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pezkuwi-subxt/substrate/frame/election-provider-support/src/lib.rs
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Kian Paimani f10203c793 move generics of election trait to associated types (#10475)
* move generics of election trait to associated types

* fix doctest
2021-12-16 06:24:28 +00:00

475 lines
18 KiB
Rust

// This file is part of Substrate.
// Copyright (C) 2020 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.
//! Primitive traits for providing election functionality.
//!
//! This crate provides two traits that could interact to enable extensible election functionality
//! within FRAME pallets.
//!
//! Something that will provide the functionality of election will implement [`ElectionProvider`],
//! whilst needing an associated [`ElectionProvider::DataProvider`], which needs to be fulfilled by
//! an entity implementing [`ElectionDataProvider`]. Most often, *the data provider is* the receiver
//! of the election, resulting in a diagram as below:
//!
//! ```ignore
//! ElectionDataProvider
//! <------------------------------------------+
//! | |
//! v |
//! +-----+----+ +------+---+
//! | | | |
//! pallet-do-election | | | | pallet-needs-election
//! | | | |
//! | | | |
//! +-----+----+ +------+---+
//! | ^
//! | |
//! +------------------------------------------+
//! ElectionProvider
//! ```
//!
//! > It could also be possible that a third party pallet (C), provides the data of election to an
//! > election provider (B), which then passes the election result to another pallet (A).
//!
//! ## Election Types
//!
//! Typically, two types of elections exist:
//!
//! 1. **Stateless**: Election data is provided, and the election result is immediately ready.
//! 2. **Stateful**: Election data is is queried ahead of time, and the election result might be
//! ready some number of blocks in the future.
//!
//! To accommodate both type of elections in one trait, the traits lean toward **stateful
//! election**, as it is more general than the stateless. This is why [`ElectionProvider::elect`]
//! has no parameters. All value and type parameter must be provided by the [`ElectionDataProvider`]
//! trait, even if the election happens immediately.
//!
//! ## Election Data
//!
//! The data associated with an election, essentially what the [`ElectionDataProvider`] must convey
//! is as follows:
//!
//! 1. A list of voters, with their stake.
//! 2. A list of targets (i.e. _candidates_).
//! 3. A number of desired targets to be elected (i.e. _winners_)
//!
//! In addition to that, the [`ElectionDataProvider`] must also hint [`ElectionProvider`] at when
//! the next election might happen ([`ElectionDataProvider::next_election_prediction`]). A stateless
//! election provider would probably ignore this. A stateful election provider can use this to
//! prepare the election result in advance.
//!
//! Nonetheless, an [`ElectionProvider`] shan't rely on this and should preferably provide some
//! means of fallback election as well, in case the `elect` was called immaturely early.
//!
//! ## Example
//!
//! ```rust
//! # use frame_election_provider_support::{*, data_provider};
//! # use sp_npos_elections::{Support, Assignment};
//!
//! type AccountId = u64;
//! type Balance = u64;
//! type BlockNumber = u32;
//!
//! mod data_provider_mod {
//! use super::*;
//!
//! pub trait Config: Sized {
//! type ElectionProvider: ElectionProvider<
//! AccountId = AccountId,
//! BlockNumber = BlockNumber,
//! DataProvider = Pallet<Self>,
//! >;
//! }
//!
//! pub struct Pallet<T: Config>(std::marker::PhantomData<T>);
//!
//! impl<T: Config> ElectionDataProvider for Pallet<T> {
//! type AccountId = AccountId;
//! type BlockNumber = BlockNumber;
//! const MAXIMUM_VOTES_PER_VOTER: u32 = 1;
//!
//! fn desired_targets() -> data_provider::Result<u32> {
//! Ok(1)
//! }
//! fn voters(maybe_max_len: Option<usize>)
//! -> data_provider::Result<Vec<(AccountId, VoteWeight, Vec<AccountId>)>>
//! {
//! Ok(Default::default())
//! }
//! fn targets(maybe_max_len: Option<usize>) -> data_provider::Result<Vec<AccountId>> {
//! Ok(vec![10, 20, 30])
//! }
//! fn next_election_prediction(now: BlockNumber) -> BlockNumber {
//! 0
//! }
//! }
//! }
//!
//!
//! mod generic_election_provider {
//! use super::*;
//!
//! pub struct GenericElectionProvider<T: Config>(std::marker::PhantomData<T>);
//!
//! pub trait Config {
//! type DataProvider: ElectionDataProvider<AccountId=AccountId, BlockNumber = BlockNumber>;
//! }
//!
//! impl<T: Config> ElectionProvider for GenericElectionProvider<T> {
//! type AccountId = AccountId;
//! type BlockNumber = BlockNumber;
//! type Error = &'static str;
//! type DataProvider = T::DataProvider;
//!
//! fn elect() -> Result<Supports<AccountId>, Self::Error> {
//! Self::DataProvider::targets(None)
//! .map_err(|_| "failed to elect")
//! .map(|t| vec![(t[0], Support::default())])
//! }
//! }
//! }
//!
//! mod runtime {
//! use super::generic_election_provider;
//! use super::data_provider_mod;
//! use super::AccountId;
//!
//! struct Runtime;
//! impl generic_election_provider::Config for Runtime {
//! type DataProvider = data_provider_mod::Pallet<Runtime>;
//! }
//!
//! impl data_provider_mod::Config for Runtime {
//! type ElectionProvider = generic_election_provider::GenericElectionProvider<Runtime>;
//! }
//!
//! }
//!
//! # fn main() {}
//! ```
#![cfg_attr(not(feature = "std"), no_std)]
pub mod onchain;
use frame_support::traits::Get;
use sp_std::{fmt::Debug, prelude::*};
/// Re-export some type as they are used in the interface.
pub use sp_arithmetic::PerThing;
pub use sp_npos_elections::{
Assignment, ElectionResult, ExtendedBalance, IdentifierT, PerThing128, Support, Supports,
VoteWeight,
};
/// Types that are used by the data provider trait.
pub mod data_provider {
/// Alias for the result type of the election data provider.
pub type Result<T> = sp_std::result::Result<T, &'static str>;
}
/// Something that can provide the data to an [`ElectionProvider`].
pub trait ElectionDataProvider {
/// The account identifier type.
type AccountId;
/// The block number type.
type BlockNumber;
/// Maximum number of votes per voter that this data provider is providing.
const MAXIMUM_VOTES_PER_VOTER: u32;
/// All possible targets for the election, i.e. the candidates.
///
/// If `maybe_max_len` is `Some(v)` then the resulting vector MUST NOT be longer than `v` items
/// long.
///
/// This should be implemented as a self-weighing function. The implementor should register its
/// appropriate weight at the end of execution with the system pallet directly.
fn targets(maybe_max_len: Option<usize>) -> data_provider::Result<Vec<Self::AccountId>>;
/// All possible voters for the election.
///
/// Note that if a notion of self-vote exists, it should be represented here.
///
/// If `maybe_max_len` is `Some(v)` then the resulting vector MUST NOT be longer than `v` items
/// long.
///
/// This should be implemented as a self-weighing function. The implementor should register its
/// appropriate weight at the end of execution with the system pallet directly.
fn voters(
maybe_max_len: Option<usize>,
) -> data_provider::Result<Vec<(Self::AccountId, VoteWeight, Vec<Self::AccountId>)>>;
/// The number of targets to elect.
///
/// This should be implemented as a self-weighing function. The implementor should register its
/// appropriate weight at the end of execution with the system pallet directly.
fn desired_targets() -> data_provider::Result<u32>;
/// Provide a best effort prediction about when the next election is about to happen.
///
/// In essence, the implementor should predict with this function when it will trigger the
/// [`ElectionProvider::elect`].
///
/// This is only useful for stateful election providers.
fn next_election_prediction(now: Self::BlockNumber) -> Self::BlockNumber;
/// Utility function only to be used in benchmarking scenarios, to be implemented optionally,
/// else a noop.
#[cfg(any(feature = "runtime-benchmarks", test))]
fn put_snapshot(
_voters: Vec<(Self::AccountId, VoteWeight, Vec<Self::AccountId>)>,
_targets: Vec<Self::AccountId>,
_target_stake: Option<VoteWeight>,
) {
}
/// Utility function only to be used in benchmarking scenarios, to be implemented optionally,
/// else a noop.
///
/// Same as `put_snapshot`, but can add a single voter one by one.
#[cfg(any(feature = "runtime-benchmarks", test))]
fn add_voter(_voter: Self::AccountId, _weight: VoteWeight, _targets: Vec<Self::AccountId>) {}
/// Utility function only to be used in benchmarking scenarios, to be implemented optionally,
/// else a noop.
///
/// Same as `put_snapshot`, but can add a single voter one by one.
#[cfg(any(feature = "runtime-benchmarks", test))]
fn add_target(_target: Self::AccountId) {}
/// Clear all voters and targets.
#[cfg(any(feature = "runtime-benchmarks", test))]
fn clear() {}
}
/// An election data provider that should only be used for testing.
#[cfg(feature = "std")]
pub struct TestDataProvider<X>(sp_std::marker::PhantomData<X>);
#[cfg(feature = "std")]
impl<AccountId, BlockNumber> ElectionDataProvider for TestDataProvider<(AccountId, BlockNumber)> {
type AccountId = AccountId;
type BlockNumber = BlockNumber;
const MAXIMUM_VOTES_PER_VOTER: u32 = 0;
fn targets(_maybe_max_len: Option<usize>) -> data_provider::Result<Vec<AccountId>> {
Ok(Default::default())
}
fn voters(
_maybe_max_len: Option<usize>,
) -> data_provider::Result<Vec<(AccountId, VoteWeight, Vec<AccountId>)>> {
Ok(Default::default())
}
fn desired_targets() -> data_provider::Result<u32> {
Ok(Default::default())
}
fn next_election_prediction(now: BlockNumber) -> BlockNumber {
now
}
}
/// Something that can compute the result of an election and pass it back to the caller.
///
/// This trait only provides an interface to _request_ an election, i.e.
/// [`ElectionProvider::elect`]. That data required for the election need to be passed to the
/// implemented of this trait through [`ElectionProvider::DataProvider`].
pub trait ElectionProvider {
/// The account identifier type.
type AccountId;
/// The block number type.
type BlockNumber;
/// The error type that is returned by the provider.
type Error: Debug;
/// The data provider of the election.
type DataProvider: ElectionDataProvider<
AccountId = Self::AccountId,
BlockNumber = Self::BlockNumber,
>;
/// Elect a new set of winners.
///
/// The result is returned in a target major format, namely as vector of supports.
///
/// This should be implemented as a self-weighing function. The implementor should register its
/// appropriate weight at the end of execution with the system pallet directly.
fn elect() -> Result<Supports<Self::AccountId>, Self::Error>;
}
/// An election provider to be used only for testing.
#[cfg(feature = "std")]
pub struct NoElection<X>(sp_std::marker::PhantomData<X>);
#[cfg(feature = "std")]
impl<AccountId, BlockNumber> ElectionProvider for NoElection<(AccountId, BlockNumber)> {
type AccountId = AccountId;
type BlockNumber = BlockNumber;
type Error = &'static str;
type DataProvider = TestDataProvider<(AccountId, BlockNumber)>;
fn elect() -> Result<Supports<AccountId>, Self::Error> {
Err("<NoElection as ElectionProvider> cannot do anything.")
}
}
/// A utility trait for something to implement `ElectionDataProvider` in a sensible way.
///
/// This is generic over `AccountId` and it can represent a validator, a nominator, or any other
/// entity.
///
/// To simplify the trait, the `VoteWeight` is hardcoded as the weight of each entity. The weights
/// are ascending, the higher, the better. In the long term, if this trait ends up having use cases
/// outside of the election context, it is easy enough to make it generic over the `VoteWeight`.
///
/// Something that implements this trait will do a best-effort sort over ids, and thus can be
/// used on the implementing side of [`ElectionDataProvider`].
pub trait SortedListProvider<AccountId> {
/// The list's error type.
type Error;
/// An iterator over the list, which can have `take` called on it.
fn iter() -> Box<dyn Iterator<Item = AccountId>>;
/// The current count of ids in the list.
fn count() -> u32;
/// Return true if the list already contains `id`.
fn contains(id: &AccountId) -> bool;
/// Hook for inserting a new id.
fn on_insert(id: AccountId, weight: VoteWeight) -> Result<(), Self::Error>;
/// Hook for updating a single id.
fn on_update(id: &AccountId, weight: VoteWeight);
/// Hook for removing am id from the list.
fn on_remove(id: &AccountId);
/// Regenerate this list from scratch. Returns the count of items inserted.
///
/// This should typically only be used at a runtime upgrade.
///
/// ## WARNING
///
/// This function should be called with care, regenerate will remove the current list write the
/// new list, which can lead to too many storage accesses, exhausting the block weight.
fn unsafe_regenerate(
all: impl IntoIterator<Item = AccountId>,
weight_of: Box<dyn Fn(&AccountId) -> VoteWeight>,
) -> u32;
/// Remove all items from the list.
///
/// ## WARNING
///
/// This function should never be called in production settings because it can lead to an
/// unbounded amount of storage accesses.
fn unsafe_clear();
/// Sanity check internal state of list. Only meant for debug compilation.
fn sanity_check() -> Result<(), &'static str>;
/// If `who` changes by the returned amount they are guaranteed to have a worst case change
/// in their list position.
#[cfg(feature = "runtime-benchmarks")]
fn weight_update_worst_case(_who: &AccountId, _is_increase: bool) -> VoteWeight {
VoteWeight::MAX
}
}
/// Something that can provide the `VoteWeight` of an account. Similar to [`ElectionProvider`] and
/// [`ElectionDataProvider`], this should typically be implementing by whoever is supposed to *use*
/// `SortedListProvider`.
pub trait VoteWeightProvider<AccountId> {
/// Get the current `VoteWeight` of `who`.
fn vote_weight(who: &AccountId) -> VoteWeight;
/// For tests and benchmarks, set the `VoteWeight`.
#[cfg(any(feature = "runtime-benchmarks", test))]
fn set_vote_weight_of(_: &AccountId, _: VoteWeight) {}
}
/// Something that can compute the result to an NPoS solution.
pub trait NposSolver {
/// The account identifier type of this solver.
type AccountId: sp_npos_elections::IdentifierT;
/// The accuracy of this solver. This will affect the accuracy of the output.
type Accuracy: PerThing128;
/// The error type of this implementation.
type Error: sp_std::fmt::Debug + sp_std::cmp::PartialEq;
/// Solve an NPoS solution with the given `voters`, `targets`, and select `to_elect` count
/// of `targets`.
fn solve(
to_elect: usize,
targets: Vec<Self::AccountId>,
voters: Vec<(Self::AccountId, VoteWeight, Vec<Self::AccountId>)>,
) -> Result<ElectionResult<Self::AccountId, Self::Accuracy>, Self::Error>;
}
/// A wrapper for [`sp_npos_elections::seq_phragmen`] that implements [`NposSolver`]. See the
/// documentation of [`sp_npos_elections::seq_phragmen`] for more info.
pub struct SequentialPhragmen<AccountId, Accuracy, Balancing = ()>(
sp_std::marker::PhantomData<(AccountId, Accuracy, Balancing)>,
);
impl<
AccountId: IdentifierT,
Accuracy: PerThing128,
Balancing: Get<Option<(usize, ExtendedBalance)>>,
> NposSolver for SequentialPhragmen<AccountId, Accuracy, Balancing>
{
type AccountId = AccountId;
type Accuracy = Accuracy;
type Error = sp_npos_elections::Error;
fn solve(
winners: usize,
targets: Vec<Self::AccountId>,
voters: Vec<(Self::AccountId, VoteWeight, Vec<Self::AccountId>)>,
) -> Result<ElectionResult<Self::AccountId, Self::Accuracy>, Self::Error> {
sp_npos_elections::seq_phragmen(winners, targets, voters, Balancing::get())
}
}
/// A wrapper for [`sp_npos_elections::phragmms()`] that implements [`NposSolver`]. See the
/// documentation of [`sp_npos_elections::phragmms()`] for more info.
pub struct PhragMMS<AccountId, Accuracy, Balancing = ()>(
sp_std::marker::PhantomData<(AccountId, Accuracy, Balancing)>,
);
impl<
AccountId: IdentifierT,
Accuracy: PerThing128,
Balancing: Get<Option<(usize, ExtendedBalance)>>,
> NposSolver for PhragMMS<AccountId, Accuracy, Balancing>
{
type AccountId = AccountId;
type Accuracy = Accuracy;
type Error = sp_npos_elections::Error;
fn solve(
winners: usize,
targets: Vec<Self::AccountId>,
voters: Vec<(Self::AccountId, VoteWeight, Vec<Self::AccountId>)>,
) -> Result<ElectionResult<Self::AccountId, Self::Accuracy>, Self::Error> {
sp_npos_elections::phragmms(winners, targets, voters, Balancing::get())
}
}