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source: branches/HeuristicLab.DatasetRefactor/sources/HeuristicLab.Problems.Programmable/3.3/Templates/CompiledSingleObjectiveProblemDefinition.cs @ 12031

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Last change on this file since 12031 was 12001, checked in by mkommend, 10 years ago
#2174: Adapted script template for programmable problem (single-objective).
File size: 3.7 KB

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1	using System;
2	using System.Linq;
3	using System.Collections.Generic;
4	using HeuristicLab.Common;
5	using HeuristicLab.Core;
6	using HeuristicLab.Data;
7	using HeuristicLab.Encodings.BinaryVectorEncoding;
8	using HeuristicLab.Encodings.IntegerVectorEncoding;
9	using HeuristicLab.Encodings.PermutationEncoding;
10	using HeuristicLab.Encodings.RealVectorEncoding;
11	using HeuristicLab.Optimization;
12	using HeuristicLab.Problems.Programmable;
13
14	namespace HeuristicLab.Problems.Programmable {
15	public class CompiledSingleObjectiveProblemDefinition : CompiledProblemDefinition, ISingleObjectiveProblemDefinition {
16	public bool Maximization { get { return false; } }
17
18	public override void Initialize() {
19	// Use vars.yourVariable to access variables in the variable store i.e. yourVariable
20	// Define the solution encoding which can also consist of multiple vectors, examples below
21	//Encoding = new BinaryVectorEncoding("b", length: 5);
22	//Encoding = new IntegerVectorEncoding("i", length: 5, min: 2, max: 14, step: 2);
23	//Encoding = new RealVectorEncoding("r", length: 5, min: -1.0, max: 1.0);
24	//Encoding = new PermutationEncoding("p", length: 5, type: PermutationTypes.Absolute);
25	// The encoding can also be a combination
26	//Encoding = new MultiEncoding()
27	//.Add(new BinaryVectorEncoding("b", length: 5))
28	//.Add(new IntegerVectorEncoding("i", length: 5, min: 2, max: 14, step: 4))
29	//.Add(new RealVectorEncoding("r", length: 5, min: -1.0, max: 1.0))
30	//.Add(new PermutationEncoding("p", length: 5, type: PermutationTypes.Absolute))
31	;
32	// Add additional initialization code e.g. private variables that you need for evaluating
33	}
34
35	public double Evaluate(Individual individual, IRandom random) {
36	// Use vars.yourVariable to access variables in the variable store i.e. yourVariable
37	var quality = 0.0;
38	//quality = individual.RealVector("r").Sum(x => x * x);
39	return quality;
40	}
41
42	public void Analyze(Individual[] individuals, double[] qualities, ResultCollection results, IRandom random) {
43	// Use vars.yourVariable to access variables in the variable store i.e. yourVariable
44	// Write or update results given the range of vectors and resulting qualities
45	// Uncomment the following lines if you want to retrieve the best individual
46
47	//var orderedIndividuals = individuals.Zip(qualities, (i, q) => new { Individual = i, Quality = q }).OrderBy(z => z.Quality);
48	//var best = Maximization ? orderedIndividuals.Last().Individual : orderedIndividuals.First().Individual;
49
50	//if (!results.ContainsKey("Best Solution")) {
51	// results.Add(new Result("Best Solution", typeof(RealVector)));
52	//}
53	//results["Best Solution"].Value = (IItem)best.RealVector("r").Clone();
54	}
55
56	public IEnumerable<Individual> GetNeighbors(Individual individual, IRandom random) {
57	// Use vars.yourVariable to access variables in the variable store i.e. yourVariable
58	// Create new vectors, based on the given one that represent small changes
59	// This method is only called from move-based algorithms (Local Search, Simulated Annealing, etc.)
60	while (true) {
61	// Algorithm will draw only a finite amount of samples
62	// Change to a for-loop to return a concrete amount of neighbors
63	var neighbor = individual.Copy();
64	// For instance, perform a single bit-flip in a binary parameter
65	//var bIndex = random.Next(neighbor.BinaryVector("b").Length);
66	//neighbor.BinaryVector("b")[bIndex] = !neighbor.BinaryVector("b")[bIndex];
67	yield return neighbor;
68	}
69	}
70
71	// Implement further classes and methods
72	}
73	}
74

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