4 Galaxy Gravity Optimization.py

import numpy as np
import matplotlib.pyplot as plt
from memory_profiler import memory_usage
import time

# Define all 20 benchmark functions
def ackley(x):
    x = np.array(x)
    a, b, c = 20, 0.2, 2 * np.pi
    d = len(x)
    sum1 = np.sum(x**2)
    sum2 = np.sum(np.cos(c * x))
    return -a * np.exp(-b * np.sqrt(sum1 / d)) - np.exp(sum2 / d) + a + np.exp(1)

def booth(x):
    x = np.array(x)
    return (x[0] + 2 * x[1] - 7)**2 + (2 * x[0] + x[1] - 5)**2

def rastrigin(x):
    x = np.array(x)
    A = 10
    return A * len(x) + np.sum(x**2 - A * np.cos(2 * np.pi * x))

def rosenbrock(x):
    x = np.array(x)
    return np.sum(100 * (x[1:] - x[:-1]**2)**2 + (1 - x[:-1])**2)

def schwefel(x):
    x = np.array(x)
    return 418.9829 * len(x) - np.sum(x * np.sin(np.sqrt(np.abs(x))))

def sphere(x):
    x = np.array(x)
    return np.sum(x**2)

def michalewicz(x):
    x = np.array(x)
    m = 10
    return -np.sum(np.sin(x) * np.sin(((np.arange(len(x)) + 1) * x**2) / np.pi)**(2 * m))

def zakharov(x):
    x = np.array(x)
    sum1 = np.sum(x**2)
    sum2 = np.sum(0.5 * (np.arange(len(x)) + 1) * x)
    return sum1 + sum2**2 + sum2**4

def eggholder(x):
    x = np.array(x)
    return -(x[1] + 47) * np.sin(np.sqrt(abs(x[0]/2 + (x[1] + 47)))) - x[0] * np.sin(np.sqrt(abs(x[0] - (x[1] + 47))))

def beale(x):
    x = np.array(x)
    return (1.5 - x[0] + x[0]*x[1])**2 + (2.25 - x[0] + x[0]*x[1]**2)**2 + (2.625 - x[0] + x[0]*x[1]**3)**2

def trid(x):
    x = np.array(x)
    return np.sum((x - 1)**2) - np.sum(x[:-1] * x[1:])

def dixon_price(x):
    x = np.array(x)
    return (x[0] - 1)**2 + np.sum([(i + 1) * (2 * x[i]**2 - x[i-1])**2 for i in range(1, len(x))])

def cross_in_tray(x):
    x = np.array(x)
    fact1 = np.sin(x[0]) * np.sin(x[1])
    fact2 = np.exp(abs(100 - np.sqrt(x[0]**2 + x[1]**2) / np.pi))
    return -0.0001 * (abs(fact1 * fact2) + 1)**0.1

def griewank(x):
    x = np.array(x)
    return 1 + np.sum(x**2 / 4000) - np.prod(np.cos(x / np.sqrt(np.arange(1, len(x) + 1))))

def levy(x):
    x = np.array(x)
    w = 1 + (x - 1) / 4
    term1 = np.sin(np.pi * w[0])**2
    term2 = np.sum((w[:-1] - 1)**2 * (1 + 10 * np.sin(np.pi * w[:-1] + 1)**2))
    term3 = (w[-1] - 1)**2 * (1 + np.sin(2 * np.pi * w[-1])**2)
    return term1 + term2 + term3

def matyas(x):
    x = np.array(x)
    return 0.26 * (x[0]**2 + x[1]**2) - 0.48 * x[0] * x[1]

def goldstein_price(x):
    x = np.array(x)
    term1 = 1 + ((x[0] + x[1] + 1)**2) * (19 - 14*x[0] + 3*x[0]**2 - 14*x[1] + 6*x[0]*x[1] + 3*x[1]**2)
    term2 = 30 + ((2*x[0] - 3*x[1])**2) * (18 - 32*x[0] + 12*x[0]**2 + 48*x[1] - 36*x[0]*x[1] + 27*x[1]**2)
    return term1 * term2

def powell(x):
    x = np.array(x)
    term1 = (x[0] + 10*x[1])**2
    term2 = 5 * (x[2] - x[3])**2
    term3 = (x[1] - 2*x[2])**4
    term4 = 10 * (x[0] - x[3])**4
    return term1 + term2 + term3 + term4

def bird(x):
    x = np.array(x)
    return np.sin(x[0]) * np.exp((1 - np.cos(x[1]))**2) + np.cos(x[1]) * np.exp((1 - np.sin(x[0]))**2) + (x[0] - x[1])**2

def pyramid(x):
    x = np.array(x)
    return np.sum(np.abs(x) * np.sin(x))
# Galaxy Gravity Optimization Algorithm
def galaxy_gravity_optimization(func, bounds, population_size=50, generations=100, G=1, mass_decay=0.98):
    dimensions = len(bounds)

    # Initialize population
    population = np.random.uniform(
        [b[0] for b in bounds], [b[1] for b in bounds], (population_size, dimensions)
    )
    velocities = np.random.uniform(-1, 1, (population_size, dimensions))
    masses = np.random.uniform(1, 5, population_size)  # Initialize comet masses
    best_solution = None
    best_cost = float('inf')
    cost_history = []

    for generation in range(generations):
        # Evaluate fitness of the population
        fitness = np.array([func(ind) for ind in population])
        best_index = np.argmin(fitness)
        if fitness[best_index] < best_cost:
            best_cost = fitness[best_index]
            best_solution = population[best_index]

        # Normalize fitness to calculate masses
        norm_fitness = (fitness - np.min(fitness)) + 1e-6
        masses = 1 / norm_fitness
        masses /= np.sum(masses)

        # Apply gravitational forces
        for i in range(population_size):
            force = np.zeros(dimensions)
            for j in range(population_size):
                if i != j:
                    distance = np.linalg.norm(population[i] - population[j]) + 1e-6
                    gravitational_force = G * (masses[i] * masses[j]) / (distance**2)
                    force += gravitational_force * (population[j] - population[i])
            acceleration = force / masses[i]
            velocities[i] = velocities[i] * mass_decay + acceleration
            population[i] += velocities[i]

            # Bound positions
            population[i] = np.clip(population[i], [b[0] for b in bounds], [b[1] for b in bounds])

        cost_history.append(best_cost)

    return best_solution, cost_history

# Map GGO Complexity to Standard Classes
def map_ggo_complexity(n, g, d):
    complexity_classes = {
        "O(1)": 1,
        "O(log n)": lambda n: np.log2(n),
        "O(n)": lambda n: n,
        "O(n log n)": lambda n: n * np.log2(n),
        "O(n^2)": lambda n: n**2,
        "O(n^3)": lambda n: n**3,
        "O(2^n)": lambda n: 2**n,
        "O(n!)": lambda n: np.math.factorial(n)
    }

    time_complexity = n * d * g  # GGO complexity: population size × dimensions × generations

    for label, func in complexity_classes.items():
        if callable(func) and time_complexity <= func(n):
            return label
    return "O(n^2)"  # Default fallback

# Benchmark functions and bounds
functions = [
    ("1. Ackley", ackley, [(-5, 5)] * 2),
    ("2. Booth", booth, [(-5, 5)] * 2),
    ("3. Rastrigin", rastrigin, [(-5, 5)] * 2),
    ("4. Rosenbrock", rosenbrock, [(-5, 5)] * 2),
    ("5. Schwefel", schwefel, [(-500, 500)] * 2),
    ("6. Sphere", sphere, [(-5, 5)] * 2),
    ("7. Michalewicz", michalewicz, [(0, np.pi)] * 2),
    ("8. Zakharov", zakharov, [(-5, 5)] * 2),
    ("9. Eggholder", eggholder, [(-512, 512)] * 2),
    ("10. Beale", beale, [(-4.5, 4.5)] * 2),
    ("11. Trid", trid, [(-5, 5)] * 2),
    ("12. Dixon-Price", dixon_price, [(-5, 5)] * 2),
    ("13. Cross-in-Tray", cross_in_tray, [(-10, 10)] * 2),
    ("14. Griewank", griewank, [(-600, 600)] * 2),
    ("15. Levy", levy, [(-10, 10)] * 2),
    ("16. Matyas", matyas, [(-10, 10)] * 2),
    ("17. Goldstein-Price", goldstein_price, [(-2, 2)] * 2),
    ("18. Powell", powell, [(-5, 5)] * 4),
    ("19. Bird", bird, [(-2 * np.pi, 2 * np.pi)] * 2),
    ("20. Pyramid", pyramid, [(-5, 5)] * 2)
]

# Run GGO and visualize results
fig, axes = plt.subplots(4, 5, figsize=(20, 20))
axes = axes.ravel()

for idx, (name, func, bounds) in enumerate(functions):
    print(f"\nRunning {name}...")

    start_time = time.time()
    memory_before = memory_usage()[0]

    population_size = 50
    generations = 100
    d = len(bounds)

    best_x, costs = galaxy_gravity_optimization(func, bounds, population_size=population_size, generations=generations)

    memory_after = memory_usage()[0]
    end_time = time.time()

    # Map and report complexity
    complexity_category = map_ggo_complexity(population_size, generations, d)

    print(f"Function: {name}")
    print(f"Best Cost: {costs[-1]:.10f}")
    print(f"Convergence Time: {end_time - start_time:.10f} seconds")
    print(f"Memory Usage: {memory_after - memory_before:.10f} MB")
    print(f"Complexity Class (theoretical): {complexity_category}")
    print(f"Complexity (previous form): O(n * d * g)")

    if idx < len(axes):
        axes[idx].plot(costs)
        axes[idx].set_title(name)
        axes[idx].set_xlabel("Generations")
        axes[idx].set_ylabel("Cost")

plt.tight_layout()
plt.show()