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author | dereeper |
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date | Tue, 08 Jan 2019 08:47:56 -0500 |
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/* Copyright 2010 Stéphane De Mita, Mathieu Siol This file is part of the EggLib library. EggLib 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. EggLib 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 EggLib. If not, see <http://www.gnu.org/licenses/>. */ #ifndef EGGLIB_HFSTATISTICS_HPP #define EGGLIB_HFSTATISTICS_HPP namespace egglib { /** \brief Computes Fst and Fit from haploid data * * The class requires loading data. Data are loaded by haploid * (one genotype per individual). The analyses are cached: they are * performed upon the first call to statistics accessors. The cache * is emptied whenever a datum is loaded. * * The computations are performed after Weir and Cockerham. The * statistic theta is generalized for multiple alleles. To allow * computation of multi-locus statistics, variance components are * also available. The two components of the variance are T1 and T2 * and theta is T1/T2 (from Weir 1996 "Genetic Data Analysis II", * Sinauer associates, Sunderland MA). * * \ingroup polymorphism * */ class HFStatistics { public: /** \brief Constructor * */ HFStatistics(); /** \brief Destructor * */ virtual ~HFStatistics(); /** \brief Reserve sufficient memory for a given number of * individuals. * * This method makes the load function faster by allocating * all required memory at once. * * \param numberOfIndividuals a strictly positive integer. * */ void reserve(unsigned int numberOfIndividuals); /** \brief Loads the data for one individual * * \param genotype an integer giving the allele. * \param populationLabel an integer indication belonging to * a population. * * Genotypes and population labels are not required to be * consecutive (both are labels, not indices). They are * internally mapped to indices (the mapping can be obtained * by accessors populationLabel and allele). * * All genotypes are considered to be valid (no missing data). * If statistics were computed previous to call to this * function, all data will be erased. * */ void loadIndividual(unsigned int genotype, unsigned int populationLabel); /** \brief Label of a population * * The index corresponds to the local mapping of populations * regardless of the ranking of population labels. (No out * of bound checking.) * */ unsigned int populationLabel(unsigned int populationIndex); /** \brief Value of an allele * * The index corresponds to the local mapping of alleles * regardless of the ranking of allele values. (No out of * bound checking.) * */ unsigned int alleleValue(unsigned int alleleIndex); /// Allele of a given individual (no checking) unsigned int allele(unsigned int individualIndex) const; /// Population label of a given individual (no checking) unsigned int individualLabel(unsigned int individualIndex) const; /** \brief Number of alleles * */ unsigned int numberOfAlleles(); /** \brief Number of populations * */ unsigned int numberOfPopulations(); /** \brief Number of loaded genotypes * */ unsigned int numberOfGenotypes() const; /** \brief Absolute total allele frequency * */ unsigned int alleleFrequencyTotal(unsigned int alleleIndex); /** \brief Absolute allele frequency in a population * */ unsigned int alleleFrequencyPerPopulation(unsigned int populationIndex, unsigned int alleleIndex); /** \brief Sample size of a population * */ unsigned int populationFrequency(unsigned int populationIndex); /** \brief Weir-Cockerham theta-statistic * * Note: equivalent to Fst. * */ double theta(); /** \brief Between-population component of variance * */ double T1(); /** \brief Total variance * */ double T2(); protected: bool d_flag; void d_init(); void d_clear(); unsigned int d_reserved; unsigned int d_numberOfGenotypes; unsigned int *d_genotypes; unsigned int *d_populationLabels; bool s_flag; void s_init(); void s_clear(); void s_compute(); void processPopulations(); void processAlleles(); unsigned int getPopulationIndex(unsigned int) const; unsigned int getAlleleIndex(unsigned int) const; unsigned int s_numberOfAlleles; unsigned int *s_alleleValueMapping; unsigned int s_numberOfPopulations; unsigned int *s_populationLabelMapping; unsigned int *s_populationFrequencies; unsigned int *s_alleleFrequenciesTotal; unsigned int **s_alleleFrequenciesPerPopulation; bool w_flag; void w_init(); void w_clear(); void w_compute(); double w_T; double *w_T1; double *w_T2; double w_nbar; double w_nc; double *w_pbar; double *w_ssquare; double w_sum_T1; double w_sum_T2; private: HFStatistics(const HFStatistics& source) { } HFStatistics& operator=(const HFStatistics& source) { return *this; } }; } #endif