qpms/qpms/groups.h

90 lines
3.5 KiB
C

/*! \file groups.h
* \brief Point groups.
*
* Right now, the instances of qpms_finite_group_t are created at compilation time
* from source code generated by Python script TODO (output groups.c)
* and they are not to be constructed dynamically.
*
* In the end, I might want to have a special type for 3D point groups
* or more specifically, for the closed subgroups of O(3), see
* https://en.wikipedia.org/wiki/Point_groups_in_three_dimensions.
* They consist of the seven infinite series of axial groups
* (characterized by the series index, the axis direction,
* and the index \a n of the \a n-fold rotational symmetry)
* and the seven remaining point groups + the finite groups.
* All off them have a quite limited number of generators
* (max. 4?; CHECKME).
* The goal is to have some representation that would enable to
* 1. fully describe the symmetries of abstract T-matrices/nanoparticles,
* 2. quickly determine e.g. whether one is a subgroup of another,
* 3. have all the irreps,
* 4. have all in C and without excessive external dependencies,
* etc.
*/
#ifndef QPMS_GROUPS_H
#define QPMS_GROUPS_H
#include "qpms_types.h"
/// To be used only in qpms_finite_group_t
struct qpms_finite_group_irrep_t {
int dim; ///< Irrep dimension.
char *name; ///< Irrep label.
/// Irrep matrix data.
/** The r-th row, c-th column of the representation of the i'th element is retrieved as
* m[i * dim * dim + r * dim + c]
*/
complex double *m;
};
/// A point group with its irreducible representations and some metadata.
/**
* The structure of the group is given by the multiplication table \a mt.
*
* Each element of the group has its index from 0 to order.
* The metadata about some element are then accessed using that index.
*
* All members are in principle optional except \a order and \a mt.
*
* Note: after changing this struct, don't forget to update the Python method
* SVWFPointGroupInfo.generate_c_source().
*/
typedef struct qpms_finite_group_t {
char *name;
qpms_gmi_t order; ///< Group order (number of elements)
qpms_gmi_t idi; ///< Identity element index
qpms_gmi_t *mt; ///< Group multiplication table. If c = a*b, then ic = mt[order * ia + ib].
qpms_gmi_t *invi; ///< Group elem inverse indices.
qpms_gmi_t *gens; ///< A canonical set of group generators.
int ngens; ///< Number of the generators in gens;
qpms_permutation_t *permrep; ///< Permutation representations of the elements.
char **elemlabels; ///< Optional human readable labels for the group elements.
int permrep_nelem; ///< Number of the elements over which the permutation representation acts.
struct qpms_irot3_t *rep3d; ///< The quaternion representation of a 3D point group (if applicable).
qpms_iri_t nirreps; ///< How many irreps does the group have
struct qpms_finite_group_irrep_t *irreps; ///< Irreducible representations of the group.
} qpms_finite_group_t;
/// Group multiplication.
static inline qpms_gmi_t qpms_finite_group_mul(const qpms_finite_group_t *G,
qpms_gmi_t a, qpms_gmi_t b) {
assert(a < G->order);
assert(b < G->order);
return G->mt[G->order * a + b];
}
/// Group element inversion.
static inline qpms_gmi_t qpms_finite_group_inv(const qpms_finite_group_t *G,
qpms_gmi_t a) {
assert(a < G->order);
return G->invi[a];
}
/// NOT IMPLEMENTED Get irrep index by name.
qpms_iri_t qpms_finite_group_find_irrep_by_name(qpms_finite_group_t *G, char *name);
extern const qpms_finite_group_t QPMS_FINITE_GROUP_TRIVIAL;
extern const qpms_finite_group_t QPMS_FINITE_GROUP_TRIVIAL_G;
#endif // QPMS_GROUPS_H