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#include <vector>
#include <iostream>
#include <cassert>
#include <queue>
#include <unordered_map>
#include "prettyprint.hpp"
//#include <boost/numeric/ublas/symmetric.hpp>
class binomial_coeff_table {
std::vector<std::vector<int> > B;
int n_max, k_max;
public:
binomial_coeff_table(int n, int k) {
n_max = n;
k_max = k;
B.resize(n + 1);
for( int i = 0; i <= n; i++ ) {
B[i].resize(k + 1);
for ( int j = 0; j <= std::min(i, k); j++ )
{
if (j == 0 || j == i)
B[i][j] = 1;
else
B[i][j] = B[i-1][j-1] + B[i-1][j];
}
}
}
int operator()(int n, int k) const {
// std::cout << "B(" << n << "," << k << ")\n";
return B[n][k];
}
};
template<typename OutputIterator>
OutputIterator get_simplex_vertices( int idx, int dim, int n, const binomial_coeff_table& binomial_coeff, OutputIterator out )
{
--n;
for( int k = dim + 1; k > 0; --k ) {
while( binomial_coeff( n , k ) > idx ) {
--n;
}
*out++ = n;
idx -= binomial_coeff( n , k );
}
return out;
}
template <typename DistanceMatrix>
class rips_filtration_comparator {
public:
const DistanceMatrix& dist;
const int dim;
private:
std::vector<int> vertices;
typedef decltype(dist(0,0)) dist_t;
bool reverse;
const binomial_coeff_table& binomial_coeff;
public:
rips_filtration_comparator(
const DistanceMatrix& _dist,
const int _dim,
const binomial_coeff_table& _binomial_coeff
// ,
// bool _reverse = true
):
dist(_dist), dim(_dim), vertices(_dim + 1),
binomial_coeff(_binomial_coeff)
// ,
// reverse(_reverse)
{};
dist_t diam(const int index) {
dist_t diam = 0;
get_simplex_vertices(index, dim, dist.size(), binomial_coeff, vertices.begin() );
for (int i = 0; i <= dim; ++i)
for (int j = i + 1; j <= dim; ++j) {
auto d = dist(vertices[i], vertices[j]);
diam = std::max(diam, dist(vertices[i], vertices[j]));
}
return diam;
}
bool operator()(const int a, const int b)
{
assert(a < binomial_coeff(dist.size(), dim + 1));
assert(b < binomial_coeff(dist.size(), dim + 1));
dist_t a_diam = 0, b_diam = 0;
a_diam = diam(a);
get_simplex_vertices(b, dim, dist.size(), binomial_coeff, vertices.begin() );
for (int i = 0; i <= dim; ++i)
for (int j = i + 1; j <= dim; ++j) {
b_diam = std::max(b_diam, dist(vertices[i], vertices[j]));
if (a_diam < b_diam)
// (((a_diam < b_diam) && !reverse) ||
// ((a_diam > b_diam) && reverse))
return true;
}
return (a_diam == b_diam) && (a < b);
// return (a_diam == b_diam) && (((a < b) && !reverse) || ((a > b) && reverse));
}
};
template<typename OutputIterator>
void get_simplex_coboundary( int idx, int dim, int n, const binomial_coeff_table& binomial_coeff, OutputIterator coboundary )
{
--n;
int modified_idx = idx;
for( int k = dim + 1; k >= 0 && n >= 0; --k ) {
while( binomial_coeff( n , k ) > idx ) {
// std::cout << "binomial_coeff(" << n << ", " << k << ") = " << binomial_coeff( n , k ) << " > " << idx << std::endl;
*coboundary++ = modified_idx + binomial_coeff( n , k + 1 );
if (n==0) break;
--n;
}
idx -= binomial_coeff( n , k );
modified_idx -= binomial_coeff( n , k );
modified_idx += binomial_coeff( n , k + 1 );
--n;
}
return;
}
class distance_matrix {
public:
typedef double value_type;
std::vector<std::vector<double> > distances;
double operator()(const int a, const int b) const {
return distances[a][b];
}
size_t size() const {
return distances.size();
}
};
template <typename ValueType>
class compressed_sparse_matrix {
public:
std::vector<size_t> bounds;
std::vector<ValueType> entries;
size_t size() const {
return bounds.size();
}
typename std::vector<ValueType>::const_iterator cbegin(size_t index) {
assert(index < size());
return index == 0 ? entries.cbegin() : entries.cbegin() + bounds[index - 1];
}
typename std::vector<ValueType>::const_iterator cend(size_t index) {
assert(index < size());
return entries.cbegin() + bounds[index];
}
template <typename Iterator>
void append(Iterator begin, Iterator end) {
for (Iterator it = begin; it != end; ++it) {
entries.push_back(*it);
}
bounds.push_back(entries.size());
}
template <typename Collection>
void append(const Collection collection) {
append(collection.cbegin(), collection.cend());
}
};
int main() {
distance_matrix dist;
// dist.distances = {
// {0,1,2,3},
// {1,0,1,2},
// {2,1,0,1},
// {3,2,1,0}
// };
// dist.distances = {
// {0,1,1,1,1},
// {1,0,1,1,1},
// {1,1,0,1,1},
// {1,1,1,0,1},
// {1,1,1,1,0}
// };
dist.distances = {
{0,1,3,6,4},
{1,0,8,2,9},
{3,8,0,10,7},
{6,2,10,0,5},
{4,9,7,5,0}
};
int dim_max = 2;
binomial_coeff_table binomial_coeff(dist.size(), dim_max + 2);
std::cout << dist (0,1) << std::endl;
rips_filtration_comparator<distance_matrix> comp1(dist, 1, binomial_coeff);
rips_filtration_comparator<distance_matrix> comp2(dist, 2, binomial_coeff);
std::cout << (comp1(0,1) ? "0<1" : "0>=1") << std::endl;
std::cout << (comp1(1,0) ? "1<0" : "1>=0") << std::endl;
std::cout << (comp1(0,2) ? "0<2" : "0>=2") << std::endl;
std::cout << (comp1(1,2) ? "1<2" : "1>=2") << std::endl;
std::vector<int> edges = {0,1,2,3,4,5};
std::sort(edges.begin(), edges.end(), comp1);
std::cout << "sorted edges: " << edges << std::endl;
std::vector<int> triangles = {0,1,2,3};
std::sort(triangles.begin(), triangles.end(), comp2);
std::cout << "sorted triangles: " << triangles << std::endl;
int dim = 1;
int simplex_index = 2;
std::vector<int> vertices;
get_simplex_vertices( simplex_index, dim, dist.size(), binomial_coeff, std::back_inserter(vertices) );
std::cout << "coboundary of simplex " << vertices << ":" << std::endl;
std::vector<int> coboundary;
get_simplex_coboundary( simplex_index, dim, dist.size(), binomial_coeff, std::back_inserter(coboundary) );
for (int coboundary_simplex_index: coboundary) {
std::vector<int> vertices;
get_simplex_vertices( coboundary_simplex_index, dim + 1, dist.size(), binomial_coeff, std::back_inserter(vertices) );
std::cout << " " << coboundary_simplex_index << " " << vertices << " (" << comp1.diam(coboundary_simplex_index) << ")" << std::endl;
}
compressed_sparse_matrix<int> csm;
csm.append(std::vector<int>({1,2,3}));
csm.append(std::vector<int>({5,6,7,8}));
csm.append(std::vector<int>({10,11}));
csm.append(std::vector<int>());
csm.append(std::vector<int>({2}));
std::cout << "compressed sparse matrix: " << std::endl;
for (int i = 0; i < csm.size(); ++i) {
std::cout << " " << std::vector<int>(csm.cbegin(i), csm.cend(i)) << std::endl;
}
std::cout << "bounds: " << csm.bounds << std::endl;
std::cout << "entries: " << csm.entries << std::endl;
std::priority_queue<int, std::vector<int>, rips_filtration_comparator<distance_matrix> > working_boundary(comp1);
for (int e: coboundary) working_boundary.push(e);
std::cout << "pivot of coboundary: " << working_boundary.top() << std::endl;
std::cout << (comp1(3,6) ? "3<6" : "3>=6") << std::endl;
std::cout << (comp1(0,6) ? "0<6" : "0>=6") << std::endl;
std::unordered_map<int, int> pivot_column_index;
std::vector<int> columns_to_reduce = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9 };
std::sort(columns_to_reduce.begin(), columns_to_reduce.end(), comp1);
std::cout << "sorted columns to reduce: " << columns_to_reduce << std::endl;
for (int index: columns_to_reduce) {
std::vector<int> vertices;
get_simplex_vertices( index, dim, dist.size(), binomial_coeff, std::back_inserter(vertices) );
std::cout << " " << index << " " << vertices << " (" << comp1.diam(index) << ")" << std::endl;
}
}
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