/* 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 . */ // SPDX-License-Identifier: GPL-3.0 /** * Miscellaneous utilities for use in yul-phaser's test cases. * * - Generic code that's only used in these particular tests. * - Convenience functions and wrappers to make tests more concise. * - Mocks and dummy objects/functions used in multiple test suites. * * Note that the code included here may be not as generic, robust and/or complete as it could be * since it's not meant for production use. If some utility seems useful enough to be moved to * the normal code base, you should review its implementation before doing so. */ #pragma once #include #include #include #include #include #include #include #include #include #include #include // OPERATORS FOR BOOST::TEST /// Output operator for arbitrary two-element tuples. /// Necessary to make BOOST_TEST() work with such tuples. template std::ostream& operator<<(std::ostream& _output, std::tuple const& _tuple) { _output << "(" << std::get<0>(_tuple) << ", " << std::get<1>(_tuple) << ")"; return _output; } namespace boost::test_tools::tt_detail { // Boost won't find the << operator unless we put it in the std namespace which is illegal. // The recommended solution is to overload print_log_value<> struct and make it use our global operator. template struct print_log_value> { void operator()(std::ostream& _output, std::tuple const& _tuple) { ::operator<<(_output, _tuple); } }; } namespace solidity::phaser::test { /** * Fitness metric that only takes into account the number of optimisation steps in the chromosome. * Recommended for use in tests because it's much faster than ProgramSize metric and it's very * easy to guess the result at a glance. */ class ChromosomeLengthMetric: public FitnessMetric { public: using FitnessMetric::FitnessMetric; size_t evaluate(Chromosome const& _chromosome) override { return _chromosome.length(); } }; // MUTATIONS /// Mutation that always replaces the whole chromosome with the one specified in the parameter. std::function wholeChromosomeReplacement(Chromosome _newChromosome); /// Mutation that always replaces the optimisation step at position @a _geneIndex with @a _geneValue. /// /// The chromosome must be long enough for this position to exist. std::function geneSubstitution(size_t _geneIndex, std::string _geneValue); // CHROMOSOME AND POPULATION HELPERS /// Returns a vector containing lengths of all chromosomes in the population (in the same order). std::vector chromosomeLengths(Population const& _population); /// Returns the number of genes that differ between two chromosomes. /// If the chromnosomes have different lengths, the positions that are present in only one of them /// are counted as mismatches. size_t countDifferences(Chromosome const& _chromosome1, Chromosome const& _chromosome2); /// Assigns indices from 0 to N to all optimisation steps available in the OptimiserSuite. /// This is a convenience helper to make it easier to test their distribution with tools made for /// integers. std::map enumerateOptmisationSteps(); // STRING UTILITIES /// Returns the input string with all the whitespace characters (spaces, line endings, etc.) removed. std::string stripWhitespace(std::string const& input); /// Counts the number of times one strinng can be found inside another. Only non-overlapping /// occurrences are counted. size_t countSubstringOccurrences(std::string const& _inputString, std::string const& _substring); // STATISTICAL UTILITIES /// Calculates the mean value of a series of samples given in a vector. /// /// Supports any integer and real type as a convenience but the precision of the result is limited /// to the precision of type @a double as all the values are internally converted to it. /// /// This is a very simple, naive implementation that's more than enough for tests where we usually /// deal with relatively short sequences of small, positive integers. It's not numerically stable /// in more complicated cases. Don't use in production. template double mean(std::vector const& _samples) { assert(_samples.size() > 0); double sum = 0; for (T const& sample: _samples) sum += double(sample); return sum / double(_samples.size()); } /// Calculates the sum of squared differences between @a _expectedValue and the values of a series /// of samples given in a vector. /// /// Supports any integer and real type as a convenience but the precision of the result is limited /// to the precision of type @a double as all the values are internally converted to it. /// /// This is a very simple, naive implementation that's more than enough for tests where we usually /// deal with relatively short sequences of small, positive integers. It's not numerically stable /// in more complicated cases. Don't use in production. template double meanSquaredError(std::vector const& _samples, double _expectedValue) { assert(_samples.size() > 0); double sumOfSquaredDifferences = 0; for (T const& sample: _samples) sumOfSquaredDifferences += (double(sample) - _expectedValue) * (double(sample) - _expectedValue); return sumOfSquaredDifferences / double(_samples.size()); } }