Macop UBQP implementation ========================= Let's see how it is possible with the use of the **Macop** package to implement and deal with this UBQP instance problem. Solution structure definition ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Firstly, we are going to use a type of solution that will allow us to define the structure of our solutions. The available ``macop.solutions.discrete.BinarySolution`` type of solution within the Macop package represents exactly what one would wish for. Let's see an example of its use: .. code:: python from macop.solutions.discrete import BinarySolution solution = BinarySolution.random(10) print(solution) The resulting solution obtained: .. code:: bash Binary solution [1 0 1 1 1 0 0 1 1 0] UBQP Evaluator ~~~~~~~~~~~~~~ Now that we have the structure of our solutions, and the means to generate them, we will seek to evaluate them. To do this, we need to create a new evaluator specific to our problem and the relative evaluation function we need to maximise: - :math:`f(x)=x′Qx=\sum_{i=1}^{n}{\sum_{j=1}^{n}{q_{ij}⋅x_i⋅x_j}}` So we are going to create a class that will inherit from the abstract class ``macop.evalutarors.base.Evaluator``: .. code:: python from macop.evaluators.base import Evaluator class UBQPEvaluator(Evaluator): """UBQP evaluator class which enables to compute UBQP solution using specific `_data` - stores into its `_data` dictionary attritute required measures when computing a UBQP solution - `_data['Q']` matrix of size n x n with real values data (stored as numpy array) - `compute` method enables to compute and associate a score to a given UBQP solution """ def compute(self, solution): """Apply the computation of fitness from solution Args: solution: {Solution} -- UBQP solution instance Returns: {float} -- fitness score of solution """ fitness = 0 for index_i, val_i in enumerate(solution.getdata = )): for index_j, val_j in enumerate(solution.getdata = )): fitness += self._data['Q'][index_i, index_j] * val_i * val_j return fitness The cost function for the Unconstrained binary quadratic problem is now well defined. .. tip:: The class proposed here, is available in the Macop package ``macop.evaluators.discrete.mono.UBQPEvaluator``. Running algorithm ~~~~~~~~~~~~~~~~~ Now that the necessary tools are available, we will be able to deal with our problem and look for solutions in the search space of our UBQP instance. Here we will use local search algorithms already implemented in **Macop**. If you are uncomfortable with some of the elements in the code that will follow, you can refer to the more complete **Macop** documentation_ that focuses more on the concepts and tools of the package. .. code:: python # main imports import numpy as np # module imports from macop.solutions.discrete import BinarySolution from macop.evaluators.discrete.mono import UBQPEvaluator from macop.operators.discrete.mutators import SimpleMutation, SimpleBinaryMutation from macop.policies.classicals import RandomPolicy from macop.algorithms.mono import IteratedLocalSearch as ILS from macop.algorithms.mono import HillClimberFirstImprovment # usefull instance data n = 100 qap_instance_file = 'qap_instance.txt' # default validator def validator(solution): return True # define init random solution def init(): return BinarySolution.random(n, validator) # load UBQP instance with open(ubqp_instance_file, 'r') as f: lines = f.readlines() # get all string floating point values of matrix Q_data = ''.join([ line.replace('\n', '') for line in lines[8:] ]) # load the concatenate obtained string Q_matrix = np.fromstring(Q_data, dtype=float, sep=' ').reshape(n, n) print(f'Q_matrix shape: {Q_matrix.shape}') # only one operator here operators = [SimpleMutation(), SimpleBinaryMutation()] # random policy policy = RandomPolicy(operators) # use of loaded data from UBQP instance evaluator = UBQPEvaluator(data={'Q': Q_matrix}) # passing global evaluation param from ILS hcfi = HillClimberFirstImprovment(init, evaluator, operators, policy, validator, maximise=True, verbose=True) algo = ILS(init, evaluator, operators, policy, validator, localSearch=hcfi, maximise=True, verbose=True) # run the algorithm bestSol = algo.run(10000, ls_evaluations=100) print('Solution for UBQP instance score is {}'.format(evaluator.compute(bestSol))) UBQP problem solving is now possible with **Macop**. As a reminder, the complete code is available in the ubqpExample.py_ file. .. _ubqpExample.py: https://github.com/jbuisine/macop/blob/master/examples/ubqpExample.py .. _documentation: https://jbuisine.github.io/macop/_build/html/documentations