import threading #fix import time import random import numpy as np from concurrent.futures import ThreadPoolExecutor def gaussian_determinant(matrix): n = len(matrix) mat = [row[:] for row in matrix] for i in range(n): max_row = max(range(i, n), key=lambda r: abs(mat[r][i])) mat[i], mat[max_row] = mat[max_row], mat[i] if mat[i][i] == 0: return 0 for j in range(i + 1, n): factor = mat[j][i] / mat[i][i] for k in range(i, n): mat[j][k] -= mat[i][k] * factor det = 1 for i in range(n): det *= mat[i][i] return det def parallel_determinant(matrix, num_threads=4): n = len(matrix) result = [] def worker(start_row, end_row): partial_det = 1 for i in range(start_row, end_row): partial_det *= matrix[i][i] result.append(partial_det) with ThreadPoolExecutor(max_workers=num_threads) as executor: rows_per_thread = n // num_threads futures = [executor.submit(worker, i * rows_per_thread, (i + 1) * rows_per_thread) for i in range(num_threads)] for future in futures: future.result() return sum(result) def generate_matrix(size): return [[random.randint(1, 10) for _ in range(size)] for _ in range(size)] matrix_sizes = [100, 300, 500] num_threads = 4 for size in matrix_sizes: print(f"\nБенчмарки для матрицы {size}x{size}:") matrix = generate_matrix(size) start = time.time() det_seq = gaussian_determinant(matrix) end = time.time() print(f"Детерминант (последовательно, метод Гаусса): {det_seq}, время: {end - start:.5f} сек") start = time.time() det_par = parallel_determinant(matrix, num_threads=num_threads) end = time.time() print(f"Детерминант (параллельно): {det_par}, время: {end - start:.5f} сек")