#include <iostream>
-#include <libstick-0.1/booleanmatrix.h>
+#include "booleanmatrix.h"
namespace libstick {
* Each 0-dimensional simplex automatically has this simplex as its face.
* Consequently, the innner class simplex_order gives the extended boundary
* matrix. */
-template<int MAXDIM, class IT=uint32_t, class VT=double>
+template<int MAXDIM, class IT, class VT>
class simplicial_complex {
public:
typedef VT value_type;
/** A simplex of the complex. */
- struct Simplex {
+ struct simplex {
/** Dimension of the simplex. */
int dim;
/** The indices of the faces of the simplex. */
/** Create a new simplex with dimension 'dim', (dim+1)-faces and
* its value. If simpley is 0-dimensional, its face is
* automatically set to one (-1)-dimensional simplex. */
- static Simplex create(int dim, index_type* faces, value_type value) {
+ static simplex create(int dim, index_type* faces, value_type value) {
assert(0 <= dim && dim <= MAXDIM);
- Simplex s;
+ simplex s;
s.dim = dim;
s.value = value;
}
/** Create a (-1)-dimensional simplex. It has the lowest possible value. */
- static Simplex create_minusonedim_simplex() {
- Simplex s;
+ static simplex create_minusonedim_simplex() {
+ simplex s;
s.dim = -1;
s.faces[0] = 0;
class simplex_order {
public:
- typedef boolean_colrowmatrix<IT> boundary_matrix;
+ typedef boolean_colmatrix<IT> boundary_matrix;
/** Create a standard order of the complex c, i.e., the identity permutation. */
simplex_order(const simplcompltype &c) :
}
/** Get i-th simplex in the simplex order. */
- const Simplex& get_simplex(size_t i) const {
- assert(i < size());
+ const simplex& get_simplex(index_type i) const {
+ assert(0 <= i && i < size());
return c.simplices[order.at(i)];
}
+ const simplcompltype& get_complex() const {
+ return c;
+ }
+
/** Returns true iff the faces of simplex i are before i in this order. */
bool is_filtration() const {
assert(size() == c.size());
return is_filtration();
}
+ /** Randomize order. It has hardly any impact on runtime, but
+ * it makes cycles "nicer" when the simplice's function values
+ * are constant.
+ * */
+ void randomize_order() {
+ std::random_shuffle(order.begin(), order.end());
+ restore_revorder_from_order();
+ }
+
/** Sort simplices such that is_monotone() gives true. This
* requires that the complex's is_monotone() gave true
* beforehand.*/
void make_monotone_filtration() {
assert(c.is_monotone());
- sort(order.begin(), order.end(), cmp_monotone_filtration(c));
+ std::sort(order.begin(), order.end(), cmp_monotone_filtration(c));
restore_revorder_from_order();
assert(c.is_monotone());
public:
simplicial_complex() {
// Add the one minus-one dimensional simplex
- add_simplex(Simplex::create_minusonedim_simplex());
+ add_simplex(simplex::create_minusonedim_simplex());
+ }
+
+ /** Remove all simplices except the dummy simplex */
+ void clear() {
+ simplices.resize(1);
}
/** Return number of simplices. */
}
/** Add a simplex to the complex. The dimension of the faces must be
- * dim-1, and they must already be part of the complex. */
- void add_simplex(int dim, index_type* faces, value_type value) {
- add_simplex(Simplex::create(dim, faces, value));
+ * dim-1, and they must already be part of the complex. Returns the
+ * index of the added simplex. */
+ index_type add_simplex(int dim, index_type* faces, value_type value) {
+ return add_simplex(simplex::create(dim, faces, value));
+ }
+
+ /** Add a simplex to the complex of at least dimension 1. The dimension
+ * of the faces must be dim-1, and they must already be part of the
+ * complex. The value of the simplex is set to the maximum value of its
+ * faces. Returns the index of the added simplex. */
+ index_type add_simplex(int dim, index_type* faces) {
+ assert(dim >= 1);
+
+ // Get max value of its faces
+ VT value = simplices[faces[0]].value;
+ for (size_t i=0; i < simplex::face_count_bydim(dim); ++i)
+ value = std::max(value, simplices[faces[i]].value);
+
+ return add_simplex(dim, faces, value);
}
/** Add a simplex to the complex. The dimension of the faces must be
- * dim-1, and they must already be part of the complex. */
- void add_simplex(Simplex s) {
+ * dim-1, and they must already be part of the complex. Returns the
+ * index of the added simplex. */
+ index_type add_simplex(simplex s) {
// Check requirements for faces
for (unsigned i=0; i < s.face_count(); ++i) {
// Faces are already in complex.
assert(simplices[s.faces[i]].dim == s.dim-1);
}
+ // index_type must be large enough
+ assert(simplices.size() < std::numeric_limits<IT>::max());
+
+ index_type idx = simplices.size();
simplices.push_back(s);
+ return idx;
+ }
+
+ /** Add an array of simplices */
+ void add_simplices(simplex* sarray, size_t count) {
+ for (unsigned i=0; i < count; ++i)
+ add_simplex(sarray[i]);
}
/** Return true iff for each simplex i with dimension dim it holds that
bool is_complex() const {
for (unsigned i=0; i < size(); ++i) {
- const Simplex &s = simplices[i];
+ const simplex &s = simplices[i];
for (unsigned f=0; f < s.face_count(); ++f) {
if (s.faces[f] >= size())
return false;
- const Simplex &face = simplices[s.faces[f]];
+ const simplex &face = simplices[s.faces[f]];
if (face.dim != s.dim-1)
return false;
}
bool is_monotone() const {
assert(is_complex());
- typename std::vector<Simplex>::const_iterator it = ++simplices.begin();
+ typename std::vector<simplex>::const_iterator it = ++simplices.begin();
for (; it != simplices.end(); ++it)
for (unsigned f=0; f < it->face_count(); ++f)
if (simplices[it->faces[f]].value > it->value)
}
bool operator()(index_type i, index_type j) {
- const Simplex& si = c.simplices[i];
- const Simplex& sj = c.simplices[j];
+ const simplex& si = c.simplices[i];
+ const simplex& sj = c.simplices[j];
if (si.value < sj.value)
return true;
public:
/** A list of simplices */
- std::vector<Simplex> simplices;
+ std::vector<simplex> simplices;
};
}