JFO_lab_skrzyzowanie/algorytmy_genetyczne.py

import numpy as np
from .decay import GeomDecay


def hill_climb(problem, max_iters=np.inf, restarts=0, init_state=None,
               curve=False, random_state=None):
    """
    best_state array containing state that optimizes the fitness function.
    best_fitness Value of fitness function at best state.
    fitness_curve array containing the fitness at every iteration.
    """
    if (not isinstance(max_iters, int) and max_iters != np.inf
            and not max_iters.is_integer()) or (max_iters < 0):
        raise Exception("""max_iters must be a positive integer.""")

    if (not isinstance(restarts, int) and not restarts.is_integer()) \
       or (restarts < 0):
        raise Exception("""restarts must be a positive integer.""")

    if init_state is not None and len(init_state) != problem.get_length():
        raise Exception("""init_state must have same length as problem.""")

    # Set random seed
    if isinstance(random_state, int) and random_state > 0:
        np.random.seed(random_state)

    best_fitness = -1*np.inf
    best_state = None

    if curve:
        fitness_curve = []

    for _ in range(restarts + 1):
        # Initialize optimization problem
        if init_state is None:
            problem.reset()
        else:
            problem.set_state(init_state)

        iters = 0

        while iters < max_iters:
            iters += 1

            # Find neighbors and determine best neighbor
            problem.find_neighbors()
            next_state = problem.best_neighbor()
            next_fitness = problem.eval_fitness(next_state)

            # If best neighbor is an improvement, move to that state
            if next_fitness > problem.get_fitness():
                problem.set_state(next_state)

            else:
                break

            if curve:
                fitness_curve.append(problem.get_fitness())

        # Update best state and best fitness
        if problem.get_fitness() > best_fitness:
            best_fitness = problem.get_fitness()
            best_state = problem.get_state()

    best_fitness = problem.get_maximize()*best_fitness

    if curve:
        return best_state, best_fitness, np.asarray(fitness_curve)

    return best_state, best_fitness


def random_hill_climb(problem, max_attempts=10, max_iters=np.inf, restarts=0,
                      init_state=None, curve=False, random_state=None):

    if (not isinstance(max_attempts, int) and not max_attempts.is_integer()) \
       or (max_attempts < 0):
        raise Exception("""max_attempts must be a positive integer.""")

    if (not isinstance(max_iters, int) and max_iters != np.inf
            and not max_iters.is_integer()) or (max_iters < 0):
        raise Exception("""max_iters must be a positive integer.""")

    if (not isinstance(restarts, int) and not restarts.is_integer()) \
       or (restarts < 0):
        raise Exception("""restarts must be a positive integer.""")

    if init_state is not None and len(init_state) != problem.get_length():
        raise Exception("""init_state must have same length as problem.""")

    # Set random seed
    if isinstance(random_state, int) and random_state > 0:
        np.random.seed(random_state)

    best_fitness = -1*np.inf
    best_state = None

    if curve:
        fitness_curve = []

    for _ in range(restarts + 1):
        # Initialize optimization problem and attempts counter
        if init_state is None:
            problem.reset()
        else:
            problem.set_state(init_state)

        attempts = 0
        iters = 0

        while (attempts < max_attempts) and (iters < max_iters):
            iters += 1

            # Find random neighbor and evaluate fitness
            next_state = problem.random_neighbor()
            next_fitness = problem.eval_fitness(next_state)

            # If best neighbor is an improvement,
            # move to that state and reset attempts counter
            if next_fitness > problem.get_fitness():
                problem.set_state(next_state)
                attempts = 0

            else:
                attempts += 1

            if curve:
                fitness_curve.append(problem.get_fitness())

        # Update best state and best fitness
        if problem.get_fitness() > best_fitness:
            best_fitness = problem.get_fitness()
            best_state = problem.get_state()

    best_fitness = problem.get_maximize()*best_fitness

    if curve:
        return best_state, best_fitness, np.asarray(fitness_curve)

    return best_state, best_fitness


def simulated_annealing(problem, schedule=GeomDecay(), max_attempts=10,
                        max_iters=np.inf, init_state=None, curve=False,
                        random_state=None):
    
    if (not isinstance(max_attempts, int) and not max_attempts.is_integer()) \
       or (max_attempts < 0):
        raise Exception("""max_attempts must be a positive integer.""")

    if (not isinstance(max_iters, int) and max_iters != np.inf
            and not max_iters.is_integer()) or (max_iters < 0):
        raise Exception("""max_iters must be a positive integer.""")

    if init_state is not None and len(init_state) != problem.get_length():
        raise Exception("""init_state must have same length as problem.""")

    # Set random seed
    if isinstance(random_state, int) and random_state > 0:
        np.random.seed(random_state)

    # Initialize problem, time and attempts counter
    if init_state is None:
        problem.reset()
    else:
        problem.set_state(init_state)

    if curve:
        fitness_curve = []

    attempts = 0
    iters = 0

    while (attempts < max_attempts) and (iters < max_iters):
        temp = schedule.evaluate(iters)
        iters += 1

        if temp == 0:
            break

        else:
            # Find random neighbor and evaluate fitness
            next_state = problem.random_neighbor()
            next_fitness = problem.eval_fitness(next_state)

            # Calculate delta E and change prob
            delta_e = next_fitness - problem.get_fitness()
            prob = np.exp(delta_e/temp)

            # If best neighbor is an improvement or random value is less
            # than prob, move to that state and reset attempts counter
            if (delta_e > 0) or (np.random.uniform() < prob):
                problem.set_state(next_state)
                attempts = 0

            else:
                attempts += 1

        if curve:
            fitness_curve.append(problem.get_fitness())

    best_fitness = problem.get_maximize()*problem.get_fitness()
    best_state = problem.get_state()

    if curve:
        return best_state, best_fitness, np.asarray(fitness_curve)

    return best_state, best_fitness


def genetic_alg(problem, pop_size=200, mutation_prob=0.1, max_attempts=10,
                max_iters=np.inf, curve=False, random_state=None):
    
    if pop_size < 0:
        raise Exception("""pop_size must be a positive integer.""")
    elif not isinstance(pop_size, int):
        if pop_size.is_integer():
            pop_size = int(pop_size)
        else:
            raise Exception("""pop_size must be a positive integer.""")

    if (mutation_prob < 0) or (mutation_prob > 1):
        raise Exception("""mutation_prob must be between 0 and 1.""")

    if (not isinstance(max_attempts, int) and not max_attempts.is_integer()) \
       or (max_attempts < 0):
        raise Exception("""max_attempts must be a positive integer.""")

    if (not isinstance(max_iters, int) and max_iters != np.inf
            and not max_iters.is_integer()) or (max_iters < 0):
        raise Exception("""max_iters must be a positive integer.""")

    # Set random seed
    if isinstance(random_state, int) and random_state > 0:
        np.random.seed(random_state)

    if curve:
        fitness_curve = []

    # Initialize problem, population and attempts counter
    problem.reset()
    problem.random_pop(pop_size)
    attempts = 0
    iters = 0

    while (attempts < max_attempts) and (iters < max_iters):
        iters += 1

        # Calculate breeding probabilities
        problem.eval_mate_probs()

        # Create next generation of population
        next_gen = []

        for _ in range(pop_size):
            # Select parents
            selected = np.random.choice(pop_size, size=2,
                                        p=problem.get_mate_probs())
            parent_1 = problem.get_population()[selected[0]]
            parent_2 = problem.get_population()[selected[1]]

            # Create offspring
            child = problem.reproduce(parent_1, parent_2, mutation_prob)
            next_gen.append(child)

        next_gen = np.array(next_gen)
        problem.set_population(next_gen)

        next_state = problem.best_child()
        next_fitness = problem.eval_fitness(next_state)

        # If best child is an improvement,
        # move to that state and reset attempts counter
        if next_fitness > problem.get_fitness():
            problem.set_state(next_state)
            attempts = 0

        else:
            attempts += 1

        if curve:
            fitness_curve.append(problem.get_fitness())

    best_fitness = problem.get_maximize()*problem.get_fitness()
    best_state = problem.get_state()

    if curve:
        return best_state, best_fitness, np.asarray(fitness_curve)

    return best_state, best_fitness


def mimic(problem, pop_size=200, keep_pct=0.2, max_attempts=10,
          max_iters=np.inf, curve=False, random_state=None, fast_mimic=False):
    """Use MIMIC to find the optimum for a given optimization problem.

    """
    if problem.get_prob_type() == 'continuous':
        raise Exception("""problem type must be discrete or tsp.""")

    if pop_size < 0:
        raise Exception("""pop_size must be a positive integer.""")
    elif not isinstance(pop_size, int):
        if pop_size.is_integer():
            pop_size = int(pop_size)
        else:
            raise Exception("""pop_size must be a positive integer.""")

    if (keep_pct < 0) or (keep_pct > 1):
        raise Exception("""keep_pct must be between 0 and 1.""")

    if (not isinstance(max_attempts, int) and not max_attempts.is_integer()) \
       or (max_attempts < 0):
        raise Exception("""max_attempts must be a positive integer.""")

    if (not isinstance(max_iters, int) and max_iters != np.inf
            and not max_iters.is_integer()) or (max_iters < 0):
        raise Exception("""max_iters must be a positive integer.""")

    # Set random seed
    if isinstance(random_state, int) and random_state > 0:
        np.random.seed(random_state)

    if curve:
        fitness_curve = []

    if fast_mimic not in (True, False):
        raise Exception("""fast_mimic mode must be a boolean.""")
    else:
        problem.mimic_speed = fast_mimic

    # Initialize problem, population and attempts counter
    problem.reset()
    problem.random_pop(pop_size)
    attempts = 0
    iters = 0

    while (attempts < max_attempts) and (iters < max_iters):
        iters += 1

        # Get top n percent of population
        problem.find_top_pct(keep_pct)

        # Update probability estimates
        problem.eval_node_probs()

        # Generate new sample
        new_sample = problem.sample_pop(pop_size)
        problem.set_population(new_sample)

        next_state = problem.best_child()

        next_fitness = problem.eval_fitness(next_state)

        # If best child is an improvement,
        # move to that state and reset attempts counter
        if next_fitness > problem.get_fitness():
            problem.set_state(next_state)
            attempts = 0

        else:
            attempts += 1

        if curve:
            fitness_curve.append(problem.get_fitness())

    best_fitness = problem.get_maximize()*problem.get_fitness()
    best_state = problem.get_state().astype(int)

    if curve:
        return best_state, best_fitness, np.asarray(fitness_curve)

    return best_state, best_fitness