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37 /* This file is completely threadsafe - keep it that way! */
40 #include "gpp_nextnb.h"
44 #include "gromacs/gmxpreprocess/toputil.h"
45 #include "gromacs/topology/ifunc.h"
46 #include "gromacs/utility/fatalerror.h"
47 #include "gromacs/utility/gmxassert.h"
48 #include "gromacs/utility/smalloc.h"
50 /* #define DEBUG_NNB */
57 bond_sort (const void *a, const void *b)
59 const sortable *sa, *sb;
61 sa = reinterpret_cast<const sortable*>(a);
62 sb = reinterpret_cast<const sortable*>(b);
66 return (sa->aj-sb->aj);
70 return (sa->ai-sb->ai);
75 compare_int (const void * a, const void * b)
77 return ( *reinterpret_cast<const int*>(a) - *reinterpret_cast<const int*>(b) );
82 #define prints(str, n, s) __prints(str, n, s)
83 static void __prints(char *str, int n, sortable *s)
89 fprintf(debug, "%s\n", str);
90 fprintf(debug, "Sortables \n");
91 for (i = 0; (i < n); i++)
93 fprintf(debug, "%d\t%d\n", s[i].ai, s[i].aj);
100 #define prints(str, n, s)
103 void init_nnb(t_nextnb *nnb, int nr, int nrex)
112 snew(nnb->nrexcl, nr);
113 for (i = 0; (i < nr); i++)
115 snew(nnb->a[i], nrex+1);
116 snew(nnb->nrexcl[i], nrex+1);
120 static void add_nnb (t_nextnb *nnb, int nre, int i, int j)
122 srenew(nnb->a[i][nre], nnb->nrexcl[i][nre]+1);
123 nnb->a[i][nre][nnb->nrexcl[i][nre]] = j;
124 nnb->nrexcl[i][nre]++;
127 void done_nnb (t_nextnb *nnb)
131 for (i = 0; (i < nnb->nr); i++)
133 for (nre = 0; (nre <= nnb->nrex); nre++)
135 if (nnb->nrexcl[i][nre] > 0)
137 sfree (nnb->a[i][nre]);
140 sfree (nnb->nrexcl[i]);
150 void __print_nnb(t_nextnb *nnb, char *s)
156 fprintf(debug, "%s\n", s);
157 fprintf(debug, "nnb->nr: %d\n", nnb->nr);
158 fprintf(debug, "nnb->nrex: %d\n", nnb->nrex);
159 for (i = 0; (i < nnb->nr); i++)
161 for (j = 0; (j <= nnb->nrex); j++)
163 fprintf(debug, "nrexcl[%d][%d]: %d, excl: ", i, j, nnb->nrexcl[i][j]);
164 for (k = 0; (k < nnb->nrexcl[i][j]); k++)
166 fprintf(debug, "%d, ", nnb->a[i][j][k]);
168 fprintf(debug, "\n");
175 static void nnb2excl(t_nextnb *nnb, t_blocka *excl)
178 int nre, nrx, nrs, nr_of_sortables;
181 srenew(excl->index, nnb->nr+1);
183 for (i = 0; (i < nnb->nr); i++)
185 /* calculate the total number of exclusions for atom i */
187 for (nre = 0; (nre <= nnb->nrex); nre++)
189 nr_of_sortables += nnb->nrexcl[i][nre];
192 /* make space for sortable array */
193 snew(s, nr_of_sortables);
195 /* fill the sortable array and sort it */
197 for (nre = 0; (nre <= nnb->nrex); nre++)
199 for (nrx = 0; (nrx < nnb->nrexcl[i][nre]); nrx++)
202 s[nrs].aj = nnb->a[i][nre][nrx];
206 if (nrs != nr_of_sortables)
208 gmx_incons("Generating exclusions");
210 prints("nnb2excl before qsort", nr_of_sortables, s);
211 if (nr_of_sortables > 1)
213 qsort (s, nr_of_sortables, static_cast<size_t>(sizeof(s[0])), bond_sort);
214 prints("nnb2excl after qsort", nr_of_sortables, s);
217 /* remove duplicate entries from the list */
219 if (nr_of_sortables > 0)
221 for (j = 1; (j < nr_of_sortables); j++)
223 if ((s[j].ai != s[j-1].ai) || (s[j].aj != s[j-1].aj))
225 s[j_index++] = s[j-1];
228 s[j_index++] = s[j-1];
230 nr_of_sortables = j_index;
231 prints("after rm-double", j_index, s);
233 /* make space for arrays */
234 srenew(excl->a, excl->nra+nr_of_sortables);
236 /* put the sorted exclusions in the target list */
237 for (nrs = 0; (nrs < nr_of_sortables); nrs++)
239 excl->a[excl->nra+nrs] = s[nrs].aj;
241 excl->nra += nr_of_sortables;
242 excl->index[i+1] = excl->nra;
244 /* cleanup temporary space */
249 /*! \brief Return true of neighbor is already present in some exclusion level
251 * To avoid exploding complexity when processing exclusions for highly
252 * connected molecules with lots of exclusions, this routine is used to
253 * check whether a particular neighbor has already been excluded at any lower
254 * bond distance, in which case we should not add it to avoid creating loops.
256 * \param nnb Valid initialized next-neighbor structure
257 * \param atom The host atom whose neighbors we are searching
258 * \param highest_order The highest-rank neighbor list to search.
259 * \param query Atom index to look for
261 * \return True if query is present as an exclusion of up to highest_order
262 * (inclusive) from atom. For instance, if highest_order is 2,
263 * the routine will return true if the query atom is already listed as
264 * first or second neighbor (exclusion) in nnb.
267 atom_is_present_in_nnb(const t_nextnb * nnb,
272 GMX_RELEASE_ASSERT(highest_order < nnb->nrex, "Inconsistent nnb seach parameters");
274 for (int order = 0; order <= highest_order; order++)
276 for (int m = 0; m < nnb->nrexcl[atom][order]; m++)
278 if (nnb->a[atom][order][m] == query)
287 static void do_gen(int nrbonds, /* total number of bonds in s */
288 sortable *s, /* bidirectional list of bonds */
289 t_nextnb *nnb) /* the tmp storage for excl */
290 /* Assume excl is initalised and s[] contains all bonds bidirectional */
295 for (i = 0; (i < nnb->nr); i++)
297 add_nnb(nnb, 0, i, i);
299 print_nnb(nnb, "After exclude self");
301 /* exclude all the bonded atoms */
304 for (i = 0; (i < nrbonds); i++)
306 add_nnb(nnb, 1, s[i].ai, s[i].aj);
309 print_nnb(nnb, "After exclude bonds");
311 /* for the nr of exclusions per atom */
312 for (n = 1; (n < nnb->nrex); n++)
314 /* now for all atoms */
315 for (i = 0; (i < nnb->nr); i++)
317 /* for all directly bonded atoms of atom i */
318 for (j = 0; (j < nnb->nrexcl[i][1]); j++)
321 /* store the 1st neighbour in nb */
322 nb = nnb->a[i][1][j];
324 /* store all atoms in nb's n-th list into i's n+1-th list */
325 for (k = 0; (k < nnb->nrexcl[nb][n]); k++)
327 // Only add if it is not already present as a closer neighbor
328 // to avoid exploding complexity for highly connected molecules
329 // with high exclusion order
330 if (!atom_is_present_in_nnb(nnb, i, n, nnb->a[nb][n][k]))
332 add_nnb(nnb, n+1, i, nnb->a[nb][n][k]);
338 print_nnb(nnb, "After exclude rest");
342 static void add_b(t_params *bonds, int *nrf, sortable *s)
347 for (i = 0; (i < bonds->nr); i++)
349 ai = bonds->param[i].ai();
350 aj = bonds->param[i].aj();
351 if ((ai < 0) || (aj < 0))
353 gmx_fatal(FARGS, "Impossible atom numbers in bond %d: ai=%d, aj=%d",
356 /* Add every bond twice */
364 void gen_nnb(t_nextnb *nnb, t_params plist[])
370 for (i = 0; (i < F_NRE); i++)
374 /* we need every bond twice (bidirectional) */
375 nrbonds += 2*plist[i].nr;
382 for (i = 0; (i < F_NRE); i++)
386 add_b(&plist[i], &nrf, s);
390 /* now sort the bonds */
391 prints("gen_excl before qsort", nrbonds, s);
394 qsort(s, nrbonds, static_cast<size_t>(sizeof(sortable)), bond_sort);
395 prints("gen_excl after qsort", nrbonds, s);
398 do_gen(nrbonds, s, nnb);
403 sort_and_purge_nnb(t_nextnb *nnb)
405 int i, j, k, m, n, cnt, found, prev, idx;
407 for (i = 0; (i < nnb->nr); i++)
409 for (n = 0; (n <= nnb->nrex); n++)
411 /* Sort atoms in this list */
412 qsort(nnb->a[i][n], nnb->nrexcl[i][n], sizeof(int), compare_int);
416 for (j = 0; j < nnb->nrexcl[i][n]; j++)
418 idx = nnb->a[i][n][j];
421 for (m = 0; m < n && !found; m++)
423 for (k = 0; k < nnb->nrexcl[i][m] && !found; k++)
425 found = (idx == nnb->a[i][m][k]);
429 if (!found && nnb->a[i][n][j] != prev)
431 nnb->a[i][n][cnt] = nnb->a[i][n][j];
432 prev = nnb->a[i][n][cnt];
436 nnb->nrexcl[i][n] = cnt;
442 void generate_excl (int nrexcl, int nratoms, t_params plist[], t_nextnb *nnb, t_blocka *excl)
446 gmx_fatal(FARGS, "Can't have %d exclusions...", nrexcl);
448 init_nnb(nnb, nratoms, nrexcl);
451 sort_and_purge_nnb(nnb);
452 nnb2excl (nnb, excl);