Disable "hard" examples in CI
[qpms.git] / qpms / pointgroups.c
blob0125655edf5f9c6d3edb72c57dfb4c7c093a6e9b
1 #include "pointgroups.h"
2 #include <search.h>
3 #include <stdlib.h>
4 #include <assert.h>
6 double qpms_pg_quat_cmp_atol = QPMS_QUAT_ATOL;
8 #define PAIRCMP(a, b) {\
9 if ((a) < (b)) return -1;\
10 if ((a) > (b)) return 1;\
13 #define PAIRCMP_ATOL(a, b, atol) {\
14 if ((a) < (b) + (atol)) return -1;\
15 if ((a) + (atol) > (b)) return 1;\
18 int qpms_pg_irot3_approx_cmp(const qpms_irot3_t *p1,
19 const qpms_irot3_t *p2, double atol) {
20 assert(atol >= 0);
21 PAIRCMP(p1->det, p2->det);
22 const qpms_quat_t r1 = qpms_quat_standardise(p1->rot, atol),
23 r2 = qpms_quat_standardise(p2->rot, atol);
24 PAIRCMP_ATOL(creal(r1.a), creal(r2.a), atol);
25 PAIRCMP_ATOL(cimag(r1.a), cimag(r2.a), atol);
26 PAIRCMP_ATOL(creal(r1.b), creal(r2.b), atol);
27 PAIRCMP_ATOL(cimag(r1.b), cimag(r2.b), atol);
28 return 0;
31 int qpms_pg_irot3_approx_cmp_v(const void *av, const void *bv) {
32 const qpms_irot3_t *a = av, *b = bv;
33 return qpms_pg_irot3_approx_cmp(a, b, qpms_pg_quat_cmp_atol);
37 /// Generates the canonical elements of a given 3D point group type.
38 qpms_irot3_t *qpms_pg_canonical_elems(qpms_irot3_t *target,
39 qpms_pointgroup_class cls, const qpms_gmi_t then) {
40 QPMS_UNTESTED;
41 const qpms_gmi_t order = qpms_pg_order(cls, then);
42 QPMS_ENSURE(order, "Cannot generate an infinite group!");
43 if (!target) QPMS_CRASHING_MALLOC(target, (1+order) * sizeof(qpms_irot3_t));
44 target[0] = QPMS_IROT3_IDENTITY;
45 qpms_gmi_t ngen = qpms_pg_genset_size(cls, then);
46 qpms_irot3_t gens[ngen];
47 (void) qpms_pg_genset(cls, then, gens);
49 // Let's try it with a binary search tree, as an exercise :)
50 void *root = NULL;
51 // put the starting element (identity) to the tree
52 (void) tsearch((void *) target, &root, qpms_pg_irot3_approx_cmp_v);
53 qpms_gmi_t n = 1; // No. of generated elements.
55 // And let's do the DFS without recursion; the "stack size" here (=order) might be excessive, but whatever
56 qpms_gmi_t gistack[order], //< generator indices (related to gens[])
57 srcstack[order], //< pre-image indices (related to target[])
58 si = 0; //< stack index
59 gistack[0] = 0;
60 srcstack[0] = 0;
62 while (si >= 0) { // DFS
63 if (gistack[si] < ngen) { // are there generators left at this level? If so, try another elem
64 if (n > order) QPMS_WTF; // TODO some error message
65 target[n] = qpms_irot3_mult(gens[gistack[si]], target[srcstack[si]]);
66 if (tfind((void *) &(target[n]), &root, qpms_pg_irot3_approx_cmp_v))
67 // elem found, try it with another gen in the next iteration
68 gistack[si]++;
69 else {
70 // elem not found, add it to the tree and proceed to next level
71 (void) tsearch( &(target[n]), &root, qpms_pg_irot3_approx_cmp_v);
72 ++si;
73 gistack[si] = 0;
74 srcstack[si] = n;
75 ++n;
77 } else { // no generators left at this level, get to the previous level
78 --si;
79 if (si >= 0) ++gistack[si];
83 QPMS_ENSURE(n == order, "Point group generation failure "
84 "(assumed group order = %d, got %d; qpms_pg_quat_cmp_atol = %g)",
85 order, n, qpms_pg_quat_cmp_atol);
87 while(root) tdelete(*(qpms_irot3_t **)root, &root, qpms_pg_irot3_approx_cmp_v); // I hope this is the correct way.
89 return target;
92 qpms_irot3_t *qpms_pg_elems(qpms_irot3_t *target, qpms_pointgroup_t g) {
93 QPMS_UNTESTED;
94 target = qpms_pg_canonical_elems(target, g.c, g.n);
95 qpms_gmi_t order = qpms_pg_order(g.c, g.n);
96 const qpms_irot3_t o = g.orientation, o_inv = qpms_irot3_inv(o);
97 for(qpms_gmi_t i = 0 ; i < order; ++i)
98 target[i] = qpms_irot3_mult(o_inv, qpms_irot3_mult(target[i], o));
99 return target;
102 _Bool qpms_pg_is_subgroup(qpms_pointgroup_t small, qpms_pointgroup_t big) {
103 QPMS_UNTESTED;
104 qpms_gmi_t order_big = qpms_pg_order(big.c, big.n);
105 qpms_gmi_t order_small = qpms_pg_order(small.c, small.n);
106 if (!order_big || !order_small)
107 QPMS_NOT_IMPLEMENTED("Subgroup testing for infinite groups not implemented");
108 if (order_big < order_small) return false;
109 // TODO maybe some other fast-track negative decisions
111 qpms_irot3_t *elems_small = qpms_pg_elems(NULL, small);
112 qpms_irot3_t *elems_big = qpms_pg_elems(NULL, small);
113 qsort(elems_big, order_big, sizeof(qpms_irot3_t), qpms_pg_irot3_approx_cmp_v);
115 for(qpms_gmi_t smalli = 0; smalli < order_small; ++smalli) {
116 qpms_irot3_t *match = bsearch(&elems_small[smalli], elems_big, order_big,
117 sizeof(qpms_irot3_t), qpms_pg_irot3_approx_cmp_v);
118 if (!match) return false;
121 return true;
124 /// Returns the order of a given 3D point group type.
125 /** For infinite groups returns 0. */
126 qpms_gmi_t qpms_pg_order(qpms_pointgroup_class cls, ///< Point group class.
127 qpms_gmi_t n ///< Number of rotations around main axis (only for finite axial groups).
129 if (qpms_pg_is_finite_axial(cls))
130 QPMS_ENSURE(n > 0, "n must be at least 1 for finite axial groups");
131 switch(cls) {
132 // Axial groups
133 case QPMS_PGS_CN:
134 return n;
135 case QPMS_PGS_S2N:
136 case QPMS_PGS_CNH:
137 case QPMS_PGS_CNV:
138 case QPMS_PGS_DN:
139 return 2*n;
140 case QPMS_PGS_DND:
141 case QPMS_PGS_DNH:
142 return 4*n;
144 // Remaining polyhedral groups
145 case QPMS_PGS_T:
146 return 12;
147 case QPMS_PGS_TD:
148 case QPMS_PGS_TH:
149 case QPMS_PGS_O:
150 return 24;
151 case QPMS_PGS_OH:
152 return 48;
153 case QPMS_PGS_I:
154 return 60;
155 case QPMS_PGS_IH:
156 return 120;
158 // Continuous axial groups
159 case QPMS_PGS_CINF:
160 case QPMS_PGS_CINFH:
161 case QPMS_PGS_CINFV:
162 case QPMS_PGS_DINF:
163 case QPMS_PGS_DINFH:
165 // Remaining continuous groups
166 case QPMS_PGS_SO3:
167 case QPMS_PGS_O3:
168 return 0; // 0 is infinity :-)
169 default:
170 QPMS_WTF;
175 /// Returns the number of canonical generators of a given 3D point group type.
176 /** TODO what does it do for infinite (Lie) groups? */
177 qpms_gmi_t qpms_pg_genset_size(qpms_pointgroup_class cls, ///< Point group class.
178 qpms_gmi_t n ///< Number of rotations around main axis (only for axial groups).
180 if (qpms_pg_is_finite_axial(cls)) {
181 QPMS_ENSURE(n > 0, "n must be at least 1 for finite axial groups");
182 // n = 1 needs special care:
183 if (n==1)
184 switch(cls) {
185 case QPMS_PGS_CN: return 0; // triv.
186 case QPMS_PGS_S2N: return 1; // Z_2
187 case QPMS_PGS_CNH: return 1; // Dih_1
188 case QPMS_PGS_CNV: return 1; // Dih_1
189 case QPMS_PGS_DN: return 1; // Dih_1
190 case QPMS_PGS_DND: return 2; // Dih_2
191 case QPMS_PGS_DNH: return 2; // Dih_1 x Dih_1
192 default: QPMS_WTF;
196 switch(cls) {
197 // Axial groups
198 case QPMS_PGS_CN: return 1; // Z_n
199 case QPMS_PGS_S2N: return 1; // Z_{2n}
200 case QPMS_PGS_CNH: return 2; // Z_n x Dih_1
201 case QPMS_PGS_CNV: return 2; // Dih_n
202 case QPMS_PGS_DN: return 2; // Dih_n
203 case QPMS_PGS_DND: return 2; // Dih_2n
204 case QPMS_PGS_DNH: return 3; // Dih_n x Dih_1
206 // Remaining polyhedral groups
207 case QPMS_PGS_T: // return ???; // A_4
208 case QPMS_PGS_TD: // return 2; // S_4
209 case QPMS_PGS_TH: // A_4 x Z_2
210 case QPMS_PGS_O: // S_4
211 case QPMS_PGS_OH: // return 3; // S_4 x Z_2
212 case QPMS_PGS_I: // A_5
213 case QPMS_PGS_IH: // A_5 x Z_2
215 // Continuous axial groups
216 case QPMS_PGS_CINF:
217 case QPMS_PGS_CINFH:
218 case QPMS_PGS_CINFV:
219 case QPMS_PGS_DINF:
220 case QPMS_PGS_DINFH:
222 // Remaining continuous groups
223 case QPMS_PGS_SO3:
224 case QPMS_PGS_O3:
225 QPMS_NOT_IMPLEMENTED("Not yet implemented for this point group class.");
226 default:
227 QPMS_WTF;
231 /// Fills an array of canonical generators of a given 3D point group type.
232 /** TODO what does it do for infinite (Lie) groups? */
233 qpms_gmi_t qpms_pg_genset(qpms_pointgroup_class cls, ///< Point group class.
234 qpms_gmi_t n, ///< Number of rotations around main axis (only for axial groups).
235 qpms_irot3_t gen[] ///< Target generator array
237 if (qpms_pg_is_finite_axial(cls)) {
238 QPMS_ENSURE(n > 0, "n must be at least 1 for finite axial groups");
239 // n = 1 needs special care:
240 if (n==1)
241 switch(cls) {
242 case QPMS_PGS_CN:
243 return 0; // triv.
244 case QPMS_PGS_S2N:
245 gen[0] = QPMS_IROT3_INVERSION;
246 return 1; // Z_2
247 case QPMS_PGS_CNH:
248 gen[0] = QPMS_IROT3_ZFLIP;
249 return 1; // Dih_1
250 case QPMS_PGS_CNV:
251 gen[0] = QPMS_IROT3_XFLIP;
252 return 1; // Dih_1
253 case QPMS_PGS_DN:
254 gen[0] = QPMS_IROT3_XROT_PI; // CHECKME
255 return 1; // Dih_1
256 case QPMS_PGS_DND:
257 gen[0] = QPMS_IROT3_INVERSION;
258 gen[1] = QPMS_IROT3_XFLIP;
259 return 2; // Dih_2
260 case QPMS_PGS_DNH: // CHECKME
261 gen[0] = QPMS_IROT3_ZFLIP;
262 gen[1] = QPMS_IROT3_XFLIP;
263 return 2; // Dih_1 x Dih_1
264 default: QPMS_WTF;
268 switch(cls) {
269 // Axial groups
270 case QPMS_PGS_CN:
271 gen[0] = qpms_irot3_zrot_Nk(n, 1);
272 return 1; // Z_n
273 case QPMS_PGS_S2N:
274 gen[0].rot = qpms_quat_zrot_Nk(2*n, 1);
275 gen[0].det = -1;
276 return 1; // Z_{2n}
277 case QPMS_PGS_CNH:
278 gen[0] = qpms_irot3_zrot_Nk(n, 1);
279 gen[1] = QPMS_IROT3_ZFLIP;
280 return 2; // Z_n x Dih_1
281 case QPMS_PGS_CNV:
282 gen[0] = qpms_irot3_zrot_Nk(n, 1);
283 gen[1] = QPMS_IROT3_XFLIP;
284 return 2; // Dih_n
285 case QPMS_PGS_DN:
286 gen[0] = qpms_irot3_zrot_Nk(n, 1);
287 gen[1] = QPMS_IROT3_XROT_PI;
288 return 2; // Dih_n
289 case QPMS_PGS_DND:
290 gen[0].rot = qpms_quat_zrot_Nk(2*n, 1);
291 gen[0].det = -1;
292 gen[1] = QPMS_IROT3_XFLIP;
293 return 2; // Dih_2n
294 case QPMS_PGS_DNH:
295 gen[0] = qpms_irot3_zrot_Nk(n, 1);
296 gen[1] = QPMS_IROT3_ZFLIP;
297 gen[2] = QPMS_IROT3_XFLIP;
298 return 3; // Dih_n x Dih_1
300 // Remaining polyhedral groups
301 case QPMS_PGS_T: // return ???; // A_4
302 case QPMS_PGS_TD: // return 2; // S_4
303 case QPMS_PGS_TH: // A_4 x Z_2
304 case QPMS_PGS_O: // S_4
305 case QPMS_PGS_OH: // return 3; // S_4 x Z_2
306 case QPMS_PGS_I: // A_5
307 case QPMS_PGS_IH: // A_5 x Z_2
309 // Continuous axial groups
310 case QPMS_PGS_CINF:
311 case QPMS_PGS_CINFH:
312 case QPMS_PGS_CINFV:
313 case QPMS_PGS_DINF:
314 case QPMS_PGS_DINFH:
316 // Remaining continuous groups
317 case QPMS_PGS_SO3:
318 case QPMS_PGS_O3:
319 QPMS_NOT_IMPLEMENTED("Not yet implemented for this point group class.");
320 default:
321 QPMS_WTF;