/** * \file Distribution.h \brief computes distribution functions * * Distribution - base distance distribution class * RadialDistributionFunction required for calculation of SAXS profile * DeltaDistributionFunction requires for chi-square derivatives * * Copyright 2007-2010 IMP Inventors. All rights reserved. * */ #ifndef IMPSAXS_DISTRIBUTION_H #define IMPSAXS_DISTRIBUTION_H #include "saxs_config.h" #include "Profile.h" #include #include #include IMPSAXS_BEGIN_NAMESPACE namespace { // anonymous static const Float pr_resolution = 0.5; } /** base class for distribution classes */ template class Distribution : public std::vector< ValueT > { public: //! Constructor Distribution(Float bin_size = pr_resolution) { init(bin_size); } //! returns maximal distance value of distribution Float get_max_distance() { return max_distance_; } //! returns bin size Float get_bin_size() { return bin_size_; } protected: void init(Float bin_size) { // clear(); bin_size_ = bin_size; one_over_bin_size_ = 1.0/bin_size_; // for faster calculation max_distance_ = 50.0; // start with ~50A (by default) reserve(dist2index(max_distance_) + 1); } unsigned int dist2index(Float dist) const { return algebra::get_rounded( dist * one_over_bin_size_ ); } Float index2dist(unsigned int index) const { return index * bin_size_; } protected: Float bin_size_, one_over_bin_size_; // resolution of discretization Float max_distance_; // parameter for maximum r value for p(r) function }; #ifdef SWIG %template(FloatDistribution) Distribution; %template(VectorDistribution) Distribution; #endif /** Radial Distribution class for calculating SAXS Profile this is distance distribution multiplied by form factors of atoms */ class IMPSAXSEXPORT RadialDistributionFunction : public Distribution { public: //! Constructor (default) RadialDistributionFunction(Float bin_size = pr_resolution); //! Constructor from gnom file RadialDistributionFunction(const std::string& file_name); friend class Profile; //! scale distribution by a constant void scale(Float c); //! add another distribution void add(const RadialDistributionFunction& model_pr); //! print tables void show(std::ostream &out=std::cout, std::string prefix="") const; //! analogy crystallographic R-factor score Float R_factor_score(const RadialDistributionFunction& model_pr, const std::string& file_name = "") const; // //! analogy to chi score \untested{chi_score} // Float chi_score(const RadialDistributionFunction& model_pr) const; //! fit the distributions by scaling according to maximum Float fit(const RadialDistributionFunction& model_pr, const std::string& file_name = "") const; //! normalize to area = 1.0 void normalize(); private: void add_to_distribution(Float dist, Float value) { unsigned int index = dist2index(dist); if(index >= size()) { if(capacity() <= index) reserve(2 * index); // to avoid many re-allocations resize(index + 1, 0); max_distance_ = index2dist(index + 1); } (*this)[index] += value; } //! read gnom file void read_pr_file(const std::string& file_name); //! write fit file for the two distributions void write_fit_file(const RadialDistributionFunction& model_pr, Float c = 1.0, const std::string& file_name = "") const; }; /** Delta Distribution class for calculating the derivatives of SAXS Score this distribution is: sum_i [f_p(0) * f_i(0) * (x_p - x_i)] sum_i [f_p(0) * f_i(0) * (y_p - y_i)] sum_i [f_p(0) * f_i(0) * (z_p - z_i)] */ class IMPSAXSEXPORT DeltaDistributionFunction : public Distribution { public: //! Constructor DeltaDistributionFunction(const Particles& particles, Float max_distance = 0.0, Float bin_size = pr_resolution); friend class Score; //! calculates distribution for an atom defined by particle void calculate_derivative_distribution(Particle* particle); //! print tables void show(std::ostream &out=std::cout, std::string prefix="") const; private: void add_to_distribution(Float dist, const algebra::Vector3D& value) { unsigned int index = dist2index(dist); if(index >= size()) { if(capacity() <= index) reserve(2 * index); // to avoid many re-allocations resize(index + 1, algebra::Vector3D(0.0, 0.0, 0.0)); max_distance_ = index2dist(index + 1); } (*this)[index] += value; } void init() { clear(); insert(begin(), dist2index(max_distance_) + 1, algebra::Vector3D(0.0, 0.0, 0.0)); } protected: std::vector coordinates_; Floats form_factors_; }; IMPSAXS_END_NAMESPACE #endif /* IMPSAXS_DISTRIBUTION_H */