qpms/qpms/lattices.h

259 lines
7.7 KiB
C

#ifndef LATTICES_H
#define LATTICES_H
/* IMPORTANT TODO
* ==============
*
* The current content of this part (and the implementation) is extremely ugly.
* When I have some time, I have to rewrite this in the style of lattices2d.py
*
*/
#include <math.h>
#include <stdbool.h>
#include <assert.h>
#include <stddef.h>
#include <stdlib.h>
#define M_SQRT3 1.7320508075688772935274463415058724
#define M_SQRT3_2 (M_SQRT3/2)
#define M_1_SQRT3 0.57735026918962576450914878050195746
// fuck, I already had had suitable type
#include "vectors.h"
typedef cart2_t point2d;
static inline point2d point2d_fromxy(const double x, const double y) {
point2d p;
p.x = x;
p.y = y;
return p;
}
/*
* THE NICE PART (adaptation of lattices2d.py)
* ===========================================
*
* all the functions are prefixed with l2d_
* convention for argument order: inputs, *outputs, add. params
*/
#define BASIS_RTOL 1e-13
typedef enum {
OBLIQUE = 1,
RECTANGULAR = 2,
SQUARE = 4,
RHOMBIC = 5,
EQUILATERAL_TRIANGULAR = 3,
RIGHT_ISOSCELES=SQUARE,
PARALLELOGRAMMIC=OBLIQUE,
CENTERED_RHOMBIC=RECTANGULAR,
RIGHT_TRIANGULAR=RECTANGULAR,
CENTERED_RECTANGULAR=RHOMBIC,
ISOSCELE_TRIANGULAR=RHOMBIC,
RIGHT_ISOSCELE_TRIANGULAR=SQUARE,
HEXAGONAL=EQUILATERAL_TRIANGULAR
} LatticeType;
/*
* Lagrange-Gauss reduction of a 2D basis.
* The output shall satisfy |out1| <= |out2| <= |out2 - out1|
*/
void l2d_reduceBasis(cart2_t in1, cart2_t in2, cart2_t *out1, cart2_t *out2);
/*
* This gives the "ordered shortest triple" of base vectors (each pair from the triple
* is a base) and there may not be obtuse angle between o1, o2 and between o2, o3
*/
void l2d_shortestBase3(cart2_t i1, cart2_t i2, cart2_t *o1, cart2_t *o2, cart2_t *o3);
/*
* TODO doc
* return value is 4 or 6.
*/
int l2d_shortestBase46(cart2_t i1, cart2_t i2, cart2_t *o1, cart2_t *o2, cart2_t *o3, cart2_t *o4, cart2_t *o5, cart2_t *o6, double rtol);
// variant
int l2d_shortestBase46_arr(cart2_t i1, cart2_t i2, cart2_t *oarr, double rtol);
// Determines whether angle between inputs is obtuse
bool l2d_is_obtuse(cart2_t i1, cart2_t i2, double rtol);
/*
* Given two basis vectors, returns 2D Bravais lattice type.
*/
LatticeType l2d_classifyLattice(cart2_t b1, cart2_t b2, double rtol);
// Other functions in lattices2d.py: TODO?
// range2D()
// generateLattice()
// generateLatticeDisk()
// cutWS()
// filledWS()
// change_basis()
/*
* Given basis vectors, returns the corners of the Wigner-Seits unit cell (W1, W2, -W1, W2)
* for rectangular and square lattice or (w1, w2, w3, -w1, -w2, -w3) otherwise.
*/
int l2d_cellCornersWS(cart2_t i1, cart2_t i2, cart2_t *o1, cart2_t *o2, cart2_t *o3, cart2_t *o4, cart2_t *o5, cart2_t *o6, double rtol);
// variant
int l2d_cellCornersWS_arr(cart2_t i1, cart2_t i2, cart2_t *oarr, double rtol);
// Reciprocal bases
void l2d_reciprocalBasis1(cart2_t b1, cart2_t b2, cart2_t *rb1, cart2_t *rb2);
void l2d_reciprocalBasis2pi(cart2_t b1, cart2_t b2, cart2_t *rb1, cart2_t *rb2);
/*
* THE MORE OR LESS OK PART
* ========================
*/
/*
* General set of points ordered by the r-coordinate.
* Typically, this will include all lattice inside a certain circle.
* This structure is internally used by the "lattice generators" below.
* It does not have its memory management of its own, as it is handled
* by the "generators". For everything except the generators,
* this structure shall be read-only.
*/
typedef struct {
size_t nrs; // number of different radii
double *rs; // the radii; of length nrs (largest contained radius == rs[nrs-1])
point2d *base;
ptrdiff_t *r_offsets; // of length nrs+1 (using relative offsets due to possible realloc's)
// the jth point of i-th radius is base[r_offsets[i]+j] or using the inline below..
/* // redundand (therefore removed) members
* point2d *points; // redundant as it is the same as points_at_r[0]
* size_t npoints; // redundant as it is the same as points_at_r[nrs]-points_at_r[0]
*/
} points2d_rordered_t;
// sorts arbitrary points and creates points2d_rordered_t
points2d_rordered_t *points2d_rordered_frompoints(const point2d *orig_base,
size_t nmemb, double rtol, double atol);
// returns a copy but shifted by a constant (actually in a stupid way, but whatever)
points2d_rordered_t *points2d_rordered_shift(const points2d_rordered_t *orig,
point2d shift, double rtol, double atol);
// returns a copy but scaled by a factor
points2d_rordered_t *points2d_rordered_scale(const points2d_rordered_t *orig,
double factor);
/* The destructor: use only for results of
* - points2D_rordered_frompoints,
* - points2d_rordered_shift,
* - points2d_rordered_scale.
*/
void points2d_rordered_free(points2d_rordered_t *);
static inline point2d points2d_rordered_get_point(const points2d_rordered_t *ps, int r_order, int i) {
assert(i >= 0);
assert(r_order < ps->nrs);
assert(i < (ps->r_offsets[r_order+1] - ps->r_offsets[r_order]));
return ps->base[ps->r_offsets[r_order] + i];
}
static inline double points2d_rordered_get_r(const points2d_rordered_t *ps, int r_order) {
assert(r_order < ps->nrs);
return ps->rs[r_order];
}
ptrdiff_t points2d_rordered_locate_r(const points2d_rordered_t *, double r);
// returns a "view" (does not copy any of the arrays)
// -- DO NOT FREE orig BEFORE THE END OF SCOPE OF THE RESULT
points2d_rordered_t points2d_rordered_annulus(const points2d_rordered_t *orig, double minr, bool minr_inc,
double maxr, bool maxr_inc);
/*
* THE UGLY PART
* =============
*/
/*
* EQUILATERAL TRIANGULAR LATTICE
*/
typedef enum {
TRIANGULAR_VERTICAL, // there is a lattice base vector parallel to the y-axis
TRIANGULAR_HORIZONTAL // there is a lattice base vector parallel to the x-axis
} TriangularLatticeOrientation;
static inline TriangularLatticeOrientation reverseTriangularLatticeOrientation(TriangularLatticeOrientation o){
switch(o) {
case TRIANGULAR_VERTICAL:
return TRIANGULAR_HORIZONTAL;
break;
case TRIANGULAR_HORIZONTAL:
return TRIANGULAR_VERTICAL;
break;
default:
abort();
}
abort();
}
// implementation data structures; not needed in the header file
typedef struct triangular_lattice_gen_privstuff_t triangular_lattice_gen_privstuff_t;
typedef struct {
// public:
points2d_rordered_t ps;
TriangularLatticeOrientation orientation;
double a; // lattice vector length
// not sure if needed:
bool includes_origin;
// Denotes an offset of the "origin" point; meaning step hexshift * a / sqrt(2) upwards
// or leftwards for the horizontal or vertical orientations, respectively.
int hexshift;
// private:
triangular_lattice_gen_privstuff_t *priv;
} triangular_lattice_gen_t;
triangular_lattice_gen_t *triangular_lattice_gen_init(double a, TriangularLatticeOrientation ori, bool include_origin,
int halfoffset);
const points2d_rordered_t * triangular_lattice_gen_getpoints(const triangular_lattice_gen_t *g);
int triangular_lattice_gen_extend_to_r(triangular_lattice_gen_t *g, double r);
int triangular_lattice_gen_extend_to_steps(triangular_lattice_gen_t *g, int maxsteps);
void triangular_lattice_gen_free(triangular_lattice_gen_t *g);
/*
* HONEYCOMB LATTICE
*/
typedef struct {
// public:
points2d_rordered_t ps;
TriangularLatticeOrientation orientation;
double a;
double h;
// private:
triangular_lattice_gen_t *tg;
} honeycomb_lattice_gen_t;
honeycomb_lattice_gen_t *honeycomb_lattice_gen_init_h(double h, TriangularLatticeOrientation ori);
honeycomb_lattice_gen_t *honeycomb_lattice_gen_init_a(double a, TriangularLatticeOrientation ori);
int honeycomb_lattice_gen_extend_to_steps(honeycomb_lattice_gen_t *g, int maxsteps);
int honeycomb_lattice_gen_extend_to_r(honeycomb_lattice_gen_t *g, double r);
void honeycomb_lattice_gen_free(honeycomb_lattice_gen_t *g);
#endif // LATTICES_H