Evolver: Meta-optimizing multi-objective metaheuristics

Evolver is a tool based on the formulation of the automatic configuration and design of multi-objective metaheuristics as a multi-objective optimization problem that can be solved by using the same kind of algorithms, i.e., Evolver applies a meta-optimization approach.

The basis of Evolver are:

• A multi-objective metaheuristic algorithm in which, given one or several problems used as training set, a configuration of it is sought that solves the training set in an efficient way. This algorithm is referred as to the Configurable Algorithm.
• A design space associated to the configurable algorithm which defines their parameters and components subject to be configured.
• A list of quality indicators used as objectives to minimize when using the configurable algorithm to solve a problem of the training set.
• A meta-optimizer algorithm which is used to solve the optimization problem defined by minimizing the quality indicators of an configurable algorithm given a particular training set.

The project is made of two parts:

• Evolver: A Java library built with maven that implements the meta-optimization approach.
• Evolver Dashboard: A Python dashboard built with Streamlit that allows to configure and execute Evolver from an user-friendly web application.

Evolver is described in the paper Evolver: Meta-optimizing multi-objective metaheuristics, published in SoftwareX.

Pre-requisites

• Java 17 or higher
• Maven 3.6.3 or higher
• Python 3.9 and <3.11 (Optional, only for the GUI)

Evolver is based on jMetal 6.1, so all the stuff provided by that framework (algorithms, problems, quality indicators, utilities) are available in Evolver.

You can use Evolver through Docker using our pre-built images. More information in the Docker section

Execute Evolver

To execute Evolver, first build the project with Maven:

$ mvn package

Then, you have three options:

• Use the MetaRunner class, which takes as a parameter a configuration file. This is the simplest way but only some parameters of the meta-runner can be set.
• Define a runner program which provides you full control to set the meta-optimizer parameters.
• Use a Graphical User Interface (GUI).

Using the MetaRunner class

To run the metarunner class, just execute the following command:

$ java -cp target/Evolver-1.0-jar-with-dependencies.jar org.uma.evolver.MetaRunner <path-to-configuration-file>

The configuration file describes an Evolver configuration by using a YAML file. The following example can use a generic NSGAII to auto-design the NSGAII algorithm to solve the ZDT1, ZDT4, and DTLZ3 problems. You can find more example configurations at the configurationFiles folder of the project.

general_config:
    dashboard_mode: false
    output_directory: /tmp/evolver
    cpu_cores: 8
    plotting_frequency: 100

meta_optimizer_arguments:
    meta_optimizer_algorithm: NSGAII
    meta_optimizer_population_size: 50
    meta_optimizer_max_evaluations: 3000
    indicators_names: NHV,EP

configurable_algorithm_arguments:
    configurable_algorithm: NSGAII
    internal_population_size: 100
    independent_runs: 3
    problem_names: org.uma.jmetal.problem.multiobjective.zdt.ZDT1,org.uma.jmetal.problem.multiobjective.zdt.ZDT4
    reference_front_file_name: resources/referenceFronts/ZDT1.csv,resources/referenceFronts/ZDT4.csv
    max_number_of_evaluations: 8000,16000

optional_specific_arguments:
    # For Configurable-MOEAD only, probably shouldn't be modified
    weight_vector_files_directory: resources/weightVectors

We comment on these parameters next:

• dashboard_mode: true if the dashboard-based GUI is used; false otherwise.
• output_directory: directory where the output of the meta-optimization is stored. The output include files with the configurations and with the values of the quality indicators.
• cpu_cores: number of cores to be used by the meta-optimizer (ignored if the meta-optimizer cannot be parallelized).
• plotting_frequency: frequency to plot the Pareto front approximation obtained by the meta-optimizer during the search. It must be a multiple of the meta-optimizer population size.
• meta_optimizer_algorithm: most of the multi-objective algorithms in jMetal can be a meta-optimizer, but it is advisable to choose among those that can be run in parallel.
• meta_optimizer_population_size: we typically use a size of 50 in our experiments.
• meta_optimizer_max_evaluations: stopping condition of the meta-optimizer.
• configurable_algorithm: algorithm whose configuration is searched for. Evolver currently provides configurable implementations of NSGA-II, MOEA/D, MOPSO, and SMS-EMOA.
• internal_population_size: population size of the configurable algorithm.
• independent_runs: number of independent runs when evaluating the configurable algorithm with a particular combination of parameters and components.
• problem_names: problems used as the training set.
• reference_front_file_name: files with the reference fronts of the problems in the training set.
• max_number_of_evaluations: stopping condition of the configurable algorithm per problem.
• weight_vector_files_directory: directory containing the weight vector files for MOEA/D.

Using a runner program

The examples package in the Evolver project contains examples illustrating combinations of meta-optimizers and algorithms to be configured.

To run the example where NSGA-II is used to find configurations of MOEAD by selecting the DTZ2Minus problems as the training set, the command to execute is:

$ java -cp target/Evolver-1.0-SNAPSHOT-jar-with-dependencies.jar org.uma.evolver.examples.NSGAIIOptimizingMOEADForProblemDTLZ2Minus

Execute Evolver with a GUI (Optional)

Additionally, you can use Python to deploy a web-based dashboard for executing evolver. To do so, follow the next steps:

# Build the latest version of the Evolver jar at target folder
$ mvn package
# Install the evolver python package
$ pip install "./evolver-dashboard"
# Execute the dashboard
$ python -m evolver

This will start the dashboard at http://localhost:8501/.

For more information in the dashboard, please refer to the dashboard documentation.

Execute with docker

There are two docker images available for Evolver.

Main Evolver

Container image: ghcr.io/jmetal/evolver

Tags: latest

Evolver requires you to include your configuration file and the folder where you want to save the results. The output folder inside the container is the one you define in your execution configuration.

You can do this by mounting volumes in the container.

Usage:

$ docker run --rm \
-v <local/path/config.yml>:/config.yml \
-v <local/path/folder>:<container/path/from/config> \
ghcr.io/jmetal/evolver:latest org.uma.evolver.MetaRunner /config.yml

Evolver dashboard

Check the dashboard documentation for more information.

Configurable algorithms

Evolver includes currently four configurable multi-objective metaheuristics:

• ConfigurableNSGAII
• ConfigurableMOEAD
• ConfigurableMOPSO
• ConfigurableSMSEMOA

These implementations are highly configurable versions of the base algorithms. For example, the design space of the configurable NSGA-II algorithm, in YAML format, is printed by running the YamlNSGAIIParameterDescriptionGenerator program:

algorithmResult:
  type: categorical
  values:
    - population:
    - externalArchive:
        specific_parameter:
          - populationSizeWithArchive:
              type: integer
              values: [10, 200]
          - externalArchive:
              type: categorical
              values:
                - crowdingDistanceArchive:
                - unboundedArchive:
#
createInitialSolutions:
  type: categorical
  values:
    - random:
    - latinHypercubeSampling:
    - scatterSearch:
#
offspringPopulationSize:
  type: categorical
  values: [1, 2, 5, 10, 20, 50, 100, 200, 400]
#
variation:
  type: categorical
  values:
    - crossoverAndMutationVariation:
        specific_parameter:
          - crossover:
              type: categorical
              global_parameters:
                - crossoverProbability:
                    type: real
                    values: [0.0, 1.0]
                - crossoverRepairStrategy:
                    type: categorical
                    values:
                      - random:
                      - round:
                      - bounds:
              values:
                - SBX:
                    specific_parameter:
                      - sbxDistributionIndex:
                          type: real
                          values: [5.0, 400.0]
                - BLX_ALPHA:
                    specific_parameter:
                      - blxAlphaCrossoverAlphaValue:
                          type: real
                          values: [0.0, 1.0]
                - wholeArithmetic:
          - mutation:
              type: categorical
              global_parameters:
                - mutationProbabilityFactor:
                    type: real
                    values: [0.0, 2.0]
                - mutationRepairStrategy:
                    type: categorical
                    values:
                      - random:
                      - round:
                      - bounds:
              values:
                - uniform:
                    specific_parameter:
                      - uniformMutationPerturbation:
                          type: real
                          values: [0.0, 1.0]
                - polynomial:
                    specific_parameter:
                      - polynomialMutationDistributionIndex:
                          type: real
                          values: [5.0, 400.0]
                - linkedPolynomial:
                    specific_parameter:
                      - linkedPolynomialMutationDistributionIndex:
                          type: real
                          values: [5.0, 400.0]
                - nonUniform:
                    specific_parameter:
                      - nonUniformMutationPerturbation:
                          type: real
                          values: [0.0, 1.0]
#
selection:
  type: categorical
  values:
    - tournament:
        specific_parameter:
          - selectionTournamentSize:
              type: integer
              values: [2, 10]
    - random:
#

These algorithms can be configured from a string containing valid combinations of parameters, as shown in the ConfigurableNSGAIIRunner class:

public class ConfigurableNSGAIIRunner {

  public static void main(String[] args) {

    String referenceFrontFileName = "resources/referenceFronts/ZDT1.csv";

    String[] parameters =
        ("--algorithmResult population "
            + "--createInitialSolutions random "
            + "--offspringPopulationSize 100 "
            + "--variation crossoverAndMutationVariation "
            + "--crossover SBX "
            + "--crossoverProbability 0.9 "
            + "--crossoverRepairStrategy round "
            + "--sbxDistributionIndex 20.0 "
            + "--mutation polynomial "
            + "--mutationProbabilityFactor 1.0 "
            + "--mutationRepairStrategy round "
            + "--polynomialMutationDistributionIndex 20.0 "
            + "--selection tournament "
            + "--selectionTournamentSize 2 ")
            .split("\\s+");

    var configurableNSGAII = new ConfigurableNSGAII(new ZDT1(), 100, 20000);
    configurableNSGAII.parse(parameters);
    
    EvolutionaryAlgorithm<DoubleSolution> nsgaII = configurableNSGAII.build();
    nsgaII.run();

    JMetalLogger.logger.info("Total computing time: " + nsgaII.totalComputingTime());

    new SolutionListOutput(nsgaII.result())
        .setVarFileOutputContext(new DefaultFileOutputContext("VAR.csv", ","))
        .setFunFileOutputContext(new DefaultFileOutputContext("FUN.csv", ","))
        .print();
  }
}

Example: Meta-optimizing NSGA-II to solve an engineering problem

To illustrate the use of Evolver, we provide an example where NSGA-II, as meta-optimizer, is used to find a configuration of NSGA-II for the liquid-rocket single element injector design problem described in Engineering applications of multi-objective evolutionary algorithms: A test suite of box-constrained real-world problems. This problem in included in jMetal in the org.uma.jmetal.problem.multiobjective.rwa.Goel2007 class. The code to run this example is in the NSGAIIOptimizingNSGAIIForProblemGoel2007 program in Evolver. Without entering into details, we set the Epsilon and Inverted Generational Distance Plus as indicators to be minimized and the stopping condition of the meta-optimizer and the NSGA-II to be tuned are, respectively, 2000 and 7000 function evaluations.

We execute the program in a terminal by using the following command:

$ java -cp target/Evolver-1.0-jar-with-dependencies.jar org.uma.evolver.examples.NSGAIIOptimizingNSGAIIForProblemGoel2007

The following chart shows the population of the meta-optimizer after 250 evaluations:

We can observe as, at this stage of the optimization, there are four non-dominated solutions.

The following pictures show the population at 1000 and 1900 function evaluations:

Once the run is completed, the output directory contains these two files:

• FUN.NSGA-II.Goel2007.EP.IGD+.2000.csv -> the Pareto front approximation obtained by the meta-optimizer
• VAR.NSGA-II.Goel2007.EP.IGD+.Conf.2000.csv -> the Pareto set approximation (i.e., the configurations found)

The plot of the Pareto front approximation shows that four non-dominated solutions are found:

We select the configuration corresponding to the solution having the minimum inverted generational distance value:

--algorithmResult externalArchive --populationSizeWithArchive 45 --externalArchive unboundedArchive --createInitialSolutions random --offspringPopulationSize 100 --variation crossoverAndMutationVariation --crossover BLX_ALPHA --crossoverProbability 0.6748953752524687 --crossoverRepairStrategy round --sbxDistributionIndex 69.33946841828451 --blxAlphaCrossoverAlphaValue 0.3524179610073535 --mutation nonUniform --mutationProbabilityFactor 1.76602778869229 --mutationRepairStrategy round --polynomialMutationDistributionIndex 20.465825376938277 --linkedPolynomialMutationDistributionIndex 369.76116204526977 --uniformMutationPerturbation 0.9230041512352161 --nonUniformMutationPerturbation 0.6160655898281514 --selection tournament --selectionTournamentSize 8 

The last step is to use this configuration with the ConfigurableNSGAIIRunner:

public class ConfigurableNSGAIIRunner {
    public static void main(String[] args) {
      String referenceFrontFileName = "resources/referenceFronts/Goel2007.csv";

      String[] parameters =
              ("--algorithmResult externalArchive "
                      + "--populationSizeWithArchive 45 "
                      + "--externalArchive unboundedArchive "
                      + "--createInitialSolutions random "
                      + "--offspringPopulationSize 100 "
                      + "--variation crossoverAndMutationVariation "
                      + "--crossover BLX_ALPHA "
                      + "--crossoverProbability 0.6748953752524687 "
                      + "--crossoverRepairStrategy round "
                      + "--sbxDistributionIndex 69.33946841828451 "
                      + "--blxAlphaCrossoverAlphaValue 0.3524179610073535 "
                      + "--mutation nonUniform "
                      + "--mutationProbabilityFactor 1.76602778869229 "
                      + "--mutationRepairStrategy round "
                      + "--polynomialMutationDistributionIndex 20.465825376938277 "
                      + "--linkedPolynomialMutationDistributionIndex 369.76116204526977 "
                      + "--nonUniformMutationPerturbation 0.6160655898281514 "
                      + "--selection tournament "
                      + "--selectionTournamentSize 8 ")
                      .split("\\s+");

      var configurableNSGAII = new ConfigurableNSGAII(new Goel2007(), 100, 15000);
      // Omitted for brevity
  }
}

Note that we set the stopping condition to 15000 function evaluations (7000 were set for the meta-optimization).

We include next the reference front of the problem, the front obtained by the configured NSGA-II and the front obtained by NSGA-II with standard settings: