/* OpenTally: Open-source election vote counting
* Copyright © 2021 Lee Yingtong Li (RunasSudo)
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program 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 Affero General Public License for more details.
*
* You should have received a copy of the GNU Affero General Public License
* along with this program. If not, see .
*/
use crate::constraints::{Constraints, ConstraintMatrix};
use crate::logger::Logger;
use crate::numbers::Number;
use crate::parser::blt::BLTParser;
use crate::sharandom::SHARandom;
use std::collections::HashMap;
use std::iter::Peekable;
/// An election to be counted
pub struct Election {
/// Name of the election
pub name: String,
/// Number of candidates to be elected
pub seats: usize,
/// [Vec] of [Candidate]s in the election
pub candidates: Vec,
/// Indexes of withdrawn candidates
pub withdrawn_candidates: Vec,
/// [Vec] of [Ballot]s cast in the election
pub ballots: Vec>,
/// Constraints on candidates
pub constraints: Option,
}
impl Election {
/// Parse the given BLT file and return an [Election]
pub fn from_blt>(input: Peekable) -> Self {
let mut parser = BLTParser::new(input);
parser.parse_blt().expect("Syntax Error");
return parser.as_election();
}
/// Convert ballots with weight >1 to multiple ballots of weight 1
pub fn normalise_ballots(&mut self) {
let mut normalised_ballots = Vec::new();
for ballot in self.ballots.iter() {
let mut n = N::new();
let one = N::one();
while n < ballot.orig_value {
let new_ballot = Ballot {
orig_value: N::one(),
preferences: ballot.preferences.clone(),
};
normalised_ballots.push(new_ballot);
n += &one;
}
}
self.ballots = normalised_ballots;
}
}
/// A candidate in an [Election]
#[derive(PartialEq, Eq, Hash)]
pub struct Candidate {
/// Name of the candidate
pub name: String,
}
/// The current state of counting an [Election]
//#[derive(Clone)]
pub struct CountState<'a, N: Number> {
/// Pointer to the [Election] being counted
pub election: &'a Election,
/// [HashMap] of [CountCard]s for each [Candidate] in the election
pub candidates: HashMap<&'a Candidate, CountCard<'a, N>>,
/// [CountCard] representing the exhausted pile
pub exhausted: CountCard<'a, N>,
/// [CountCard] representing loss by fraction
pub loss_fraction: CountCard<'a, N>,
/// [crate::stv::meek::BallotTree] for Meek STV
pub ballot_tree: Option>,
/// Values used to break ties, based on forwards tie-breaking
pub forwards_tiebreak: Option>,
/// Values used to break ties, based on backwards tie-breaking
pub backwards_tiebreak: Option>,
/// [SHARandom] for random tie-breaking
pub random: Option>,
/// Quota for election
pub quota: Option,
/// Vote required for election
///
/// Only used in ERS97/ERS76.
pub vote_required_election: Option,
/// Number of candidates who have been declared elected
pub num_elected: usize,
/// Number of candidates who have been declared excluded
pub num_excluded: usize,
/// [ConstraintMatrix] for constrained elections
pub constraint_matrix: Option,
/// The type of stage being counted
///
/// For example, "Surplus of", "Exclusion of"
pub kind: Option<&'a str>,
/// The description of the stage being counted, excluding [CountState::kind]
pub title: String,
/// [Logger] for this stage of the count
pub logger: Logger<'a>,
}
impl<'a, N: Number> CountState<'a, N> {
/// Construct a new blank [CountState] for the given [Election]
pub fn new(election: &'a Election) -> Self {
let mut state = CountState {
election: &election,
candidates: HashMap::new(),
exhausted: CountCard::new(),
loss_fraction: CountCard::new(),
ballot_tree: None,
forwards_tiebreak: None,
backwards_tiebreak: None,
random: None,
quota: None,
vote_required_election: None,
num_elected: 0,
num_excluded: 0,
constraint_matrix: None,
kind: None,
title: String::new(),
logger: Logger { entries: Vec::new() },
};
for candidate in election.candidates.iter() {
state.candidates.insert(candidate, CountCard::new());
}
for withdrawn_idx in election.withdrawn_candidates.iter() {
state.candidates.get_mut(&election.candidates[*withdrawn_idx]).unwrap().state = CandidateState::Withdrawn;
}
if let Some(constraints) = &election.constraints {
let mut num_groups: Vec = constraints.0.iter().map(|c| c.groups.len()).collect();
let mut cm = ConstraintMatrix::new(&mut num_groups[..]);
// Init constraint matrix total cells min/max
for (i, constraint) in constraints.0.iter().enumerate() {
for (j, group) in constraint.groups.iter().enumerate() {
let mut idx = vec![0; constraints.0.len()];
idx[i] = j + 1;
let mut cell = &mut cm[&idx];
cell.min = group.min;
cell.max = group.max;
}
}
// Fill in grand total, etc.
cm.update_from_state(&state.election, &state.candidates);
cm.init();
//println!("{}", cm);
// Require correct number of candidates to be elected
let idx = vec![0; constraints.0.len()];
cm[&idx].min = election.seats;
cm[&idx].max = election.seats;
state.constraint_matrix = Some(cm);
}
return state;
}
/// [Step](CountCard::step) every [CountCard] to prepare for the next stage
pub fn step_all(&mut self) {
for (_, count_card) in self.candidates.iter_mut() {
count_card.step();
}
self.exhausted.step();
self.loss_fraction.step();
}
}
/// Current state of a [Candidate] during an election count
#[derive(Clone)]
pub struct CountCard<'a, N> {
/// State of the candidate
pub state: CandidateState,
/// Order of election or exclusion
///
/// Positive integers represent order of election; negative integers represent order of exclusion
pub order_elected: isize,
//pub orig_votes: N,
/// Net votes transferred to this candidate in this stage
pub transfers: N,
/// Votes of the candidate at the end of this stage
pub votes: N,
/// Parcels of ballots assigned to this candidate
pub parcels: Vec>,
/// Candidate's keep value (Meek STV)
pub keep_value: Option,
}
impl<'a, N: Number> CountCard<'a, N> {
/// Returns a new blank [CountCard]
pub fn new() -> Self {
return CountCard {
state: CandidateState::Hopeful,
order_elected: 0,
//orig_votes: N::new(),
transfers: N::new(),
votes: N::new(),
parcels: Vec::new(),
keep_value: None,
};
}
/// Transfer the given number of votes to this [CountCard], incrementing [transfers](CountCard::transfers) and [votes](CountCard::votes)
pub fn transfer(&mut self, transfer: &'_ N) {
self.transfers += transfer;
self.votes += transfer;
}
/// Set [transfers](CountCard::transfers) to 0
pub fn step(&mut self) {
//self.orig_votes = self.votes.clone();
self.transfers = N::new();
}
/// Concatenate all parcels into a single parcel, leaving [parcels](CountCard::parcels) empty
pub fn concat_parcels(&mut self) -> Vec> {
let mut result = Vec::new();
for parcel in self.parcels.iter_mut() {
result.append(&mut parcel.votes);
}
return result;
}
}
/// Parcel of [Vote]s during a count
#[derive(Clone)]
pub struct Parcel<'a, N> {
/// [Vote]s in this parcel
pub votes: Vec>,
/// Order for sorting with [crate::stv::ExclusionMethod::BySource]
pub source_order: usize,
}
/// Represents a [Ballot] with an associated value
#[derive(Clone)]
pub struct Vote<'a, N> {
/// Ballot from which the vote is derived
pub ballot: &'a Ballot,
/// Current value of the ballot
pub value: N,
/// Index of the next preference to examine
pub up_to_pref: usize,
}
/// A record of a voter's preferences
pub struct Ballot {
/// Original value/weight of the ballot
pub orig_value: N,
/// Indexes of candidates preferenced on the ballot
pub preferences: Vec,
}
/// State of a [Candidate] during a count
#[allow(dead_code)]
#[derive(PartialEq)]
#[derive(Clone)]
pub enum CandidateState {
/// Hopeful (continuing candidate)
Hopeful,
/// Required by constraints to be guarded from exclusion
Guarded,
/// Declared elected
Elected,
/// Required by constraints to be doomed to be excluded
Doomed,
/// Withdrawn candidate
Withdrawn,
/// Declared excluded
Excluded,
}