maybe_marker_serde to std_or_serde

* update .lock

* add sp-std to executor

* fix sp-std import

* fix sp_std::format import

* use crate import

* add serde feature

* Update primitives/core/src/lib.rs

---------

Co-authored-by: Davide Galassi <davxy@datawok.net>
Co-authored-by: Bastian Köcher <git@kchr.de>
2023-05-17 11:31:12 +00:00

643 lines
20 KiB
Rust

// This file is part of Substrate.
// Copyright (C) Parity Technologies (UK) Ltd.
// SPDX-License-Identifier: Apache-2.0
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//! Merkle Mountain Range primitive types.
#![cfg_attr(not(feature = "std"), no_std)]
#![warn(missing_docs)]
pub use mmr_lib;
use scale_info::TypeInfo;
use sp_debug_derive::RuntimeDebug;
use sp_runtime::traits;
use sp_std::fmt;
#[cfg(not(feature = "std"))]
use sp_std::prelude::Vec;
pub mod utils;
/// Prefix for elements stored in the Off-chain DB via Indexing API.
pub const INDEXING_PREFIX: &'static [u8] = b"mmr";
/// A type to describe node position in the MMR (node index).
pub type NodeIndex = u64;
/// A type to describe leaf position in the MMR.
///
/// Note this is different from [`NodeIndex`], which can be applied to
/// both leafs and inner nodes. Leafs will always have consecutive `LeafIndex`,
/// but might be actually at different positions in the MMR `NodeIndex`.
pub type LeafIndex = u64;
/// A provider of the MMR's leaf data.
pub trait LeafDataProvider {
/// A type that should end up in the leaf of MMR.
type LeafData: FullLeaf + codec::Decode;
/// The method to return leaf data that should be placed
/// in the leaf node appended MMR at this block.
///
/// This is being called by the `on_initialize` method of
/// this pallet at the very beginning of each block.
fn leaf_data() -> Self::LeafData;
}
impl LeafDataProvider for () {
type LeafData = ();
fn leaf_data() -> Self::LeafData {
()
}
}
/// New MMR root notification hook.
pub trait OnNewRoot<Hash> {
/// Function called by the pallet in case new MMR root has been computed.
fn on_new_root(root: &Hash);
}
/// No-op implementation of [OnNewRoot].
impl<Hash> OnNewRoot<Hash> for () {
fn on_new_root(_root: &Hash) {}
}
/// A full leaf content stored in the offchain-db.
pub trait FullLeaf: Clone + PartialEq + fmt::Debug {
/// Encode the leaf either in its full or compact form.
///
/// NOTE the encoding returned here MUST be `Decode`able into `FullLeaf`.
fn using_encoded<R, F: FnOnce(&[u8]) -> R>(&self, f: F, compact: bool) -> R;
}
impl<T: codec::Encode + codec::Decode + Clone + PartialEq + fmt::Debug> FullLeaf for T {
fn using_encoded<R, F: FnOnce(&[u8]) -> R>(&self, f: F, _compact: bool) -> R {
codec::Encode::using_encoded(self, f)
}
}
/// A helper type to allow using arbitrary SCALE-encoded leaf data in the RuntimeApi.
///
/// The point is to be able to verify MMR proofs from external MMRs, where we don't
/// know the exact leaf type, but it's enough for us to have it SCALE-encoded.
///
/// Note the leaf type should be encoded in its compact form when passed through this type.
/// See [FullLeaf] documentation for details.
///
/// This type does not implement SCALE encoding/decoding on purpose to avoid confusion,
/// it would have to be SCALE-compatible with the concrete leaf type, but due to SCALE limitations
/// it's not possible to know how many bytes the encoding of concrete leaf type uses.
#[cfg_attr(feature = "serde", derive(serde::Serialize, serde::Deserialize))]
#[derive(RuntimeDebug, Clone, PartialEq)]
pub struct OpaqueLeaf(
/// Raw bytes of the leaf type encoded in its compact form.
///
/// NOTE it DOES NOT include length prefix (like `Vec<u8>` encoding would).
#[cfg_attr(feature = "serde", serde(with = "sp_core::bytes"))]
pub Vec<u8>,
);
impl OpaqueLeaf {
/// Convert a concrete MMR leaf into an opaque type.
pub fn from_leaf<T: FullLeaf>(leaf: &T) -> Self {
let encoded_leaf = leaf.using_encoded(|d| d.to_vec(), true);
OpaqueLeaf::from_encoded_leaf(encoded_leaf)
}
/// Create a `OpaqueLeaf` given raw bytes of compact-encoded leaf.
pub fn from_encoded_leaf(encoded_leaf: Vec<u8>) -> Self {
OpaqueLeaf(encoded_leaf)
}
/// Attempt to decode the leaf into expected concrete type.
pub fn try_decode<T: codec::Decode>(&self) -> Option<T> {
codec::Decode::decode(&mut &*self.0).ok()
}
}
impl FullLeaf for OpaqueLeaf {
fn using_encoded<R, F: FnOnce(&[u8]) -> R>(&self, f: F, _compact: bool) -> R {
f(&self.0)
}
}
/// A type-safe wrapper for the concrete leaf type.
///
/// This structure serves merely to avoid passing raw `Vec<u8>` around.
/// It must be `Vec<u8>`-encoding compatible.
///
/// It is different from [`OpaqueLeaf`], because it does implement `Codec`
/// and the encoding has to match raw `Vec<u8>` encoding.
#[derive(codec::Encode, codec::Decode, RuntimeDebug, PartialEq, Eq, TypeInfo)]
pub struct EncodableOpaqueLeaf(pub Vec<u8>);
impl EncodableOpaqueLeaf {
/// Convert a concrete leaf into encodable opaque version.
pub fn from_leaf<T: FullLeaf>(leaf: &T) -> Self {
let opaque = OpaqueLeaf::from_leaf(leaf);
Self::from_opaque_leaf(opaque)
}
/// Given an opaque leaf, make it encodable.
pub fn from_opaque_leaf(opaque: OpaqueLeaf) -> Self {
Self(opaque.0)
}
/// Try to convert into a [OpaqueLeaf].
pub fn into_opaque_leaf(self) -> OpaqueLeaf {
// wrap into `OpaqueLeaf` type
OpaqueLeaf::from_encoded_leaf(self.0)
}
}
/// An element representing either full data or its hash.
///
/// See [Compact] to see how it may be used in practice to reduce the size
/// of proofs in case multiple [LeafDataProvider]s are composed together.
/// This is also used internally by the MMR to differentiate leaf nodes (data)
/// and inner nodes (hashes).
///
/// [DataOrHash::hash] method calculates the hash of this element in its compact form,
/// so should be used instead of hashing the encoded form (which will always be non-compact).
#[derive(RuntimeDebug, Clone, PartialEq)]
pub enum DataOrHash<H: traits::Hash, L> {
/// Arbitrary data in its full form.
Data(L),
/// A hash of some data.
Hash(H::Output),
}
impl<H: traits::Hash, L> From<L> for DataOrHash<H, L> {
fn from(l: L) -> Self {
Self::Data(l)
}
}
mod encoding {
use super::*;
/// A helper type to implement [codec::Codec] for [DataOrHash].
#[derive(codec::Encode, codec::Decode)]
enum Either<A, B> {
Left(A),
Right(B),
}
impl<H: traits::Hash, L: FullLeaf> codec::Encode for DataOrHash<H, L> {
fn encode_to<T: codec::Output + ?Sized>(&self, dest: &mut T) {
match self {
Self::Data(l) => l.using_encoded(
|data| Either::<&[u8], &H::Output>::Left(data).encode_to(dest),
false,
),
Self::Hash(h) => Either::<&[u8], &H::Output>::Right(h).encode_to(dest),
}
}
}
impl<H: traits::Hash, L: FullLeaf + codec::Decode> codec::Decode for DataOrHash<H, L> {
fn decode<I: codec::Input>(value: &mut I) -> Result<Self, codec::Error> {
let decoded: Either<Vec<u8>, H::Output> = Either::decode(value)?;
Ok(match decoded {
Either::Left(l) => DataOrHash::Data(L::decode(&mut &*l)?),
Either::Right(r) => DataOrHash::Hash(r),
})
}
}
}
impl<H: traits::Hash, L: FullLeaf> DataOrHash<H, L> {
/// Retrieve a hash of this item.
///
/// Depending on the node type it's going to either be a contained value for [DataOrHash::Hash]
/// node, or a hash of SCALE-encoded [DataOrHash::Data] data.
pub fn hash(&self) -> H::Output {
match *self {
Self::Data(ref leaf) => leaf.using_encoded(<H as traits::Hash>::hash, true),
Self::Hash(ref hash) => *hash,
}
}
}
/// A composition of multiple leaf elements with compact form representation.
///
/// When composing together multiple [LeafDataProvider]s you will end up with
/// a tuple of `LeafData` that each element provides.
///
/// However this will cause the leaves to have significant size, while for some
/// use cases it will be enough to prove only one element of the tuple.
/// That's the rationale for [Compact] struct. We wrap each element of the tuple
/// into [DataOrHash] and each tuple element is hashed first before constructing
/// the final hash of the entire tuple. This allows you to replace tuple elements
/// you don't care about with their hashes.
#[derive(RuntimeDebug, Clone, PartialEq)]
pub struct Compact<H, T> {
/// Internal tuple representation.
pub tuple: T,
_hash: sp_std::marker::PhantomData<H>,
}
impl<H, T> sp_std::ops::Deref for Compact<H, T> {
type Target = T;
fn deref(&self) -> &Self::Target {
&self.tuple
}
}
impl<H, T> Compact<H, T> {
/// Create a new [Compact] wrapper for a tuple.
pub fn new(tuple: T) -> Self {
Self { tuple, _hash: Default::default() }
}
}
impl<H, T: codec::Decode> codec::Decode for Compact<H, T> {
fn decode<I: codec::Input>(value: &mut I) -> Result<Self, codec::Error> {
T::decode(value).map(Compact::new)
}
}
macro_rules! impl_leaf_data_for_tuple {
( $( $name:ident : $id:tt ),+ ) => {
/// [FullLeaf] implementation for `Compact<H, (DataOrHash<H, Tuple>, ...)>`
impl<H, $( $name ),+> FullLeaf for Compact<H, ( $( DataOrHash<H, $name>, )+ )> where
H: traits::Hash,
$( $name: FullLeaf ),+
{
fn using_encoded<R, F: FnOnce(&[u8]) -> R>(&self, f: F, compact: bool) -> R {
if compact {
codec::Encode::using_encoded(&(
$( DataOrHash::<H, $name>::Hash(self.tuple.$id.hash()), )+
), f)
} else {
codec::Encode::using_encoded(&self.tuple, f)
}
}
}
/// [LeafDataProvider] implementation for `Compact<H, (DataOrHash<H, Tuple>, ...)>`
///
/// This provides a compact-form encoding for tuples wrapped in [Compact].
impl<H, $( $name ),+> LeafDataProvider for Compact<H, ( $( $name, )+ )> where
H: traits::Hash,
$( $name: LeafDataProvider ),+
{
type LeafData = Compact<
H,
( $( DataOrHash<H, $name::LeafData>, )+ ),
>;
fn leaf_data() -> Self::LeafData {
let tuple = (
$( DataOrHash::Data($name::leaf_data()), )+
);
Compact::new(tuple)
}
}
/// [LeafDataProvider] implementation for `(Tuple, ...)`
///
/// This provides regular (non-compactable) composition of [LeafDataProvider]s.
impl<$( $name ),+> LeafDataProvider for ( $( $name, )+ ) where
( $( $name::LeafData, )+ ): FullLeaf,
$( $name: LeafDataProvider ),+
{
type LeafData = ( $( $name::LeafData, )+ );
fn leaf_data() -> Self::LeafData {
(
$( $name::leaf_data(), )+
)
}
}
}
}
/// Test functions implementation for `Compact<H, (DataOrHash<H, Tuple>, ...)>`
#[cfg(test)]
impl<H, A, B> Compact<H, (DataOrHash<H, A>, DataOrHash<H, B>)>
where
H: traits::Hash,
A: FullLeaf,
B: FullLeaf,
{
/// Retrieve a hash of this item in its compact form.
pub fn hash(&self) -> H::Output {
self.using_encoded(<H as traits::Hash>::hash, true)
}
}
impl_leaf_data_for_tuple!(A:0);
impl_leaf_data_for_tuple!(A:0, B:1);
impl_leaf_data_for_tuple!(A:0, B:1, C:2);
impl_leaf_data_for_tuple!(A:0, B:1, C:2, D:3);
impl_leaf_data_for_tuple!(A:0, B:1, C:2, D:3, E:4);
/// An MMR proof data for a group of leaves.
#[derive(codec::Encode, codec::Decode, RuntimeDebug, Clone, PartialEq, Eq, TypeInfo)]
pub struct Proof<Hash> {
/// The indices of the leaves the proof is for.
pub leaf_indices: Vec<LeafIndex>,
/// Number of leaves in MMR, when the proof was generated.
pub leaf_count: NodeIndex,
/// Proof elements (hashes of siblings of inner nodes on the path to the leaf).
pub items: Vec<Hash>,
}
/// Merkle Mountain Range operation error.
#[cfg_attr(feature = "std", derive(thiserror::Error))]
#[derive(RuntimeDebug, codec::Encode, codec::Decode, PartialEq, Eq, TypeInfo)]
pub enum Error {
/// Error during translation of a block number into a leaf index.
#[cfg_attr(feature = "std", error("Error performing numeric op"))]
InvalidNumericOp,
/// Error while pushing new node.
#[cfg_attr(feature = "std", error("Error pushing new node"))]
Push,
/// Error getting the new root.
#[cfg_attr(feature = "std", error("Error getting new root"))]
GetRoot,
/// Error committing changes.
#[cfg_attr(feature = "std", error("Error committing changes"))]
Commit,
/// Error during proof generation.
#[cfg_attr(feature = "std", error("Error generating proof"))]
GenerateProof,
/// Proof verification error.
#[cfg_attr(feature = "std", error("Invalid proof"))]
Verify,
/// Leaf not found in the storage.
#[cfg_attr(feature = "std", error("Leaf was not found"))]
LeafNotFound,
/// Mmr Pallet not included in runtime
#[cfg_attr(feature = "std", error("MMR pallet not included in runtime"))]
PalletNotIncluded,
/// Cannot find the requested leaf index
#[cfg_attr(feature = "std", error("Requested leaf index invalid"))]
InvalidLeafIndex,
/// The provided best know block number is invalid.
#[cfg_attr(feature = "std", error("Provided best known block number invalid"))]
InvalidBestKnownBlock,
}
impl Error {
#![allow(unused_variables)]
/// Consume given error `e` with `self` and generate a native log entry with error details.
pub fn log_error(self, e: impl fmt::Debug) -> Self {
log::error!(
target: "runtime::mmr",
"[{:?}] MMR error: {:?}",
self,
e,
);
self
}
/// Consume given error `e` with `self` and generate a native log entry with error details.
pub fn log_debug(self, e: impl fmt::Debug) -> Self {
log::debug!(
target: "runtime::mmr",
"[{:?}] MMR error: {:?}",
self,
e,
);
self
}
}
sp_api::decl_runtime_apis! {
/// API to interact with MMR pallet.
#[api_version(2)]
pub trait MmrApi<Hash: codec::Codec, BlockNumber: codec::Codec> {
/// Return the on-chain MMR root hash.
fn mmr_root() -> Result<Hash, Error>;
/// Return the number of MMR blocks in the chain.
fn mmr_leaf_count() -> Result<LeafIndex, Error>;
/// Generate MMR proof for a series of block numbers. If `best_known_block_number = Some(n)`,
/// use historical MMR state at given block height `n`. Else, use current MMR state.
fn generate_proof(
block_numbers: Vec<BlockNumber>,
best_known_block_number: Option<BlockNumber>
) -> Result<(Vec<EncodableOpaqueLeaf>, Proof<Hash>), Error>;
/// Verify MMR proof against on-chain MMR for a batch of leaves.
///
/// Note this function will use on-chain MMR root hash and check if the proof matches the hash.
/// Note, the leaves should be sorted such that corresponding leaves and leaf indices have the
/// same position in both the `leaves` vector and the `leaf_indices` vector contained in the [Proof]
fn verify_proof(leaves: Vec<EncodableOpaqueLeaf>, proof: Proof<Hash>) -> Result<(), Error>;
/// Verify MMR proof against given root hash for a batch of leaves.
///
/// Note this function does not require any on-chain storage - the
/// proof is verified against given MMR root hash.
///
/// Note, the leaves should be sorted such that corresponding leaves and leaf indices have the
/// same position in both the `leaves` vector and the `leaf_indices` vector contained in the [Proof]
fn verify_proof_stateless(root: Hash, leaves: Vec<EncodableOpaqueLeaf>, proof: Proof<Hash>)
-> Result<(), Error>;
}
}
#[cfg(test)]
mod tests {
use super::*;
use codec::Decode;
use sp_core::H256;
use sp_runtime::traits::Keccak256;
pub(crate) fn hex(s: &str) -> H256 {
s.parse().unwrap()
}
type Test = DataOrHash<Keccak256, String>;
type TestCompact = Compact<Keccak256, (Test, Test)>;
type TestProof = Proof<<Keccak256 as traits::Hash>::Output>;
#[test]
fn should_encode_decode_proof() {
// given
let proof: TestProof = Proof {
leaf_indices: vec![5],
leaf_count: 10,
items: vec![
hex("c3e7ba6b511162fead58f2c8b5764ce869ed1118011ac37392522ed16720bbcd"),
hex("d3e7ba6b511162fead58f2c8b5764ce869ed1118011ac37392522ed16720bbcd"),
hex("e3e7ba6b511162fead58f2c8b5764ce869ed1118011ac37392522ed16720bbcd"),
],
};
// when
let encoded = codec::Encode::encode(&proof);
let decoded = TestProof::decode(&mut &*encoded);
// then
assert_eq!(decoded, Ok(proof));
}
#[test]
fn should_encode_decode_correctly_if_no_compact() {
// given
let cases = vec![
Test::Data("Hello World!".into()),
Test::Hash(hex("c3e7ba6b511162fead58f2c8b5764ce869ed1118011ac37392522ed16720bbcd")),
Test::Data("".into()),
Test::Data("3e48d6bcd417fb22e044747242451e2c0f3e602d1bcad2767c34808621956417".into()),
];
// when
let encoded = cases.iter().map(codec::Encode::encode).collect::<Vec<_>>();
let decoded = encoded.iter().map(|x| Test::decode(&mut &**x)).collect::<Vec<_>>();
// then
assert_eq!(
decoded,
cases.into_iter().map(Result::<_, codec::Error>::Ok).collect::<Vec<_>>()
);
// check encoding correctness
assert_eq!(
&encoded[0],
&array_bytes::hex2bytes_unchecked("00343048656c6c6f20576f726c6421")
);
assert_eq!(
encoded[1].as_slice(),
array_bytes::hex2bytes_unchecked(
"01c3e7ba6b511162fead58f2c8b5764ce869ed1118011ac37392522ed16720bbcd"
)
.as_slice()
);
}
#[test]
fn should_return_the_hash_correctly() {
// given
let a = Test::Data("Hello World!".into());
let b = Test::Hash(hex("c3e7ba6b511162fead58f2c8b5764ce869ed1118011ac37392522ed16720bbcd"));
// when
let a = a.hash();
let b = b.hash();
// then
assert_eq!(a, hex("a9c321be8c24ba4dc2bd73f5300bde67dc57228ab8b68b607bb4c39c5374fac9"));
assert_eq!(b, hex("c3e7ba6b511162fead58f2c8b5764ce869ed1118011ac37392522ed16720bbcd"));
}
#[test]
fn compact_should_work() {
// given
let a = Test::Data("Hello World!".into());
let b = Test::Data("".into());
// when
let c: TestCompact = Compact::new((a.clone(), b.clone()));
let d: TestCompact = Compact::new((Test::Hash(a.hash()), Test::Hash(b.hash())));
// then
assert_eq!(c.hash(), d.hash());
}
#[test]
fn compact_should_encode_decode_correctly() {
// given
let a = Test::Data("Hello World!".into());
let b = Test::Data("".into());
let c: TestCompact = Compact::new((a.clone(), b.clone()));
let d: TestCompact = Compact::new((Test::Hash(a.hash()), Test::Hash(b.hash())));
let cases = vec![c, d.clone()];
// when
let encoded_compact =
cases.iter().map(|c| c.using_encoded(|x| x.to_vec(), true)).collect::<Vec<_>>();
let encoded =
cases.iter().map(|c| c.using_encoded(|x| x.to_vec(), false)).collect::<Vec<_>>();
let decoded_compact = encoded_compact
.iter()
.map(|x| TestCompact::decode(&mut &**x))
.collect::<Vec<_>>();
let decoded = encoded.iter().map(|x| TestCompact::decode(&mut &**x)).collect::<Vec<_>>();
// then
assert_eq!(
decoded,
cases.into_iter().map(Result::<_, codec::Error>::Ok).collect::<Vec<_>>()
);
assert_eq!(decoded_compact, vec![Ok(d.clone()), Ok(d.clone())]);
}
#[test]
fn opaque_leaves_should_be_full_leaf_compatible() {
// given
let a = Test::Data("Hello World!".into());
let b = Test::Data("".into());
let c: TestCompact = Compact::new((a.clone(), b.clone()));
let d: TestCompact = Compact::new((Test::Hash(a.hash()), Test::Hash(b.hash())));
let cases = vec![c, d.clone()];
let encoded_compact = cases
.iter()
.map(|c| c.using_encoded(|x| x.to_vec(), true))
.map(OpaqueLeaf::from_encoded_leaf)
.collect::<Vec<_>>();
let opaque = cases.iter().map(OpaqueLeaf::from_leaf).collect::<Vec<_>>();
// then
assert_eq!(encoded_compact, opaque);
}
#[test]
fn encode_opaque_leaf_should_be_scale_compatible() {
use codec::Encode;
// given
let a = Test::Data("Hello World!".into());
let case1 = EncodableOpaqueLeaf::from_leaf(&a);
let case2 = EncodableOpaqueLeaf::from_opaque_leaf(OpaqueLeaf(a.encode()));
let case3 = a.encode().encode();
// when
let encoded = vec![&case1, &case2].into_iter().map(|x| x.encode()).collect::<Vec<_>>();
let decoded = vec![&*encoded[0], &*encoded[1], &*case3]
.into_iter()
.map(|x| EncodableOpaqueLeaf::decode(&mut &*x))
.collect::<Vec<_>>();
// then
assert_eq!(case1, case2);
assert_eq!(encoded[0], encoded[1]);
// then encoding should also match double-encoded leaf.
assert_eq!(encoded[0], case3);
assert_eq!(decoded[0], decoded[1]);
assert_eq!(decoded[1], decoded[2]);
assert_eq!(decoded[0], Ok(case2));
assert_eq!(decoded[1], Ok(case1));
}
}