AICup/run.py

import glob
#import pandas as pd
from src.io_tsp import ProblemInstance
from src.TSP_solver import TSPSolver, available_improvers, available_solvers
import numpy as np


def use_solver_to_compute_solution(solver, improve, index, results, name, verbose, show_plots):
    #solver.bind(improve)
    # solver.bind("2-opt")
    # solver.bind("2.5-opt")
    solver.compute_solution(return_value=False, verbose=verbose)
    # solver.pop()
    # solver.pop()

    if verbose:
        print(f"the total length for the solution found is {solver.found_length}",
              f"while the optimal length is {solver.problem_instance.best_sol}",
              f"the gap is {solver.gap}%",
              f"the solution is found in {solver.duration} seconds", sep="\n")

    index.append((name, solver.name_method))
    results.append([solver.found_length, solver.problem_instance.best_sol, solver.gap, solver.duration])

    if show_plots:
        solver.plot_solution()


def run(show_plots=False, verbose=False):
    problems = glob.glob('./problems/*.tsp')

    problems = ["./problems/fl1577.tsp"]

    solvers_names = available_solvers.keys()
    improvers_names = available_improvers.keys()
    results = []
    index = []
    for problem_path in problems:
        prob_instance = ProblemInstance(problem_path)
        if verbose:
            prob_instance.print_info()
        if show_plots:
            prob_instance.plot_data()


        for solver_name in solvers_names:
            solver = TSPSolver(solver_name, prob_instance)
            use_solver_to_compute_solution(solver, None, index, results, problem_path, verbose, show_plots)
            # for improve in improvers_names:
            #     solver = TSPSolver(solver_name, prob_instance)
            #     use_solver_to_compute_solution(solver, improve, index, results, problem_path, verbose, show_plots)
                # for improve2 in [j for j in improvers_names if j not in [improve]]:
                #     use_solver_to_compute_solution(solver, improve2, index, results, problem_path, verbose, show_plots)
                #
                #     for improve3 in [j for j in improvers_names if j not in [improve, improve2]]:
                #         use_solver_to_compute_solution(solver, improve3, index, results, problem_path, verbose,
                #                                        show_plots)
                #         solver.pop()
                #
                #     solver.pop()

        if prob_instance.exist_opt and show_plots:
            solver = TSPSolver("optimal", prob_instance)
            solver.solved = True
            solver.solution = np.concatenate([prob_instance.optimal_tour, [prob_instance.optimal_tour[0]]])
            solver.plot_solution()

    #index = pd.MultiIndex.from_tuples(index, names=['problem', 'method'])

    return None
    #return pd.DataFrame(results, index=index, columns=["tour length", "optimal solution", "gap", "time to solve"])


if __name__ == '__main__':
    df = run(show_plots=True, verbose=True)
    df.to_csv("./results.csv")
need a final check and should be done 2020-09-28 09:56:36 +00:00			`import glob`
Done c++ ant colony opt with 2.5opt = 7.5 2020-11-29 21:17:17 +00:00			`#import pandas as pd`
code reworking WIP 2020-09-28 07:30:21 +00:00			`from src.io_tsp import ProblemInstance`
lab 2 WIP 2020-10-19 15:25:30 +00:00			`from src.TSP_solver import TSPSolver, available_improvers, available_solvers`
First pass of refactor 2020-09-25 09:15:15 +00:00			`import numpy as np`
run 2019-11-18 07:16:45 +00:00
update 2019-10-23 19:07:20 +00:00
code reworking WIP 2020-09-28 09:07:19 +00:00			`def use_solver_to_compute_solution(solver, improve, index, results, name, verbose, show_plots):`
Done c++ ant colony opt with 2.5opt = 7.5 2020-11-29 21:17:17 +00:00			`#solver.bind(improve)`
			`# solver.bind("2-opt")`
			`# solver.bind("2.5-opt")`
code reworking WIP 2020-09-28 07:30:21 +00:00			`solver.compute_solution(return_value=False, verbose=verbose)`
Done c++ ant colony opt with 2.5opt = 7.5 2020-11-29 21:17:17 +00:00			`# solver.pop()`
			`# solver.pop()`
run 2019-12-02 08:11:15 +00:00
			`if verbose:`
			`print(f"the total length for the solution found is {solver.found_length}",`
code reworking WIP 2020-09-28 07:30:21 +00:00			`f"while the optimal length is {solver.problem_instance.best_sol}",`
run 2019-12-02 08:11:15 +00:00			`f"the gap is {solver.gap}%",`
code reworking WIP 2020-09-28 07:30:21 +00:00			`f"the solution is found in {solver.duration} seconds", sep="\n")`
run 2019-12-02 08:11:15 +00:00
			`index.append((name, solver.name_method))`
code reworking WIP 2020-09-28 07:30:21 +00:00			`results.append([solver.found_length, solver.problem_instance.best_sol, solver.gap, solver.duration])`
run 2019-12-02 08:11:15 +00:00
			`if show_plots:`
			`solver.plot_solution()`


run 2019-11-09 15:52:13 +00:00			`def run(show_plots=False, verbose=False):`
Done c++ ant colony opt with 2.5opt = 7.5 2020-11-29 21:17:17 +00:00			`problems = glob.glob('./problems/*.tsp')`

			`problems = ["./problems/fl1577.tsp"]`

code reworking WIP 2020-09-28 07:30:21 +00:00			`solvers_names = available_solvers.keys()`
			`improvers_names = available_improvers.keys()`
udpate 2019-10-31 17:58:06 +00:00			`results = []`
			`index = []`
code reworking WIP 2020-09-28 07:30:21 +00:00			`for problem_path in problems:`
			`prob_instance = ProblemInstance(problem_path)`
run 2019-11-09 15:52:13 +00:00			`if verbose:`
code reworking WIP 2020-09-28 07:30:21 +00:00			`prob_instance.print_info()`
update 2019-10-23 19:19:38 +00:00			`if show_plots:`
code reworking WIP 2020-09-28 07:30:21 +00:00			`prob_instance.plot_data()`
update 2019-10-31 15:17:47 +00:00

Done c++ ant colony opt with 2.5opt = 7.5 2020-11-29 21:17:17 +00:00			`for solver_name in solvers_names:`
			`solver = TSPSolver(solver_name, prob_instance)`
			`use_solver_to_compute_solution(solver, None, index, results, problem_path, verbose, show_plots)`
			`# for improve in improvers_names:`
			`# solver = TSPSolver(solver_name, prob_instance)`
			`# use_solver_to_compute_solution(solver, improve, index, results, problem_path, verbose, show_plots)`
			`# for improve2 in [j for j in improvers_names if j not in [improve]]:`
			`# use_solver_to_compute_solution(solver, improve2, index, results, problem_path, verbose, show_plots)`
			`#`
			`# for improve3 in [j for j in improvers_names if j not in [improve, improve2]]:`
			`# use_solver_to_compute_solution(solver, improve3, index, results, problem_path, verbose,`
			`# show_plots)`
			`# solver.pop()`
			`#`
			`# solver.pop()`
udpate 2019-10-31 17:58:06 +00:00
code reworking WIP 2020-09-28 07:30:21 +00:00			`if prob_instance.exist_opt and show_plots:`
lab 2 WIP 2020-10-19 15:25:30 +00:00			`solver = TSPSolver("optimal", prob_instance)`
need a final check and should be done 2020-09-28 09:56:36 +00:00			`solver.solved = True`
code reworking WIP 2020-09-28 07:30:21 +00:00			`solver.solution = np.concatenate([prob_instance.optimal_tour, [prob_instance.optimal_tour[0]]])`
solver 2019-11-04 05:43:54 +00:00			`solver.plot_solution()`

Done c++ ant colony opt with 2.5opt = 7.5 2020-11-29 21:17:17 +00:00			`#index = pd.MultiIndex.from_tuples(index, names=['problem', 'method'])`
udpate 2019-10-31 17:33:22 +00:00
Done c++ ant colony opt with 2.5opt = 7.5 2020-11-29 21:17:17 +00:00			`return None`
			`#return pd.DataFrame(results, index=index, columns=["tour length", "optimal solution", "gap", "time to solve"])`
update 2019-10-23 19:11:32 +00:00
udpate 2019-10-31 18:05:53 +00:00
update 2019-10-23 19:07:20 +00:00			`if __name__ == '__main__':`
Done c++ ant colony opt with 2.5opt = 7.5 2020-11-29 21:17:17 +00:00			`df = run(show_plots=True, verbose=True)`
run 2019-11-18 07:31:03 +00:00			`df.to_csv("./results.csv")`