From 55c7181126aa7defce38c9b82872d14223d4c1dd Mon Sep 17 00:00:00 2001 From: Gard Spreemann Date: Tue, 7 Feb 2017 17:33:01 +0100 Subject: Initial import of upstream's 1.3.1. --- include/gudhi/Bitmap_cubical_complex_base.h | 817 ++++++++++++++++++++++++++++ 1 file changed, 817 insertions(+) create mode 100644 include/gudhi/Bitmap_cubical_complex_base.h (limited to 'include/gudhi/Bitmap_cubical_complex_base.h') diff --git a/include/gudhi/Bitmap_cubical_complex_base.h b/include/gudhi/Bitmap_cubical_complex_base.h new file mode 100644 index 00000000..0442ac34 --- /dev/null +++ b/include/gudhi/Bitmap_cubical_complex_base.h @@ -0,0 +1,817 @@ +/* This file is part of the Gudhi Library. The Gudhi library + * (Geometric Understanding in Higher Dimensions) is a generic C++ + * library for computational topology. + * + * Author(s): Pawel Dlotko + * + * Copyright (C) 2015 INRIA Sophia-Saclay (France) + * + * This program 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. + * + * This program 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 this program. If not, see . + */ + +#ifndef BITMAP_CUBICAL_COMPLEX_BASE_H_ +#define BITMAP_CUBICAL_COMPLEX_BASE_H_ + +#include + +#include +#include +#include +#include +#include +#include +#include +#include // for pair<> + +namespace Gudhi { + +namespace cubical_complex { + +/** + * @brief Cubical complex represented as a bitmap, class with basic implementation. + * @ingroup cubical_complex + * @details This is a class implementing a basic bitmap data structure to store cubical complexes. + * It implements only the most basic subroutines. + * The idea of the bitmap is the following. Our aim is to have a memory efficient + * data structure to store d-dimensional cubical complex + * C being a cubical decomposition + * of a rectangular region of a space. This is achieved by storing C as a + * vector of bits (this is where the name 'bitmap' came from). + * Each cell is represented by a single + * bit (in case of black and white bitmaps, or by a single element of a type T + * (here T is a filtration type of a bitmap, typically a double). + * All the informations needed for homology and + * persistent homology computations (like dimension of a cell, boundary and + * coboundary elements of a cell, are then obtained from the + * position of the element in C. + * The default filtration used in this implementation is the lower star filtration. + */ +template +class Bitmap_cubical_complex_base { + public: + typedef T filtration_type; + + /** + *Default constructor + **/ + Bitmap_cubical_complex_base() : + total_number_of_cells(0) { } + /** + * There are a few constructors of a Bitmap_cubical_complex_base class. + * First one, that takes vector, creates an empty bitmap of a dimension equal + * the number of elements in the + * input vector and size in the i-th dimension equal the number in the position i-of the input vector. + */ + Bitmap_cubical_complex_base(const std::vector& sizes); + /** + * The second constructor takes as a input a Perseus style file. For more details, + * please consult the documentations of + * Perseus software as well as examples attached to this + * implementation. + **/ + Bitmap_cubical_complex_base(const char* perseus_style_file); + /** + * The last constructor of a Bitmap_cubical_complex_base class accepts vector of dimensions (as the first one) + * together with vector of filtration values of top dimensional cells. + **/ + Bitmap_cubical_complex_base(const std::vector& dimensions, const std::vector& top_dimensional_cells); + + /** + * Destructor of the Bitmap_cubical_complex_base class. + **/ + virtual ~Bitmap_cubical_complex_base() { } + + /** + * The functions get_boundary_of_a_cell, get_coboundary_of_a_cell, get_dimension_of_a_cell + * and get_cell_data are the basic + * functions that compute boundary / coboundary / dimension and the filtration + * value form a position of a cell in the structure of a bitmap. The input parameter of all of those function is a + * non-negative integer, indicating a position of a cube in the data structure. + * In the case of functions that compute (co)boundary, the output is a vector if non-negative integers pointing to + * the positions of (co)boundary element of the input cell. + */ + virtual inline std::vector< size_t > get_boundary_of_a_cell(size_t cell)const; + /** + * The functions get_coboundary_of_a_cell, get_coboundary_of_a_cell, + * get_dimension_of_a_cell and get_cell_data are the basic + * functions that compute boundary / coboundary / dimension and the filtration + * value form a position of a cell in the structure of a bitmap. + * The input parameter of all of those function is a non-negative integer, + * indicating a position of a cube in the data structure. + * In the case of functions that compute (co)boundary, the output is a vector if + * non-negative integers pointing to the + * positions of (co)boundary element of the input cell. + **/ + virtual inline std::vector< size_t > get_coboundary_of_a_cell(size_t cell)const; + /** + * In the case of get_dimension_of_a_cell function, the output is a non-negative integer + * indicating the dimension of a cell. + **/ + inline unsigned get_dimension_of_a_cell(size_t cell)const; + /** + * In the case of get_cell_data, the output parameter is a reference to the value of a cube in a given position. + * This allows reading and changing the value of filtration. Note that if the value of a filtration is changed, the + * code do not check if we have a filtration or not. i.e. it do not check if the value of a filtration of a cell is + * not smaller than the value of a filtration of its boundary and not greater than the value of its coboundary. + **/ + inline T& get_cell_data(size_t cell); + + + /** + * Typical input used to construct a baseBitmap class is a filtration given at the top dimensional cells. + * Then, there are a few ways one can pick the filtration of lower dimensional + * cells. The most typical one is by so called lower star filtration. This function is always called by any + * constructor which takes the top dimensional cells. If you use such a constructor, + * then there is no need to call this function. Call it only if you are putting the filtration + * of the cells by your own (for instance by using Top_dimensional_cells_iterator). + **/ + void impose_lower_star_filtration(); // assume that top dimensional cells are already set. + + /** + * Returns dimension of a complex. + **/ + inline unsigned dimension()const { + return sizes.size(); + } + + /** + * Returns number of all cubes in the data structure. + **/ + inline unsigned size()const { + return this->data.size(); + } + + /** + * Writing to stream operator. By using it we get the values T of cells in order in which they are stored in the + * structure. This procedure is used for debugging purposes. + **/ + template + friend std::ostream& operator<<(std::ostream & os, const Bitmap_cubical_complex_base& b); + + /** + * Function that put the input data to bins. By putting data to bins we mean rounding them to a sequence of values + * equally distributed in the range of data. + * Sometimes if most of the cells have different birth-death times, the performance of the algorithms to compute + * persistence gets worst. When dealing with this type of data, one may want to put different values on cells to + * some number of bins. The function put_data_to_bins( size_t number_of_bins ) is designed for that purpose. + * The parameter of the function is the number of bins (distinct values) we want to have in the cubical complex. + **/ + void put_data_to_bins(size_t number_of_bins); + + /** + * Function that put the input data to bins. By putting data to bins we mean rounding them to a sequence of values + * equally distributed in the range of data. + * Sometimes if most of the cells have different birth-death times, the performance of the algorithms to compute + * persistence gets worst. When dealing with this type of data, one may want to put different values on cells to + * some number of bins. The function put_data_to_bins( T diameter_of_bin ) is designed for that purpose. + * The parameter of it is the diameter of each bin. Note that the bottleneck distance between the persistence + * diagram of the cubical complex before and after using such a function will be bounded by the parameter + * diameter_of_bin. + **/ + void put_data_to_bins(T diameter_of_bin); + + /** + * Functions to find min and max values of filtration. + **/ + std::pair< T, T > min_max_filtration(); + + // ITERATORS + + /** + * @brief Iterator through all cells in the complex (in order they appear in the structure -- i.e. + * in lexicographical order). + **/ + class All_cells_iterator : std::iterator< std::input_iterator_tag, T > { + public: + All_cells_iterator() { + this->counter = 0; + } + + All_cells_iterator operator++() { + // first find first element of the counter that can be increased: + ++this->counter; + return *this; + } + + All_cells_iterator operator++(int) { + All_cells_iterator result = *this; + ++(*this); + return result; + } + + All_cells_iterator& operator=(const All_cells_iterator& rhs) { + this->counter = rhs.counter; + return *this; + } + + bool operator==(const All_cells_iterator& rhs)const { + if (this->counter != rhs.counter)return false; + return true; + } + + bool operator!=(const All_cells_iterator& rhs)const { + return !(*this == rhs); + } + + /* + * The operator * returns position of a cube in the structure of cubical complex. This position can be then used as + * an argument of the following functions: + * get_boundary_of_a_cell, get_coboundary_of_a_cell, get_dimension_of_a_cell to get information about the cell + * boundary and coboundary and dimension + * and in function get_cell_data to get a filtration of a cell. + */ + size_t operator*() { + return this->counter; + } + friend class Bitmap_cubical_complex_base; + protected: + size_t counter; + }; + + /** + * Function returning a All_cells_iterator to the first cell of the bitmap. + **/ + All_cells_iterator all_cells_iterator_begin() { + All_cells_iterator a; + return a; + } + + /** + * Function returning a All_cells_iterator to the last cell of the bitmap. + **/ + All_cells_iterator all_cells_iterator_end() { + All_cells_iterator a; + a.counter = this->data.size(); + return a; + } + + /** + * @brief All_cells_range class provides ranges for All_cells_iterator + **/ + class All_cells_range { + public: + All_cells_range(Bitmap_cubical_complex_base* b) : b(b) { } + + All_cells_iterator begin() { + return b->all_cells_iterator_begin(); + } + + All_cells_iterator end() { + return b->all_cells_iterator_end(); + } + private: + Bitmap_cubical_complex_base* b; + }; + + All_cells_range all_cells_range() { + return All_cells_range(this); + } + + + /** + * Boundary_range class provides ranges for boundary iterators. + **/ + typedef typename std::vector< size_t >::const_iterator Boundary_iterator; + typedef typename std::vector< size_t > Boundary_range; + + /** + * boundary_simplex_range creates an object of a Boundary_simplex_range class + * that provides ranges for the Boundary_simplex_iterator. + **/ + Boundary_range boundary_range(size_t sh) { + return this->get_boundary_of_a_cell(sh); + } + + /** + * Coboundary_range class provides ranges for boundary iterators. + **/ + typedef typename std::vector< size_t >::const_iterator Coboundary_iterator; + typedef typename std::vector< size_t > Coboundary_range; + + /** + * boundary_simplex_range creates an object of a Boundary_simplex_range class + * that provides ranges for the Boundary_simplex_iterator. + **/ + Coboundary_range coboundary_range(size_t sh) { + return this->get_coboundary_of_a_cell(sh); + } + + /** + * @brief Iterator through top dimensional cells of the complex. The cells appear in order they are stored + * in the structure (i.e. in lexicographical order) + **/ + class Top_dimensional_cells_iterator : std::iterator< std::input_iterator_tag, T > { + public: + Top_dimensional_cells_iterator(Bitmap_cubical_complex_base& b) : b(b) { + this->counter = std::vector(b.dimension()); + // std::fill( this->counter.begin() , this->counter.end() , 0 ); + } + + Top_dimensional_cells_iterator operator++() { + // first find first element of the counter that can be increased: + size_t dim = 0; + while ((dim != this->b.dimension()) && (this->counter[dim] == this->b.sizes[dim] - 1))++dim; + + if (dim != this->b.dimension()) { + ++this->counter[dim]; + for (size_t i = 0; i != dim; ++i) { + this->counter[i] = 0; + } + } else { + ++this->counter[0]; + } + return *this; + } + + Top_dimensional_cells_iterator operator++(int) { + Top_dimensional_cells_iterator result = *this; + ++(*this); + return result; + } + + Top_dimensional_cells_iterator& operator=(const Top_dimensional_cells_iterator& rhs) { + this->counter = rhs.counter; + this->b = rhs.b; + return *this; + } + + bool operator==(const Top_dimensional_cells_iterator& rhs)const { + if (&this->b != &rhs.b)return false; + if (this->counter.size() != rhs.counter.size())return false; + for (size_t i = 0; i != this->counter.size(); ++i) { + if (this->counter[i] != rhs.counter[i])return false; + } + return true; + } + + bool operator!=(const Top_dimensional_cells_iterator& rhs)const { + return !(*this == rhs); + } + + /* + * The operator * returns position of a cube in the structure of cubical complex. This position can be then used as + * an argument of the following functions: + * get_boundary_of_a_cell, get_coboundary_of_a_cell, get_dimension_of_a_cell to get information about the cell + * boundary and coboundary and dimension + * and in function get_cell_data to get a filtration of a cell. + */ + size_t operator*() { + return this->compute_index_in_bitmap(); + } + + size_t compute_index_in_bitmap()const { + size_t index = 0; + for (size_t i = 0; i != this->counter.size(); ++i) { + index += (2 * this->counter[i] + 1) * this->b.multipliers[i]; + } + return index; + } + + void print_counter()const { + for (size_t i = 0; i != this->counter.size(); ++i) { + std::cout << this->counter[i] << " "; + } + } + friend class Bitmap_cubical_complex_base; + protected: + std::vector< size_t > counter; + Bitmap_cubical_complex_base& b; + }; + + /** + * Function returning a Top_dimensional_cells_iterator to the first top dimensional cell of the bitmap. + **/ + Top_dimensional_cells_iterator top_dimensional_cells_iterator_begin() { + Top_dimensional_cells_iterator a(*this); + return a; + } + + /** + * Function returning a Top_dimensional_cells_iterator to the last top dimensional cell of the bitmap. + **/ + Top_dimensional_cells_iterator top_dimensional_cells_iterator_end() { + Top_dimensional_cells_iterator a(*this); + for (size_t i = 0; i != this->dimension(); ++i) { + a.counter[i] = this->sizes[i] - 1; + } + a.counter[0]++; + return a; + } + + /** + * @brief Top_dimensional_cells_iterator_range class provides ranges for Top_dimensional_cells_iterator_range + **/ + class Top_dimensional_cells_range { + public: + Top_dimensional_cells_range(Bitmap_cubical_complex_base* b) : b(b) { } + + Top_dimensional_cells_iterator begin() { + return b->top_dimensional_cells_iterator_begin(); + } + + Top_dimensional_cells_iterator end() { + return b->top_dimensional_cells_iterator_end(); + } + private: + Bitmap_cubical_complex_base* b; + }; + + Top_dimensional_cells_range top_dimensional_cells_range() { + return Top_dimensional_cells_range(this); + } + + + //****************************************************************************************************************// + //****************************************************************************************************************// + //****************************************************************************************************************// + //****************************************************************************************************************// + + inline size_t number_cells()const { + return this->total_number_of_cells; + } + + //****************************************************************************************************************// + //****************************************************************************************************************// + //****************************************************************************************************************// + //****************************************************************************************************************// + + protected: + std::vector sizes; + std::vector multipliers; + std::vector data; + size_t total_number_of_cells; + + void set_up_containers(const std::vector& sizes) { + unsigned multiplier = 1; + for (size_t i = 0; i != sizes.size(); ++i) { + this->sizes.push_back(sizes[i]); + this->multipliers.push_back(multiplier); + multiplier *= 2 * sizes[i] + 1; + } + this->data = std::vector(multiplier, std::numeric_limits::max()); + this->total_number_of_cells = multiplier; + } + + size_t compute_position_in_bitmap(const std::vector< unsigned >& counter) { + size_t position = 0; + for (size_t i = 0; i != this->multipliers.size(); ++i) { + position += this->multipliers[i] * counter[i]; + } + return position; + } + + std::vector compute_counter_for_given_cell(size_t cell)const { + std::vector counter; + counter.reserve(this->sizes.size()); + for (size_t dim = this->sizes.size(); dim != 0; --dim) { + counter.push_back(cell / this->multipliers[dim - 1]); + cell = cell % this->multipliers[dim - 1]; + } + std::reverse(counter.begin(), counter.end()); + return counter; + } + void read_perseus_style_file(const char* perseus_style_file); + void setup_bitmap_based_on_top_dimensional_cells_list(const std::vector& sizes_in_following_directions, + const std::vector& top_dimensional_cells); + Bitmap_cubical_complex_base(const char* perseus_style_file, std::vector directions); + Bitmap_cubical_complex_base(const std::vector& sizes, std::vector directions); + Bitmap_cubical_complex_base(const std::vector& dimensions, + const std::vector& top_dimensional_cells, + std::vector directions); +}; + +template +void Bitmap_cubical_complex_base::put_data_to_bins(size_t number_of_bins) { + bool bdg = false; + + std::pair< T, T > min_max = this->min_max_filtration(); + T dx = (min_max.second - min_max.first) / (T) number_of_bins; + + // now put the data into the appropriate bins: + for (size_t i = 0; i != this->data.size(); ++i) { + if (bdg) { + std::cerr << "Before binning : " << this->data[i] << std::endl; + } + this->data[i] = min_max.first + dx * (this->data[i] - min_max.first) / number_of_bins; + if (bdg) { + std::cerr << "After binning : " << this->data[i] << std::endl; + getchar(); + } + } +} + +template +void Bitmap_cubical_complex_base::put_data_to_bins(T diameter_of_bin) { + bool bdg = false; + std::pair< T, T > min_max = this->min_max_filtration(); + + size_t number_of_bins = (min_max.second - min_max.first) / diameter_of_bin; + // now put the data into the appropriate bins: + for (size_t i = 0; i != this->data.size(); ++i) { + if (bdg) { + std::cerr << "Before binning : " << this->data[i] << std::endl; + } + this->data[i] = min_max.first + diameter_of_bin * (this->data[i] - min_max.first) / number_of_bins; + if (bdg) { + std::cerr << "After binning : " << this->data[i] << std::endl; + getchar(); + } + } +} + +template +std::pair< T, T > Bitmap_cubical_complex_base::min_max_filtration() { + std::pair< T, T > min_max(std::numeric_limits::max(), std::numeric_limits::min()); + for (size_t i = 0; i != this->data.size(); ++i) { + if (this->data[i] < min_max.first)min_max.first = this->data[i]; + if (this->data[i] > min_max.second)min_max.second = this->data[i]; + } + return min_max; +} + +template +std::ostream& operator<<(std::ostream & out, const Bitmap_cubical_complex_base& b) { + for (typename Bitmap_cubical_complex_base::all_cells_const_iterator + it = b.all_cells_const_begin(); it != b.all_cells_const_end(); ++it) { + out << *it << " "; + } + return out; +} + +template +Bitmap_cubical_complex_base::Bitmap_cubical_complex_base +(const std::vector& sizes) { + this->set_up_containers(sizes); +} + +template +void Bitmap_cubical_complex_base::setup_bitmap_based_on_top_dimensional_cells_list(const std::vector& sizes_in_following_directions, + const std::vector& top_dimensional_cells) { + this->set_up_containers(sizes_in_following_directions); + + size_t number_of_top_dimensional_elements = 1; + for (size_t i = 0; i != sizes_in_following_directions.size(); ++i) { + number_of_top_dimensional_elements *= sizes_in_following_directions[i]; + } + if (number_of_top_dimensional_elements != top_dimensional_cells.size()) { + std::cerr << "Error in constructor Bitmap_cubical_complex_base ( std::vector sizes_in_following_directions" + << ", std::vector top_dimensional_cells ). Number of top dimensional elements that follow from " + << "sizes_in_following_directions vector is different than the size of top_dimensional_cells vector." + << std::endl; + throw("Error in constructor Bitmap_cubical_complex_base( std::vector sizes_in_following_directions," + "std::vector top_dimensional_cells ). Number of top dimensional elements that follow from " + "sizes_in_following_directions vector is different than the size of top_dimensional_cells vector."); + } + + Bitmap_cubical_complex_base::Top_dimensional_cells_iterator it(*this); + size_t index = 0; + for (it = this->top_dimensional_cells_iterator_begin(); it != this->top_dimensional_cells_iterator_end(); ++it) { + this->get_cell_data(*it) = top_dimensional_cells[index]; + ++index; + } + this->impose_lower_star_filtration(); +} + +template +Bitmap_cubical_complex_base::Bitmap_cubical_complex_base +(const std::vector& sizes_in_following_directions, const std::vector& top_dimensional_cells) { + this->setup_bitmap_based_on_top_dimensional_cells_list(sizes_in_following_directions, top_dimensional_cells); +} + +template +void Bitmap_cubical_complex_base::read_perseus_style_file(const char* perseus_style_file) { + bool dbg = false; + std::ifstream inFiltration; + inFiltration.open(perseus_style_file); + unsigned dimensionOfData; + inFiltration >> dimensionOfData; + + if (dbg) { + std::cerr << "dimensionOfData : " << dimensionOfData << std::endl; + getchar(); + } + + std::vector sizes; + sizes.reserve(dimensionOfData); + for (size_t i = 0; i != dimensionOfData; ++i) { + unsigned size_in_this_dimension; + inFiltration >> size_in_this_dimension; + sizes.push_back(size_in_this_dimension); + if (dbg) { + std::cerr << "size_in_this_dimension : " << size_in_this_dimension << std::endl; + } + } + this->set_up_containers(sizes); + + Bitmap_cubical_complex_base::Top_dimensional_cells_iterator it(*this); + it = this->top_dimensional_cells_iterator_begin(); + + while (!inFiltration.eof()) { + T filtrationLevel; + inFiltration >> filtrationLevel; + if (dbg) { + std::cerr << "Cell of an index : " + << it.compute_index_in_bitmap() + << " and dimension: " + << this->get_dimension_of_a_cell(it.compute_index_in_bitmap()) + << " get the value : " << filtrationLevel << std::endl; + } + this->get_cell_data(*it) = filtrationLevel; + ++it; + } + inFiltration.close(); + this->impose_lower_star_filtration(); +} + +template +Bitmap_cubical_complex_base::Bitmap_cubical_complex_base(const char* perseus_style_file, + std::vector directions) { + // this constructor is here just for compatibility with a class that creates cubical complexes with periodic boundary + // conditions. + // It ignores the last parameter of the function. + this->read_perseus_style_file(perseus_style_file); +} + +template +Bitmap_cubical_complex_base::Bitmap_cubical_complex_base(const std::vector& sizes, + std::vector directions) { + // this constructor is here just for compatibility with a class that creates cubical complexes with periodic boundary + // conditions. + // It ignores the last parameter of the function. + this->set_up_containers(sizes); +} + +template +Bitmap_cubical_complex_base::Bitmap_cubical_complex_base(const std::vector& dimensions, + const std::vector& top_dimensional_cells, + std::vector directions) { + // this constructor is here just for compatibility with a class that creates cubical complexes with periodic boundary + // conditions. + // It ignores the last parameter of the function. + this->setup_bitmap_based_on_top_dimensional_cells_list(dimensions, top_dimensional_cells); +} + +template +Bitmap_cubical_complex_base::Bitmap_cubical_complex_base(const char* perseus_style_file) { + this->read_perseus_style_file(perseus_style_file); +} + +template +std::vector< size_t > Bitmap_cubical_complex_base::get_boundary_of_a_cell(size_t cell)const { + std::vector< size_t > boundary_elements; + + // Speed traded of for memory. Check if it is better in practice. + boundary_elements.reserve(this->dimension()*2); + + size_t cell1 = cell; + for (size_t i = this->multipliers.size(); i != 0; --i) { + unsigned position = cell1 / this->multipliers[i - 1]; + if (position % 2 == 1) { + boundary_elements.push_back(cell - this->multipliers[ i - 1 ]); + boundary_elements.push_back(cell + this->multipliers[ i - 1 ]); + } + cell1 = cell1 % this->multipliers[i - 1]; + } + return boundary_elements; +} + +template +std::vector< size_t > Bitmap_cubical_complex_base::get_coboundary_of_a_cell(size_t cell)const { + std::vector counter = this->compute_counter_for_given_cell(cell); + std::vector< size_t > coboundary_elements; + size_t cell1 = cell; + for (size_t i = this->multipliers.size(); i != 0; --i) { + unsigned position = cell1 / this->multipliers[i - 1]; + if (position % 2 == 0) { + if ((cell > this->multipliers[i - 1]) && (counter[i - 1] != 0)) { + coboundary_elements.push_back(cell - this->multipliers[i - 1]); + } + if ( + (cell + this->multipliers[i - 1] < this->data.size()) && (counter[i - 1] != 2 * this->sizes[i - 1])) { + coboundary_elements.push_back(cell + this->multipliers[i - 1]); + } + } + cell1 = cell1 % this->multipliers[i - 1]; + } + return coboundary_elements; +} + +template +unsigned Bitmap_cubical_complex_base::get_dimension_of_a_cell(size_t cell)const { + bool dbg = false; + if (dbg) std::cerr << "\n\n\n Computing position o a cell of an index : " << cell << std::endl; + unsigned dimension = 0; + for (size_t i = this->multipliers.size(); i != 0; --i) { + unsigned position = cell / this->multipliers[i - 1]; + + if (dbg) { + std::cerr << "i-1 :" << i - 1 << std::endl; + std::cerr << "cell : " << cell << std::endl; + std::cerr << "position : " << position << std::endl; + std::cerr << "multipliers[" << i - 1 << "] = " << this->multipliers[i - 1] << std::endl; + getchar(); + } + + if (position % 2 == 1) { + if (dbg) std::cerr << "Nonzero length in this direction \n"; + dimension++; + } + cell = cell % this->multipliers[i - 1]; + } + return dimension; +} + +template +inline T& Bitmap_cubical_complex_base::get_cell_data(size_t cell) { + return this->data[cell]; +} + +template +void Bitmap_cubical_complex_base::impose_lower_star_filtration() { + bool dbg = false; + + // this vector will be used to check which elements have already been taken care of in imposing lower star filtration + std::vector is_this_cell_considered(this->data.size(), false); + + size_t size_to_reserve = 1; + for (size_t i = 0; i != this->multipliers.size(); ++i) { + size_to_reserve *= (size_t) ((this->multipliers[i] - 1) / 2); + } + + std::vector indices_to_consider; + indices_to_consider.reserve(size_to_reserve); + // we assume here that we already have a filtration on the top dimensional cells and + // we have to extend it to lower ones. + typename Bitmap_cubical_complex_base::Top_dimensional_cells_iterator it(*this); + for (it = this->top_dimensional_cells_iterator_begin(); it != this->top_dimensional_cells_iterator_end(); ++it) { + indices_to_consider.push_back(it.compute_index_in_bitmap()); + } + + while (indices_to_consider.size()) { + if (dbg) { + std::cerr << "indices_to_consider in this iteration \n"; + for (size_t i = 0; i != indices_to_consider.size(); ++i) { + std::cout << indices_to_consider[i] << " "; + } + getchar(); + } + std::vector new_indices_to_consider; + for (size_t i = 0; i != indices_to_consider.size(); ++i) { + std::vector bd = this->get_boundary_of_a_cell(indices_to_consider[i]); + for (size_t boundaryIt = 0; boundaryIt != bd.size(); ++boundaryIt) { + if (dbg) { + std::cerr << "filtration of a cell : " << bd[boundaryIt] << " is : " << this->data[ bd[boundaryIt] ] + << " while of a cell: " << indices_to_consider[i] << " is: " << this->data[ indices_to_consider[i] ] + << std::endl; + getchar(); + } + if (this->data[ bd[boundaryIt] ] > this->data[ indices_to_consider[i] ]) { + this->data[ bd[boundaryIt] ] = this->data[ indices_to_consider[i] ]; + if (dbg) { + std::cerr << "Setting the value of a cell : " << bd[boundaryIt] << " to : " + << this->data[ indices_to_consider[i] ] << std::endl; + getchar(); + } + } + if (is_this_cell_considered[ bd[boundaryIt] ] == false) { + new_indices_to_consider.push_back(bd[boundaryIt]); + is_this_cell_considered[ bd[boundaryIt] ] = true; + } + } + } + indices_to_consider.swap(new_indices_to_consider); + } +} + +template +bool compareFirstElementsOfTuples(const std::pair< std::pair< T, size_t >, char >& first, + const std::pair< std::pair< T, size_t >, char >& second) { + if (first.first.first < second.first.first) { + return true; + } else { + if (first.first.first > second.first.first) { + return false; + } + // in this case first.first.first == second.first.first, so we need to compare dimensions + return first.second < second.second; + } +} + +} // namespace cubical_complex + +namespace Cubical_complex = cubical_complex; + +} // namespace Gudhi + +#endif // BITMAP_CUBICAL_COMPLEX_BASE_H_ -- cgit v1.2.3