Disable "hard" examples in CI
[qpms.git] / qpms / lattices.h
blobd7daa3ce7d15fef0fa105adab2b756227b257831
1 /*! \file lattices.h
2 * \brief Lattice point generators and lattice vector analysis / transformation.
4 */
5 #ifndef LATTICES_H
6 #define LATTICES_H
8 #include <math.h>
9 #include <stdbool.h>
10 #include <assert.h>
11 #include <stddef.h>
12 #include <stdlib.h>
13 #ifndef M_SQRT3
14 #define M_SQRT3 1.7320508075688772935274463415058724
15 #endif
16 #ifndef M_SQRT3_2
17 #define M_SQRT3_2 (M_SQRT3/2)
18 #endif
19 #ifndef M_1_SQRT3
20 #define M_1_SQRT3 0.57735026918962576450914878050195746
21 #endif
25 /* IMPORTANT TODO
26 * ==============
28 * The current content of this part (and the implementation) is extremely ugly.
29 * When I have some time, I have to rewrite this in the style of lattices2d.py
33 typedef enum LatticeDimensionality {
34 LAT1D = 1,
35 LAT2D = 2,
36 LAT3D = 4,
37 SPACE1D = 8,
38 SPACE2D = 16,
39 SPACE3D = 32,
40 LAT_1D_IN_3D = 33,
41 LAT_2D_IN_3D = 34,
42 LAT_3D_IN_3D = 40,
43 // special coordinate arrangements (indicating possible optimisations)
44 LAT_ZONLY = 64,
45 LAT_XYONLY = 128,
46 LAT_1D_IN_3D_ZONLY = 97, // LAT1D | SPACE3D | 64
47 LAT_2D_IN_3D_XYONLY = 162 // LAT2D | SPACE3D | 128
48 } LatticeDimensionality;
50 inline static bool LatticeDimensionality_checkflags(
51 LatticeDimensionality a, LatticeDimensionality flags_a_has_to_contain) {
52 return ((a & flags_a_has_to_contain) == flags_a_has_to_contain);
55 // fuck, I already had had suitable type
56 #include "vectors.h"
57 typedef cart2_t point2d;
59 static inline point2d point2d_fromxy(const double x, const double y) {
60 point2d p;
61 p.x = x;
62 p.y = y;
63 return p;
66 /// Lattice basis reduction.
67 /** This is currenty a bit naïve implementation of
68 * Lenstra-Lenstra-Lovász algorithm.
70 * The reduction happens in-place, i.e. the basis vectors in \a b are
71 * replaced with the reduced basis.
73 int qpms_reduce_lattice_basis(double *b, ///< Array of dimension [bsize][ndim].
74 const size_t bsize, ///< Number of the basis vectors (dimensionality of the lattice).
75 const size_t ndim, ///< Dimension of the space into which the lattice is embedded.
76 /// Lovász condition parameter \f$ \delta \f$.
77 /** Polynomial time complexity guaranteed for \f$\delta \in (1/4,1)\f$.
79 double delta
82 /// Generic lattice point generator type.
83 /**
84 * A bit of OOP-in-C brainfuck here.
86 * The basic principle of operation is following:
87 * Instead of a list (array) of points, an initialized PGen object
88 * is passed to a function that does something over a set of points.
89 * Each time PGen-type object is "called" (more specifically, one of
90 * the "methods" specified in the PGenClassInfo structure in @ref c,
91 * it returns PGenReturnData
92 * which contains a point in given coordinates (depending on the generator
93 * class) and some metadata.
95 * After the last generated point, the generator frees all internal memory
96 * and returns PGenSphReturnData with PGEN_NOTDONE flag unset (the rest
97 * shall be considered invalid data).
98 * The caller can also decide not to use the rest and end getting the points
99 * even when the PGEN_NOTDONE was set in the last returned data.
100 * In such case, the caller shall call PGen_destroy() manually.
102 * Methods
103 * -------
105 * The standard wrapper "methods" to generate a single point in a given
106 * coordinate system are
108 * * PGen_next_z(),
109 * * PGen_next_cart2(),
110 * * PGen_next_cart3(),
111 * * PGen_next_pol(),
112 * * PGen_next_sph().
114 * Memory management policy
115 * ------------------------
117 * The basic PGen structure shall be allocated on stack (it's only two pointers),
118 * everything internal goes on heap.
120 typedef struct PGen {
121 /// Pointer to the "class" metadata defining the behaviour of the generator.
122 const struct PGenClassInfo * /*const*/ c;
123 /// Pointer to internal state data; shall be NULL if invalid (destroyed);
124 void *stateData;
125 } PGen;
127 typedef enum PGenPointFlags {
128 /** The most important flag: when this is not set, the
129 * interation ended – other data returned should be
130 * considered nonsense and at this point, the generator
131 * should have de-allocated all internal memory.
133 PGEN_NOTDONE = 2,
134 /** Set if the r-coordinate is not different than in the
135 * previous generated point (so radial parts of the
136 * calculation have to be redone).
137 * Optional.
139 PGEN_OLD_R = 1,
140 /** Set if the r-coordinate has not changed between the
141 * first and the last point generated in the current
142 * call.
143 * Only for the bulk generator methods.
144 * Optional.
146 PGEN_SINGLE_R = 16,
147 PGEN_AT_Z = 4, ///< Set if the point(s) lie(s) at the z-axis (theta is either 0 or M_PI).
148 PGEN_AT_XY = 8, ///< Set if the point(s) lie(s) in the xy-plane (theta is M_PI2).
149 PGEN_METHOD_UNAVAILABLE = 2048, ///< Set if no suitable method exists (no point generated).
150 PGEN_DONE = 0, ///< Convenience identifier, not an actual flag.
151 PGEN_COORDS_CART1 = QPMS_COORDS_CART1,
152 PGEN_COORDS_CART2 = QPMS_COORDS_CART2,
153 PGEN_COORDS_CART3 = QPMS_COORDS_CART3,
154 PGEN_COORDS_POL = QPMS_COORDS_POL,
155 PGEN_COORDS_SPH = QPMS_COORDS_SPH,
156 PGEN_COORDS_BITRANGE = QPMS_COORDS_BITRANGE,
157 } PGenPointFlags;
160 /// Metadata generated by the fetch*() methods from PGenClassInfo
161 typedef struct PGenReturnDataBulk {
162 /// Flags describing the returned data.
163 PGenPointFlags flags;
164 size_t generated; ///< Number of points really generated
165 } PGenReturnDataBulk;
167 /// Generic PGen return type that might contain point represented in any of the supported coordinate systems.
168 typedef struct PGenReturnData {
169 PGenPointFlags flags; ///< Metadata, must contain valid coordinate system defining flags.
170 anycoord_point_t point; ///< Generated point in a coordinate system defined by flags.
171 } PGenReturnData;
173 /// PGen single-point return data type (1D).
174 typedef struct PGenZReturnData {
175 PGenPointFlags flags; ///< Medatata.
176 double point_z; ///< Generated point on a real axis.
177 } PGenZReturnData;
179 /// PGen single-point return data type (2D, polar coordinates).
180 typedef struct PGenPolReturnData {
181 PGenPointFlags flags; ///< Metadata.
182 pol_t point_pol; ///< Generated point in polar coordinates.
183 } PGenPolReturnData;
185 /// PGen single-point return data type (3D, spherical coordinates).
186 typedef struct PGenSphReturnData {
187 PGenPointFlags flags; ///< Metadata.
188 sph_t point_sph; ///< Generated point in spherical coordinates.
189 } PGenSphReturnData;
191 /// PGen single-point return data type (2D, cartesian coordinates).
192 typedef struct PGenCart2ReturnData {
193 PGenPointFlags flags; ///< Metadata.
194 cart2_t point_cart2; ///< Generated point in cartesian coordinates.
195 } PGenCart2ReturnData;
197 /// PGen single-point return data type (3D, cartesian coordinates).
198 typedef struct PGenCart3ReturnData {
199 PGenPointFlags flags; ///< Metadata.
200 cart3_t point_cart3; ///< Generated point in cartesian coordinates.
201 } PGenCart3ReturnData;
203 // convenience constants for use in the extractor implementations
204 static const PGenZReturnData PGenZDoneVal = {PGEN_DONE, 0};
205 static const PGenPolReturnData PGenPolDoneVal = {PGEN_DONE, {0,0}};
206 static const PGenSphReturnData PGenSphDoneVal = {PGEN_DONE, {0,0,0}};
207 static const PGenCart2ReturnData PGenCart2DoneVal = {PGEN_DONE, {0,0}};
208 static const PGenCart3ReturnData PGenCart3DoneVal = {PGEN_DONE, {0,0,0}};
211 /// PGen class metadata.
213 * This structure determines the behaviour of the PGen
214 * instance pointing to it.
216 * For generating a single point, use the next() method.
217 * For generating up to N points in a single call, use the
218 * fetch() method.
220 * It is strongly recommended that at least the native-coordinate
221 * fetch method and the native-coordinate next method are implemented.
223 * Usually, each generator uses internally one "native" coordinate
224 * system (in lattice generators, this will typically be nD
225 * cartesian coordinates) in which the next() method gives its result.
227 * One does not have to explicitly implement every single method.
229 * TODO doc about the default transformations etc.
231 typedef struct PGenClassInfo { // static PGenSph info
232 char * const name; // mainly for debugging purposes
233 int dimensionality; // lower-dimensional can be converted to higher-D, not vice versa; bit redundant with the following, whatever.
234 /// Info about the generator native coordinate system.
235 PGenPointFlags native_point_flags;
236 /// Generate a single point in the native coordinates.
237 PGenReturnData (*next)(struct PGen *);
238 /// Generate a single 1D point.
239 PGenZReturnData (*next_z)(struct PGen *);
240 /// Generate a single 2D point in polar coordinates.
241 PGenPolReturnData (*next_pol)(struct PGen *);
242 /// Generate a single 3D point in spherical coordinates.
243 PGenSphReturnData (*next_sph)(struct PGen *);
244 /// Generate a single 2D point in cartesian coordinates.
245 PGenCart2ReturnData (*next_cart2)(struct PGen *);
246 /// Generate a single 3D point in cartesian coordinates.
247 PGenCart3ReturnData (*next_cart3)(struct PGen *);
248 /// Generate up to \a n points in the native coordinates.
249 PGenReturnDataBulk (*fetch)(struct PGen *, size_t, anycoord_point_t *);
250 /// Generate up to \a n 1D points.
251 PGenReturnDataBulk (*fetch_z)(struct PGen *, size_t, double *);
252 /// Generate up to \a n 2D points in polar coordinates.
253 PGenReturnDataBulk (*fetch_pol)(struct PGen *, size_t, pol_t *);
254 /// Generate up to \a n 3D points in spherical coordinates.
255 PGenReturnDataBulk (*fetch_sph)(struct PGen *, size_t, sph_t *);
256 /// Generate up to \a n 2D points in cartesian coordinates.
257 PGenReturnDataBulk (*fetch_cart2)(struct PGen *, size_t, cart2_t *);
258 /// Generate up to \a n 3D points in cartesian coordinates.
259 PGenReturnDataBulk (*fetch_cart3)(struct PGen *, size_t, cart3_t *);
260 /// Destructor.
261 /** To be called by next() at iteration end, or by the caller
262 * if ending the generation prematurely
264 void (*destructor)(struct PGen *);
265 } PGenClassInfo;
267 /// Generate a point with any of the next-methods.
268 static inline PGenReturnData PGen_next_nf(struct PGen *g) {
269 if (g->c->next)
270 return g->c->next(g);
271 else {
272 PGenReturnData r;
273 if (g->c->next_z) {
274 PGenZReturnData res = g->c->next_z(g);
275 r.flags = res.flags;
276 r.point.z = res.point_z;
277 } else if (g->c->next_pol) {
278 PGenPolReturnData res = g->c->next_pol(g);
279 r.flags = res.flags;
280 r.point.pol = res.point_pol;
281 } else if (g->c->next_cart2) {
282 PGenCart2ReturnData res = g->c->next_cart2(g);
283 r.flags = res.flags;
284 r.point.cart2 = res.point_cart2;
285 } else if (g->c->next_sph) {
286 PGenSphReturnData res = g->c->next_sph(g);
287 r.flags = res.flags;
288 r.point.sph = res.point_sph;
289 } else if (g->c->next_cart3) {
290 PGenCart3ReturnData res = g->c->next_cart3(g);
291 r.flags = res.flags;
292 r.point.cart3 = res.point_cart3;
293 } else
294 r.flags = PGEN_METHOD_UNAVAILABLE;
295 return r;
299 /// Generate multiple points with PGen in any coordinate system.
300 // Ultimate ugliness
301 static inline PGenReturnDataBulk PGen_fetch_any(struct PGen *g, size_t nmemb,
302 anycoord_point_t *target) {
303 if (g->c->fetch)
304 return g->c->fetch(g, nmemb, target);
305 else if (g->c->fetch_cart3) {
306 cart3_t *t2 = (cart3_t*) ((char *) target
307 + nmemb * (sizeof(anycoord_point_t)-sizeof(cart3_t)));
308 PGenReturnDataBulk res = g->c->fetch_cart3(g, nmemb, t2);
309 for (size_t i = 0; i < nmemb; ++i)
310 target[i].cart3 = t2[i];
311 return res;
312 } else if (g->c->fetch_sph) {
313 sph_t *t2 = (sph_t*) ((char *) target
314 + nmemb * (sizeof(anycoord_point_t)-sizeof(sph_t)));
315 PGenReturnDataBulk res = g->c->fetch_sph(g, nmemb, t2);
316 for (size_t i = 0; i < nmemb; ++i)
317 target[i].sph = t2[i];
318 return res;
319 } else if (g->c->fetch_cart2) {
320 cart2_t *t2 = (cart2_t*) ((char *) target
321 + nmemb * (sizeof(anycoord_point_t)-sizeof(cart2_t)));
322 PGenReturnDataBulk res = g->c->fetch_cart2(g, nmemb, t2);
323 for (size_t i = 0; i < nmemb; ++i)
324 target[i].cart2 = t2[i];
325 return res;
326 } else if (g->c->fetch_pol) {
327 pol_t *t2 = (pol_t*) ((char *) target
328 + nmemb * (sizeof(anycoord_point_t)-sizeof(pol_t)));
329 PGenReturnDataBulk res = g->c->fetch_pol(g, nmemb, t2);
330 for (size_t i = 0; i < nmemb; ++i)
331 target[i].pol = t2[i];
332 return res;
333 } else if (g->c->fetch_z) {
334 double *t2 = (double*) ((char *) target
335 + nmemb * (sizeof(anycoord_point_t)-sizeof(double)));
336 PGenReturnDataBulk res = g->c->fetch_z(g, nmemb, t2);
337 for (size_t i = 0; i < nmemb; ++i)
338 target[i].z = t2[i];
339 return res;
340 } else {
341 // This is ridiculously inefficient
342 PGenReturnDataBulk res = {PGEN_NOTDONE, 0};
343 for (res.generated = 0; res.generated < nmemb;
344 ++res.generated) {
345 PGenReturnData res1 = PGen_next_nf(g);
346 QPMS_ENSURE(!(res1.flags & PGEN_METHOD_UNAVAILABLE),
347 "No method found to generate points. The PGenClassInfo"
348 " %s is apparently broken.", g->c->name);
349 if (res1.flags & PGEN_NOTDONE) {
350 target[res.generated] = res1.point;
351 // The coordinate system generated by next() must be consistent:
352 assert(!res.generated || ((res1.flags & PGEN_COORDS_BITRANGE) == (res.flags & PGEN_COORDS_BITRANGE)));
353 res.flags |= res1.flags & PGEN_COORDS_BITRANGE;
354 } else {
355 res.flags &= ~PGEN_NOTDONE;
356 break;
359 // Do not guarantee anything for; low priority TODO
360 res.flags &= ~(PGEN_OLD_R & PGEN_SINGLE_R);
361 return res;
365 /// Generate a point with any of the next-methods or fetch-methods.
366 static inline PGenReturnData PGen_next(struct PGen *g) {
367 PGenReturnData res = PGen_next_nf(g);
368 if (!(res.flags & PGEN_METHOD_UNAVAILABLE))
369 return res;
370 else { // Slow if implementation is stupid, but short!
371 PGenReturnDataBulk resb = PGen_fetch_any(g, 1, &res.point);
372 if (resb.generated)
373 // the | PGEN_NOTDONE may not be needed, but my brain melted
374 res.flags = resb.flags | PGEN_NOTDONE;
375 else
376 res.flags = PGEN_DONE;
377 return res;
381 /// Generate multiple points in spherical coordinates.
382 static inline PGenReturnDataBulk PGen_fetch_sph(struct PGen *g,
383 size_t nmemb, sph_t *target) {
384 if (g->c->fetch_sph)
385 return g->c->fetch_sph(g, nmemb, target);
386 else {
387 anycoord_point_t *tmp;
388 QPMS_CRASHING_MALLOC(tmp, sizeof(anycoord_point_t) * nmemb);
389 PGenReturnDataBulk res = PGen_fetch_any(g, nmemb, tmp);
390 anycoord_arr2something(target, QPMS_COORDS_SPH,
391 tmp, res.flags, res.generated);
392 free(tmp);
393 res.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
394 | QPMS_COORDS_SPH;
395 return res;
399 /// Generate multiple points in 3D cartesian coordinates.
400 static inline PGenReturnDataBulk PGen_fetch_cart3(struct PGen *g,
401 size_t nmemb, cart3_t *target) {
402 if (g->c->fetch_cart3)
403 return g->c->fetch_cart3(g, nmemb, target);
404 else {
405 anycoord_point_t *tmp;
406 QPMS_CRASHING_MALLOC(tmp, sizeof(anycoord_point_t) * nmemb);
407 PGenReturnDataBulk res = PGen_fetch_any(g, nmemb, tmp);
408 anycoord_arr2something(target, QPMS_COORDS_CART3,
409 tmp, res.flags, res.generated);
410 free(tmp);
411 res.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
412 | QPMS_COORDS_CART3;
413 return res;
417 /// Generate multiple points in polar coordinates.
418 static inline PGenReturnDataBulk PGen_fetch_pol(struct PGen *g,
419 size_t nmemb, pol_t *target) {
420 if (g->c->fetch_pol)
421 return g->c->fetch_pol(g, nmemb, target);
422 else {
423 anycoord_point_t *tmp;
424 QPMS_CRASHING_MALLOC(tmp, sizeof(anycoord_point_t) * nmemb);
425 PGenReturnDataBulk res = PGen_fetch_any(g, nmemb, tmp);
426 anycoord_arr2something(target, QPMS_COORDS_POL,
427 tmp, res.flags, res.generated);
428 free(tmp);
429 res.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
430 | QPMS_COORDS_POL;
431 return res;
435 /// Generate multiple points in 2D cartesian coordinates.
436 static inline PGenReturnDataBulk PGen_fetch_cart2(struct PGen *g,
437 size_t nmemb, cart2_t *target) {
438 if (g->c->fetch_cart2)
439 return g->c->fetch_cart2(g, nmemb, target);
440 else {
441 anycoord_point_t *tmp;
442 QPMS_CRASHING_MALLOC(tmp, sizeof(anycoord_point_t) * nmemb);
443 PGenReturnDataBulk res = PGen_fetch_any(g, nmemb, tmp);
444 anycoord_arr2something(target, QPMS_COORDS_CART2,
445 tmp, res.flags, res.generated);
446 free(tmp);
447 res.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
448 | QPMS_COORDS_CART2;
449 return res;
453 /// Generate multiple points in 1D cartesian coordinates.
454 static inline PGenReturnDataBulk PGen_fetch_z(struct PGen *g,
455 size_t nmemb, double *target) {
456 if (g->c->fetch_z)
457 return g->c->fetch_z(g, nmemb, target);
458 else {
459 anycoord_point_t *tmp;
460 QPMS_CRASHING_MALLOC(tmp, sizeof(anycoord_point_t) * nmemb);
461 PGenReturnDataBulk res = PGen_fetch_any(g, nmemb, tmp);
462 anycoord_arr2something(target, QPMS_COORDS_CART1,
463 tmp, res.flags, res.generated);
464 free(tmp);
465 res.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
466 | QPMS_COORDS_CART1;
467 return res;
471 /// Deallocate and invalidate a PGen point generator.
472 static inline void PGen_destroy(PGen *g) {
473 g->c->destructor(g);
474 assert(g->stateData == NULL); // this should be done by the destructor
477 /// Generate a point in a 1D real space.
478 static inline PGenZReturnData PGen_next_z(PGen *g) {
479 if (g->c->next_z)
480 return g->c->next_z(g);
481 else { // Super-slow generic fallback.
482 PGenReturnData res = PGen_next(g);
483 if (res.flags & PGEN_NOTDONE) {
484 PGenZReturnData r;
485 r.point_z = anycoord2cart1(res.point, res.flags);
486 r.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
487 | QPMS_COORDS_CART1;
488 return r;
489 } else
490 return PGenZDoneVal;
494 /// Generate a point in a 3D real space (spherical coordinates).
495 static inline PGenSphReturnData PGen_next_sph(PGen *g) {
496 if (g->c->next_sph)
497 return g->c->next_sph(g);
498 else { // Super-slow generic fallback.
499 PGenReturnData res = PGen_next(g);
500 if (res.flags & PGEN_NOTDONE) {
501 PGenSphReturnData r;
502 r.point_sph = anycoord2sph(res.point, res.flags);
503 r.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
504 | QPMS_COORDS_SPH;
505 return r;
506 } else
507 return PGenSphDoneVal;
511 /// Generate a point in a 2D real space (polar coordinates).
512 static inline PGenPolReturnData PGen_next_pol(PGen *g) {
513 if (g->c->next_pol)
514 return g->c->next_pol(g);
515 else { // Super-slow generic fallback.
516 PGenReturnData res = PGen_next(g);
517 if (res.flags & PGEN_NOTDONE) {
518 PGenPolReturnData r;
519 r.point_pol = anycoord2pol(res.point, res.flags);
520 r.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
521 | QPMS_COORDS_POL;
522 return r;
523 } else
524 return PGenPolDoneVal;
528 /// Generate a point in a 3D real space (cartesian coordinates).
529 static inline PGenCart3ReturnData PGen_next_cart3(PGen *g) {
530 if (g->c->next_cart3)
531 return g->c->next_cart3(g);
532 else { // Super-slow generic fallback.
533 PGenReturnData res = PGen_next(g);
534 if (res.flags & PGEN_NOTDONE) {
535 PGenCart3ReturnData r;
536 r.point_cart3 = anycoord2cart3(res.point, res.flags);
537 r.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
538 | QPMS_COORDS_CART3;
539 return r;
540 } else
541 return PGenCart3DoneVal;
545 /// Generate a point in a 2D real space (cartesian coordinates).
546 static inline PGenCart2ReturnData PGen_next_cart2(PGen *g) {
547 if (g->c->next_cart2)
548 return g->c->next_cart2(g);
549 else { // Super-slow generic fallback.
550 PGenReturnData res = PGen_next(g);
551 if (res.flags & PGEN_NOTDONE) {
552 PGenCart2ReturnData r;
553 r.point_cart2 = anycoord2cart2(res.point, res.flags);
554 r.flags = (res.flags & ~QPMS_COORDS_BITRANGE)
555 | QPMS_COORDS_CART2;
556 return r;
557 } else
558 return PGenCart2DoneVal;
562 #if 0
563 /// Generate up to \a n points.
564 static inline PGenReturnDataBulk PGen_fetch(PGen *g, size_t n, anycoord_point_t *arr){
565 if (g->c->fetch)
566 return g->c->fetch(g, n, arr);
567 else abort();
569 #endif
571 static inline bool PGenSph_notDone(PGenSphReturnData data) {
572 return data.flags & PGEN_NOTDONE ? true : false;
574 static inline bool PGenCart3_notDone(PGenCart3ReturnData data) {
575 return data.flags & PGEN_NOTDONE ? true : false;
578 /// Standard PGen spherical coordinates -> 3d cartesian convertor.
579 static inline PGenCart3ReturnData PGenReturnDataConv_sph_cart3(PGenSphReturnData sphdata){
580 PGenCart3ReturnData c3data;
581 c3data.flags = sphdata.flags;
582 c3data.point_cart3 = sph2cart(sphdata.point_sph);
583 return c3data;
586 /// Standard PGen 3d cartesian -> spherical coordinates convertor.
587 static inline PGenSphReturnData PGenReturnDataConv_cart3_sph(PGenCart3ReturnData c){
588 PGenSphReturnData s;
589 s.flags = c.flags;
590 s.point_sph = cart2sph(c.point_cart3);
591 return s;
595 * Some basic lattice generators implementing the abstract interface above (implemented in latticegens.c).
598 /// 2D point generator that simply iterates over an existing array of Point2d.
599 extern const PGenClassInfo PGen_FromPoint2DArray; // TODO Do I even need this to be declared here?
600 /// PGen_FromPoint2DArray constructor.
601 PGen PGen_FromPoints2DArray_new(const point2d *points, size_t len);
603 /// 1D equidistant point generator.
604 extern const PGenClassInfo PGen_1D;
605 typedef enum PGen_1D_incrementDirection{
606 //PGEN_1D_POSITIVE_INC, // not implemented
607 //PGEN_1D_NEGATIVE_INC, // not implemented
608 PGEN_1D_INC_FROM_ORIGIN,
609 PGEN_1D_INC_TOWARDS_ORIGIN
610 } PGen_1D_incrementDirection;
611 /// PGen_1D point generator constructor.
612 PGen PGen_1D_new_minMaxR(double period, ///< Distance between points.
613 double offset, ///< Lattice offset from zero.
614 double minR, ///< Lower bound of |z| of the generated points.
615 bool inc_minR, ///< Include also |z| == minR (if applicable).
616 double maxR, ///< Upper bound of |z| of the generated points.
617 bool inc_maxR, ///< Include also |z| == maxR if applicable.
618 PGen_1D_incrementDirection incdir ///< Order of generated points.
621 extern const PGenClassInfo PGen_xyWeb;
622 PGen PGen_xyWeb_new(cart2_t b1, cart2_t b2, double rtol, cart2_t offset,
623 double minR, bool inc_minR, double maxR, bool inc_maxR);
625 /// Returns a number larger or equal than the number of all the points generated by a PGen_xyWeb.
626 size_t PGen_xyWeb_sizecap(cart2_t b1, cart2_t b2, double rtol, cart2_t offset,
627 double minR, bool inc_minR, double maxR, bool inc_maxR);
630 extern const PGenClassInfo PGen_LatticeRadialHeap2D;
631 extern const PGenClassInfo PGen_LatticeRadialHeap3D;
632 PGen PGen_LatticeRadialHeap2D_new(cart2_t b1, cart2_t b2, cart2_t offset,
633 double minR, bool inc_minR, double maxR, bool inc_maxR);
634 PGen PGen_LatticeRadialHeap3D_new(const cart3_t *b1, const cart3_t *b2, const cart3_t *b3,
635 const cart3_t *offset, double minR, bool inc_minR, double maxR, bool inc_maxR);
638 /// A metagenerator generating points from another generator shifted by a constant.
639 extern const PGenClassInfo PGen_shifted;
640 PGen PGen_shifted_new(PGen orig, cart3_t shift);
643 * THE NICE PART (adaptation of lattices2d.py)
644 * ===========================================
646 * all the functions are prefixed with l2d_
647 * convention for argument order: inputs, *outputs, add. params
650 #define BASIS_RTOL 1e-13
652 // Bravais lattice types
653 typedef enum {
654 OBLIQUE = 1,
655 RECTANGULAR = 2,
656 SQUARE = 4,
657 RHOMBIC = 5,
658 EQUILATERAL_TRIANGULAR = 3,
659 RIGHT_ISOSCELES=SQUARE,
660 PARALLELOGRAMMIC=OBLIQUE,
661 CENTERED_RHOMBIC=RECTANGULAR,
662 RIGHT_TRIANGULAR=RECTANGULAR,
663 CENTERED_RECTANGULAR=RHOMBIC,
664 ISOSCELE_TRIANGULAR=RHOMBIC,
665 RIGHT_ISOSCELE_TRIANGULAR=SQUARE,
666 HEXAGONAL=EQUILATERAL_TRIANGULAR
667 } LatticeType2;
669 #if 0
670 // Wallpaper groups
671 typedef enum {
672 TODO
673 } SpaceGroup2;
674 #endif
676 // Just for detecting the right angles (needed for generators).
677 typedef enum {
678 NOT_ORTHOGONAL = 0,
679 ORTHOGONAL_01 = 1,
680 ORTHOGONAL_12 = 2,
681 ORTHOGONAL_02 = 4
682 } LatticeFlags;
687 * Lagrange-Gauss reduction of a 2D basis.
688 * The output shall satisfy |out1| <= |out2| <= |out2 - out1|
690 void l2d_reduceBasis(cart2_t in1, cart2_t in2, cart2_t *out1, cart2_t *out2);
692 // This one uses LLL reduction.
693 void l3d_reduceBasis(const cart3_t in[3], cart3_t out[3]);
696 * This gives the "ordered shortest triple" of base vectors (each pair from the triple
697 * is a base) and there may not be obtuse angle between o1, o2 and between o2, o3
699 void l2d_shortestBase3(cart2_t i1, cart2_t i2, cart2_t *o1, cart2_t *o2, cart2_t *o3);
702 * TODO doc
703 * return value is 4 or 6.
705 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);
706 // variant
707 int l2d_shortestBase46_arr(cart2_t i1, cart2_t i2, cart2_t *oarr, double rtol);
709 // Determines whether angle between inputs is obtuse
710 bool l2d_is_obtuse_r(cart2_t i1, cart2_t i2, double rtol);
711 bool l2d_is_obtuse(cart2_t i1, cart2_t i2);
714 * Given two basis vectors, returns 2D Bravais lattice type.
716 LatticeType2 l2d_classifyLattice(cart2_t b1, cart2_t b2, double rtol);
718 // Detects right angles.
719 LatticeFlags l2d_detectRightAngles(cart2_t b1, cart2_t b2, double rtol);
720 LatticeFlags l3d_detectRightAngles(const cart3_t basis[3], double rtol);
722 // Other functions in lattices2d.py: TODO?
723 // range2D()
724 // generateLattice()
725 // generateLatticeDisk()
726 // cutWS()
727 // filledWS()
728 // change_basis()
731 * Given basis vectors, returns the corners of the Wigner-Seits unit cell (W1, W2, -W1, W2)
732 * for rectangular and square lattice or (w1, w2, w3, -w1, -w2, -w3) otherwise.
734 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);
735 // variant
736 int l2d_cellCornersWS_arr(cart2_t i1, cart2_t i2, cart2_t *oarr, double rtol);
738 // Reciprocal bases; returns 0 on success, possibly a non-zero if b1 and b2 are parallel
739 int l2d_reciprocalBasis1(cart2_t b1, cart2_t b2, cart2_t *rb1, cart2_t *rb2);
740 int l2d_reciprocalBasis2pi(cart2_t b1, cart2_t b2, cart2_t *rb1, cart2_t *rb2);
741 // 3D reciprocal bases; returns (direct) unit cell volume with possible sign. Assumes direct lattice basis already reduced.
742 double l3d_reciprocalBasis1(const cart3_t direct_basis[3], cart3_t reciprocal_basis[3]);
743 double l3d_reciprocalBasis2pi(const cart3_t direct_basis[3], cart3_t reciprocal_basis[3]);
745 double l2d_unitcell_area(cart2_t b1, cart2_t b2);
747 // returns the radius of inscribed circle of a hexagon (or rectangle/square if applicable) created by the shortest base triple
748 double l2d_hexWebInCircleRadius(cart2_t b1, cart2_t b2);
751 * THE MORE OR LESS OK PART
752 * ========================
756 * General set of points ordered by the r-coordinate.
757 * Typically, this will include all lattice inside a certain circle.
758 * This structure is internally used by the "lattice generators" below.
759 * It does not have its memory management of its own, as it is handled
760 * by the "generators". For everything except the generators,
761 * this structure shall be read-only.
763 typedef struct {
764 size_t nrs; // number of different radii
765 double *rs; // the radii; of length nrs (largest contained radius == rs[nrs-1])
766 point2d *base;
767 ptrdiff_t *r_offsets; // of length nrs+1 (using relative offsets due to possible realloc's)
768 // the jth point of i-th radius is base[r_offsets[i]+j] or using the inline below..
769 /* // redundand (therefore removed) members
770 * point2d *points; // redundant as it is the same as points_at_r[0]
771 * size_t npoints; // redundant as it is the same as points_at_r[nrs]-points_at_r[0]
773 } points2d_rordered_t;
776 // sorts arbitrary points and creates points2d_rordered_t
777 points2d_rordered_t *points2d_rordered_frompoints(const point2d *orig_base,
778 size_t nmemb, double rtol, double atol);
780 // returns a copy but shifted by a constant (actually in a stupid way, but whatever)
781 points2d_rordered_t *points2d_rordered_shift(const points2d_rordered_t *orig,
782 point2d shift, double rtol, double atol);
784 // returns a copy but scaled by a factor
785 points2d_rordered_t *points2d_rordered_scale(const points2d_rordered_t *orig,
786 double factor);
789 /* The destructor: use only for results of
790 * - points2D_rordered_frompoints,
791 * - points2d_rordered_shift,
792 * - points2d_rordered_scale.
794 void points2d_rordered_free(points2d_rordered_t *);
796 static inline point2d points2d_rordered_get_point(const points2d_rordered_t *ps, int r_order, int i) {
797 assert(i >= 0);
798 assert(r_order < ps->nrs);
799 assert(i < (ps->r_offsets[r_order+1] - ps->r_offsets[r_order]));
800 return ps->base[ps->r_offsets[r_order] + i];
803 static inline double points2d_rordered_get_r(const points2d_rordered_t *ps, int r_order) {
804 assert(r_order < ps->nrs);
805 return ps->rs[r_order];
809 ptrdiff_t points2d_rordered_locate_r(const points2d_rordered_t *, double r);
811 // returns a "view" (does not copy any of the arrays)
812 // -- DO NOT FREE orig BEFORE THE END OF SCOPE OF THE RESULT
813 points2d_rordered_t points2d_rordered_annulus(const points2d_rordered_t *orig, double minr, bool minr_inc,
814 double maxr, bool maxr_inc);
817 #if 0
818 /// Gives the frequency of \a n-th empty lattice mode at a given wave vector \a k.
819 double qpms_emptylattice2_mode_nth(
820 cart2_t b1_rec, ///< First reciprocal lattice base vector
821 cart2_t b2_rec, ///< Second reciprocal lattice base vector
822 double rtol, ///< Relative tolerance to detect right angles
823 cart2_t k, ///< The wave vector
824 double wave_speed, ///< Wave speed in a given medium (i.e. vacuum speed / refractive index).
825 size_t N ///< Index of the mode (note that degenerate modes are counted multiple times).
828 /// Gives the first `maxindex` frequencies of empty lattice modes at a given wave vector \a k.
829 void qpms_emptylattice2_modes_maxindex(
830 double target_freqs[], ///< Target array of size maxindex.
831 cart2_t b1_rec, ///< First reciprocal lattice base vector
832 cart2_t b2_rec, ///< Second reciprocal lattice base vector
833 double rtol, ///< Relative tolerance to detect right angles
834 cart2_t k, ///< The wave vector
835 double wave_speed, ///< Wave speed in a given medium (i.e. vacuum speed / refractive index).
836 size_t maxindex ///< Number of the frequencies generated.
838 #endif
840 /// Gives the frequencies of empty lattice modes at a given wave vector \a k up to \a maxfreq and one more.
842 * The frequencies are saved to a newly allocated array *target_freqs (to be deallocated
843 * using free() by the caller).
845 * \returns Number of found mode frequencies lower or equal than \a maxfreq plus one.
847 size_t qpms_emptylattice2_modes_maxfreq(
848 double **target_freqs,
849 cart2_t b1_rec, ///< First reciprocal lattice base vector
850 cart2_t b2_rec, ///< Second reciprocal lattice base vector
851 double rtol, ///< Relative tolerance to detect right angles
852 cart2_t k, ///< The wave vector
853 double wave_speed, ///< Wave speed in a given medium (i.e. vacuum speed / refractive index).
854 double maxfreq ///< The maximum frequency.
857 /// Gives the frequencies of two empty lattice modes nearest to \a omega at a given wave vector \a k.
858 void qpms_emptylattice2_modes_nearest(
859 double target[2], ///< Target array with lower ([0]) and upper ([1]) frequency.
860 cart2_t b1_rec, ///< First reciprocal lattice base vector
861 cart2_t b2_rec, ///< Second reciprocal lattice base vector
862 double rtol, ///< Relative tolerance to detect right angles
863 cart2_t k, ///< The wave vector
864 double wave_speed, ///< Wave speed in a given medium (i.e. vacuum speed / refractive index).
865 double omega ///< The frequency around which the frequencies are searched.
871 * THE UGLY PART
872 * =============
876 * EQUILATERAL TRIANGULAR LATTICE
879 typedef enum {
880 TRIANGULAR_VERTICAL, // there is a lattice base vector parallel to the y-axis
881 TRIANGULAR_HORIZONTAL // there is a lattice base vector parallel to the x-axis
882 } TriangularLatticeOrientation;
884 static inline TriangularLatticeOrientation reverseTriangularLatticeOrientation(TriangularLatticeOrientation o){
885 switch(o) {
886 case TRIANGULAR_VERTICAL:
887 return TRIANGULAR_HORIZONTAL;
888 break;
889 case TRIANGULAR_HORIZONTAL:
890 return TRIANGULAR_VERTICAL;
891 break;
892 default:
893 abort();
895 abort();
898 // implementation data structures; not needed in the header file
899 typedef struct triangular_lattice_gen_privstuff_t triangular_lattice_gen_privstuff_t;
901 typedef struct {
902 // public:
903 points2d_rordered_t ps;
904 TriangularLatticeOrientation orientation;
905 double a; // lattice vector length
907 // not sure if needed:
908 bool includes_origin;
910 // Denotes an offset of the "origin" point; meaning step hexshift * a / sqrt(2) upwards
911 // or leftwards for the horizontal or vertical orientations, respectively.
912 int hexshift;
914 // private:
915 triangular_lattice_gen_privstuff_t *priv;
917 } triangular_lattice_gen_t;
919 triangular_lattice_gen_t *triangular_lattice_gen_init(double a, TriangularLatticeOrientation ori, bool include_origin,
920 int halfoffset);
921 const points2d_rordered_t * triangular_lattice_gen_getpoints(const triangular_lattice_gen_t *g);
922 int triangular_lattice_gen_extend_to_r(triangular_lattice_gen_t *g, double r);
923 int triangular_lattice_gen_extend_to_steps(triangular_lattice_gen_t *g, int maxsteps);
924 void triangular_lattice_gen_free(triangular_lattice_gen_t *g);
928 * HONEYCOMB LATTICE
931 typedef struct {
932 // public:
933 points2d_rordered_t ps;
934 TriangularLatticeOrientation orientation;
935 double a;
936 double h;
938 // private:
939 triangular_lattice_gen_t *tg;
940 } honeycomb_lattice_gen_t;
942 honeycomb_lattice_gen_t *honeycomb_lattice_gen_init_h(double h, TriangularLatticeOrientation ori);
943 honeycomb_lattice_gen_t *honeycomb_lattice_gen_init_a(double a, TriangularLatticeOrientation ori);
944 int honeycomb_lattice_gen_extend_to_steps(honeycomb_lattice_gen_t *g, int maxsteps);
945 int honeycomb_lattice_gen_extend_to_r(honeycomb_lattice_gen_t *g, double r);
946 void honeycomb_lattice_gen_free(honeycomb_lattice_gen_t *g);
948 #endif // LATTICES_H