/* This file is part of solidity. solidity is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. solidity is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with solidity. If not, see . */ #include #include #include #include #include #include using namespace std; namespace solidity::phaser::test { BOOST_AUTO_TEST_SUITE(Phaser) BOOST_AUTO_TEST_SUITE(MutationsTest) BOOST_AUTO_TEST_SUITE(GeneRandomisationTest) BOOST_AUTO_TEST_CASE(geneRandomisation_should_iterate_over_genes_and_replace_them_with_random_ones_with_given_probability) { Chromosome chromosome("fcCUnDvejs"); function mutation01 = geneRandomisation(0.1); function mutation05 = geneRandomisation(0.5); function mutation10 = geneRandomisation(1.0); SimulationRNG::reset(1); BOOST_TEST(countDifferences(mutation01(chromosome), chromosome), 2); BOOST_TEST(countDifferences(mutation05(chromosome), chromosome), 5); BOOST_TEST(countDifferences(mutation10(chromosome), chromosome), 7); SimulationRNG::reset(2); BOOST_TEST(countDifferences(mutation01(chromosome), chromosome), 1); BOOST_TEST(countDifferences(mutation05(chromosome), chromosome), 3); BOOST_TEST(countDifferences(mutation10(chromosome), chromosome), 9); } BOOST_AUTO_TEST_CASE(geneRandomisation_should_return_identical_chromosome_if_probability_is_zero) { Chromosome chromosome("fcCUnDvejsrmV"); function mutation = geneRandomisation(0.0); BOOST_TEST(mutation(chromosome) == chromosome); } BOOST_AUTO_TEST_CASE(geneDeletion_should_iterate_over_genes_and_delete_them_with_given_probability) { Chromosome chromosome("fcCUnDvejs"); function mutation01 = geneDeletion(0.1); function mutation05 = geneDeletion(0.5); SimulationRNG::reset(1); // fcCUnDvejs BOOST_TEST(mutation01(chromosome) == Chromosome(stripWhitespace("fcCU Dvejs"))); BOOST_TEST(mutation05(chromosome) == Chromosome(stripWhitespace(" D ejs"))); SimulationRNG::reset(2); BOOST_TEST(mutation01(chromosome) == Chromosome(stripWhitespace("fcUnDvejs"))); BOOST_TEST(mutation05(chromosome) == Chromosome(stripWhitespace(" Un s"))); } BOOST_AUTO_TEST_CASE(geneDeletion_should_return_identical_chromosome_if_probability_is_zero) { Chromosome chromosome("fcCUnDvejsrmV"); function mutation = geneDeletion(0.0); BOOST_TEST(mutation(chromosome) == chromosome); } BOOST_AUTO_TEST_CASE(geneDeletion_should_delete_all_genes_if_probability_is_one) { Chromosome chromosome("fcCUnDvejsrmV"); function mutation = geneDeletion(1.0); BOOST_TEST(mutation(chromosome) == Chromosome("")); } BOOST_AUTO_TEST_CASE(geneAddition_should_iterate_over_gene_positions_and_insert_new_genes_with_given_probability) { Chromosome chromosome("fcCUnDvejs"); function mutation01 = geneAddition(0.1); function mutation05 = geneAddition(0.5); SimulationRNG::reset(1); // f c C U n D v e j s BOOST_TEST(mutation01(chromosome) == Chromosome(stripWhitespace(" f c C UC n D v e jx s"))); // 20% more BOOST_TEST(mutation05(chromosome) == Chromosome(stripWhitespace("j f cu C U ne D v eI j sf"))); // 50% more SimulationRNG::reset(2); BOOST_TEST(mutation01(chromosome) == Chromosome(stripWhitespace(" f cu C U n D v e j s"))); // 10% more BOOST_TEST(mutation05(chromosome) == Chromosome(stripWhitespace("L f ce Cv U n D v e jO s"))); // 40% more } BOOST_AUTO_TEST_CASE(geneAddition_should_be_able_to_insert_before_first_position) { SimulationRNG::reset(7); Chromosome chromosome("fcCUnDvejs"); function mutation = geneAddition(0.1); Chromosome mutatedChromosome = mutation(chromosome); BOOST_TEST(mutatedChromosome.length() > chromosome.length()); vector suffix( mutatedChromosome.optimisationSteps().end() - chromosome.length(), mutatedChromosome.optimisationSteps().end() ); BOOST_TEST(suffix == chromosome.optimisationSteps()); } BOOST_AUTO_TEST_CASE(geneAddition_should_be_able_to_insert_after_last_position) { SimulationRNG::reset(81); Chromosome chromosome("fcCUnDvejs"); function mutation = geneAddition(0.1); Chromosome mutatedChromosome = mutation(chromosome); BOOST_TEST(mutatedChromosome.length() > chromosome.length()); vector prefix( mutatedChromosome.optimisationSteps().begin(), mutatedChromosome.optimisationSteps().begin() + chromosome.length() ); BOOST_TEST(prefix == chromosome.optimisationSteps()); } BOOST_AUTO_TEST_CASE(geneAddition_should_return_identical_chromosome_if_probability_is_zero) { Chromosome chromosome("fcCUnDvejsrmV"); function mutation = geneAddition(0.0); BOOST_TEST(mutation(chromosome) == chromosome); } BOOST_AUTO_TEST_CASE(geneAddition_should_insert_genes_at_all_positions_if_probability_is_one) { Chromosome chromosome("fcCUnDvejsrmV"); function mutation = geneAddition(1.0); Chromosome mutatedChromosome = mutation(chromosome); BOOST_TEST(mutatedChromosome.length() == chromosome.length() * 2 + 1); vector originalGenes; for (size_t i = 0; i < mutatedChromosome.length() - 1; ++i) if (i % 2 == 1) originalGenes.push_back(mutatedChromosome.optimisationSteps()[i]); BOOST_TEST(Chromosome(originalGenes) == chromosome); } BOOST_AUTO_TEST_CASE(alternativeMutations_should_choose_between_mutations_with_given_probability) { SimulationRNG::reset(1); Chromosome chromosome("a"); function mutation = alternativeMutations( 0.8, wholeChromosomeReplacement(Chromosome("c")), wholeChromosomeReplacement(Chromosome("f")) ); size_t cCount = 0; size_t fCount = 0; for (size_t i = 0; i < 10; ++i) { Chromosome mutatedChromosome = mutation(chromosome); cCount += static_cast(mutatedChromosome == Chromosome("c")); fCount += static_cast(mutatedChromosome == Chromosome("f")); } // This particular seed results in 7 "c"s out of 10 which looks plausible given the 80% chance. BOOST_TEST(cCount == 7); BOOST_TEST(fCount == 3); } BOOST_AUTO_TEST_CASE(alternativeMutations_should_always_choose_first_mutation_if_probability_is_one) { Chromosome chromosome("a"); function mutation = alternativeMutations( 1.0, wholeChromosomeReplacement(Chromosome("c")), wholeChromosomeReplacement(Chromosome("f")) ); for (size_t i = 0; i < 10; ++i) BOOST_TEST(mutation(chromosome) == Chromosome("c")); } BOOST_AUTO_TEST_CASE(alternativeMutations_should_always_choose_second_mutation_if_probability_is_zero) { Chromosome chromosome("a"); function mutation = alternativeMutations( 0.0, wholeChromosomeReplacement(Chromosome("c")), wholeChromosomeReplacement(Chromosome("f")) ); for (size_t i = 0; i < 10; ++i) BOOST_TEST(mutation(chromosome) == Chromosome("f")); } BOOST_AUTO_TEST_CASE(randomPointCrossover_should_swap_chromosome_parts_at_random_point) { function crossover = randomPointCrossover(); SimulationRNG::reset(1); Chromosome result1 = crossover(Chromosome("aaaaaaaaaa"), Chromosome("cccccc")); BOOST_TEST(result1 == Chromosome("aaaccc")); SimulationRNG::reset(1); Chromosome result2 = crossover(Chromosome("cccccc"), Chromosome("aaaaaaaaaa")); BOOST_TEST(result2 == Chromosome("cccaaaaaaa")); } BOOST_AUTO_TEST_CASE(randomPointCrossover_should_only_consider_points_available_on_both_chromosomes) { SimulationRNG::reset(1); function crossover = randomPointCrossover(); for (size_t i = 0; i < 30; ++i) { Chromosome result1 = crossover(Chromosome("aaa"), Chromosome("TTTTTTTTTTTTTTTTTTTT")); Chromosome result2 = crossover(Chromosome("TTTTTTTTTTTTTTTTTTTT"), Chromosome("aaa")); BOOST_TEST(( result1 == Chromosome("TTTTTTTTTTTTTTTTTTTT") || result1 == Chromosome("aTTTTTTTTTTTTTTTTTTT") || result1 == Chromosome("aaTTTTTTTTTTTTTTTTTT") || result1 == Chromosome("aaaTTTTTTTTTTTTTTTTT") )); BOOST_TEST(( result2 == Chromosome("aaa") || result2 == Chromosome("Taa") || result2 == Chromosome("TTa") || result2 == Chromosome("TTT") )); } } BOOST_AUTO_TEST_CASE(randomPointCrossover_should_never_split_at_position_zero_if_chromosomes_are_splittable) { SimulationRNG::reset(1); function crossover = randomPointCrossover(); for (size_t i = 0; i < 30; ++i) { Chromosome result1 = crossover(Chromosome("aa"), Chromosome("TTTTTTTTTTTTTTTTTTTT")); Chromosome result2 = crossover(Chromosome("TTTTTTTTTTTTTTTTTTTT"), Chromosome("aa")); BOOST_TEST(result1 != Chromosome("TTTTTTTTTTTTTTTTTTTT")); BOOST_TEST(result2 != Chromosome("aa")); } } BOOST_AUTO_TEST_CASE(randomPointCrossover_should_never_split_at_position_zero_if_chromosomes_are_not_empty) { SimulationRNG::reset(1); function crossover = randomPointCrossover(); for (size_t i = 0; i < 30; ++i) { Chromosome result1 = crossover(Chromosome("a"), Chromosome("T")); Chromosome result2 = crossover(Chromosome("T"), Chromosome("a")); BOOST_TEST(result1 == Chromosome("a")); BOOST_TEST(result2 == Chromosome("T")); } } BOOST_AUTO_TEST_CASE(randomPointCrossover_should_work_even_if_one_chromosome_is_unsplittable) { function crossover = randomPointCrossover(); SimulationRNG::reset(1); BOOST_CHECK(crossover(Chromosome("ff"), Chromosome("a")) == Chromosome("f")); BOOST_CHECK(crossover(Chromosome("a"), Chromosome("ff")) == Chromosome("af")); } BOOST_AUTO_TEST_CASE(randomPointCrossover_should_split_at_position_zero_only_if_at_least_one_chromosome_is_empty) { Chromosome empty(""); Chromosome unsplittable("a"); Chromosome splittable("aaaa"); function crossover = randomPointCrossover(); SimulationRNG::reset(1); BOOST_CHECK(crossover(empty, empty) == empty); BOOST_CHECK(crossover(unsplittable, empty) == empty); BOOST_CHECK(crossover(empty, unsplittable) == unsplittable); BOOST_CHECK(crossover(splittable, empty) == empty); BOOST_CHECK(crossover(empty, splittable) == splittable); } BOOST_AUTO_TEST_CASE(fixedPointCrossover_should_swap_chromosome_parts_at_given_point) { Chromosome result1 = fixedPointCrossover(0.8)(Chromosome("aaaaaaaaaa"), Chromosome("cccccccccc")); Chromosome result2 = fixedPointCrossover(0.8)(Chromosome("cccccccccc"), Chromosome("aaaaaaaaaa")); BOOST_TEST(result1 == Chromosome("aaaaaaaacc")); BOOST_TEST(result2 == Chromosome("ccccccccaa")); } BOOST_AUTO_TEST_CASE(fixedPointCrossover_should_determine_crossover_point_based_on_length_of_shorter_chromosome) { Chromosome result1 = fixedPointCrossover(0.4)(Chromosome("aaaaa"), Chromosome("cccccccccc")); Chromosome result2 = fixedPointCrossover(0.4)(Chromosome("cccccccccc"), Chromosome("aaaaa")); BOOST_TEST(result1 == Chromosome("aacccccccc")); BOOST_TEST(result2 == Chromosome("ccaaa")); } BOOST_AUTO_TEST_CASE(fixedPointCrossover_should_round_split_point) { Chromosome result1 = fixedPointCrossover(0.49)(Chromosome("aaaaa"), Chromosome("ccccc")); Chromosome result2 = fixedPointCrossover(0.49)(Chromosome("ccccc"), Chromosome("aaaaa")); BOOST_TEST(result1 == Chromosome("aaccc")); BOOST_TEST(result2 == Chromosome("ccaaa")); Chromosome result3 = fixedPointCrossover(0.50)(Chromosome("aaaaa"), Chromosome("ccccc")); Chromosome result4 = fixedPointCrossover(0.50)(Chromosome("ccccc"), Chromosome("aaaaa")); BOOST_TEST(result3 == Chromosome("aaacc")); BOOST_TEST(result4 == Chromosome("cccaa")); Chromosome result5 = fixedPointCrossover(0.51)(Chromosome("aaaaa"), Chromosome("ccccc")); Chromosome result6 = fixedPointCrossover(0.51)(Chromosome("ccccc"), Chromosome("aaaaa")); BOOST_TEST(result5 == Chromosome("aaacc")); BOOST_TEST(result6 == Chromosome("cccaa")); } BOOST_AUTO_TEST_CASE(fixedPointCrossover_should_split_at_position_zero_if_explicitly_requested) { Chromosome result1 = fixedPointCrossover(0.0)(Chromosome("aaaaa"), Chromosome("cccccccccc")); Chromosome result2 = fixedPointCrossover(0.0)(Chromosome("cccccccccc"), Chromosome("aaaaa")); BOOST_TEST(result1 == Chromosome("cccccccccc")); BOOST_TEST(result2 == Chromosome("aaaaa")); } BOOST_AUTO_TEST_CASE(fixedPointCrossover_should_split_at_end_of_shorter_chromosome_if_crossover_point_is_after_last_position) { Chromosome result1 = fixedPointCrossover(1.0)(Chromosome("aaaaa"), Chromosome("cccccccccc")); Chromosome result2 = fixedPointCrossover(1.0)(Chromosome("cccccccccc"), Chromosome("aaaaa")); BOOST_TEST(result1 == Chromosome("aaaaaccccc")); BOOST_TEST(result2 == Chromosome("ccccc")); } BOOST_AUTO_TEST_CASE(fixedPointCrossover_should_select_correct_split_point_for_unsplittable_chromosomes) { function crossover00 = fixedPointCrossover(0.0); BOOST_CHECK(crossover00(Chromosome("fff"), Chromosome("a")) == Chromosome("a")); BOOST_CHECK(crossover00(Chromosome("a"), Chromosome("fff")) == Chromosome("fff")); BOOST_CHECK(crossover00(Chromosome("f"), Chromosome("a")) == Chromosome("a")); function crossover10 = fixedPointCrossover(1.0); BOOST_CHECK(crossover10(Chromosome("fff"), Chromosome("a")) == Chromosome("f")); BOOST_CHECK(crossover10(Chromosome("a"), Chromosome("fff")) == Chromosome("aff")); BOOST_CHECK(crossover10(Chromosome("f"), Chromosome("a")) == Chromosome("f")); } BOOST_AUTO_TEST_CASE(fixedPointCrossover_should_always_use_position_zero_as_split_point_when_chromosome_empty) { Chromosome empty(""); Chromosome unsplittable("f"); Chromosome splittable("aaaa"); function crossover00 = fixedPointCrossover(0.0); BOOST_CHECK(crossover00(empty, empty) == empty); BOOST_CHECK(crossover00(unsplittable, empty) == empty); BOOST_CHECK(crossover00(empty, unsplittable) == unsplittable); BOOST_CHECK(crossover00(splittable, empty) == empty); BOOST_CHECK(crossover00(empty, splittable) == splittable); function crossover10 = fixedPointCrossover(1.0); BOOST_CHECK(crossover10(empty, empty) == empty); BOOST_CHECK(crossover10(unsplittable, empty) == empty); BOOST_CHECK(crossover10(empty, unsplittable) == unsplittable); BOOST_CHECK(crossover10(splittable, empty) == empty); BOOST_CHECK(crossover10(empty, splittable) == splittable); } BOOST_AUTO_TEST_SUITE_END() BOOST_AUTO_TEST_SUITE_END() BOOST_AUTO_TEST_SUITE_END() }