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use std;
use simulation::{Simulation, SimulationType, SimulationResult};
use individual::{Individual};
use population::Population;
pub struct SimulationBuilder<T: Individual + Send + Sync> {
simulation: Simulation<T>,
}
error_chain! {
errors {
EndIterationTooLow
}
}
impl<T: Individual + Send + Sync> SimulationBuilder<T> {
pub fn new() -> SimulationBuilder<T> {
SimulationBuilder {
simulation: Simulation {
type_of_simulation: SimulationType::EndIteration(10),
num_of_threads: 2,
habitat: Vec::new(),
total_time_in_ms: 0.0,
simulation_result: SimulationResult {
improvement_factor: std::f64::MAX,
original_fitness: std::f64::MAX,
fittest: Vec::new(),
iteration_counter: 0
},
share_fittest: false,
num_of_global_fittest: 10,
output_every: 10,
output_every_counter: 0,
share_every: 10,
share_counter: 0
},
}
}
pub fn iterations(mut self, iterations: u32) -> SimulationBuilder<T> {
self.simulation.type_of_simulation = SimulationType::EndIteration(iterations);
self
}
pub fn factor(mut self, factor: f64) -> SimulationBuilder<T> {
self.simulation.type_of_simulation = SimulationType::EndFactor(factor);
self
}
pub fn fitness(mut self, fitness: f64) -> SimulationBuilder<T> {
self.simulation.type_of_simulation = SimulationType::EndFitness(fitness);
self
}
pub fn threads(mut self, threads: usize) -> SimulationBuilder<T> {
self.simulation.num_of_threads = threads;
self
}
pub fn add_population(mut self, population: Population<T>) -> SimulationBuilder<T> {
self.simulation.habitat.push(population);
self
}
pub fn add_multiple_populations(mut self, multiple_populations: Vec<Population<T>>) -> SimulationBuilder<T> {
for population in multiple_populations {
self.simulation.habitat.push(population);
}
self
}
pub fn share_fittest(mut self) -> SimulationBuilder<T> {
self.simulation.share_fittest = true;
self
}
pub fn num_of_global_fittest(mut self, num_of_global_fittest: usize) -> SimulationBuilder<T> {
self.simulation.num_of_global_fittest = num_of_global_fittest;
self
}
pub fn output_every(mut self, output_every: u32) -> SimulationBuilder<T> {
self.simulation.output_every = output_every;
self
}
pub fn share_every(mut self, share_every: u32) -> SimulationBuilder<T> {
self.simulation.share_every = share_every;
self
}
pub fn finalize(self) -> Result<Simulation<T>> {
match self.simulation {
Simulation { type_of_simulation: SimulationType::EndIteration(0...9), .. } => {
Err(ErrorKind::EndIterationTooLow.into())
}
_ => Ok(self.simulation),
}
}
}