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/*
* symmetry.c
*
* Symmetry
*
* (c) 2006-2010 Thomas White <taw@physics.org>
*
* Part of CrystFEL - crystallography with a FEL
*
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#include "utils.h"
#ifdef DEBUG
#define SYM_DEBUG STATUS
#else /* DEBUG */
#define SYM_DEBUG(...)
#endif /* DEBUG */
/* Check if a reflection is in the asymmetric unit cell */
static int check_cond(signed int h, signed int k, signed int l, const char *sym)
{
/* Triclinic */
if ( strcmp(sym, "1") == 0 )
return ( 1 );
if ( strcmp(sym, "-1") == 0 )
return ( (l>0)
|| ( (l==0) && (k>0) )
|| ( (l==0) && (k==0) && (h>=0) ) );
/* Tetragonal */
if ( strcmp(sym, "422") == 0 )
return ( (((h>=0) && (k>0)) || ((h==0) && (k==0)))
&& (h>=k) );
/* Hexagonal */
if ( strcmp(sym, "6") == 0 )
return ( ((h>0) && (k>=0)) || ((h==0) && (k==0)) );
if ( strcmp(sym, "6/m") == 0 )
return ( (((h>0) && (k>=0)) || ((h==0) && (k==0))) && (l>=0) );
if ( strcmp(sym, "6/mmm") == 0 )
return ( (((h>0) && (k>=0)) || ((h==0) && (k==0))) && (l>=0)
&& (h>=k) );
/* TODO: Add more groups here */
return 1;
}
/* Macros for checking the above conditions and returning if satisfied */
#define CHECK_COND(h, k, l, sym) \
if ( check_cond((h), (k), (l), (sym)) ) { \
*hp = (h); *kp = (k); *lp = (l); \
return; \
}
int num_general_equivs(const char *sym)
{
/* Triclinic */
if ( strcmp(sym, "1") == 0 ) return 1;
if ( strcmp(sym, "-1") == 0 ) return 2;
/* Tetragonal */
if ( strcmp(sym, "422") == 0 ) return 8;
/* Hexagonal */
if ( strcmp(sym, "6") == 0 ) return 6;
if ( strcmp(sym, "6/m") == 0 ) return 12;
if ( strcmp(sym, "6/mmm") == 0 ) return 24;
/* TODO: Add more groups here */
return 1;
}
void get_general_equiv(signed int h, signed int k, signed int l,
signed int *he, signed int *ke, signed int *le,
const char *sym, int idx)
{
signed int i = -h-k;
/* The returned indices when idx=0 *must* be the same as the input.
* After that, the order does not matter. */
if ( strcmp(sym, "1") == 0 ) {
*he = h; *ke = k; *le = l; return;
}
if ( strcmp(sym, "-1") == 0 ) {
switch ( idx ) {
case 0 : *he = h; *ke = k; *le = l; return;
case 1 : *he = -h; *ke = -k; *le = -l; return;
}
}
if ( strcmp(sym, "422") == 0 ) {
switch ( idx ) {
case 0 : *he = h; *ke = k; *le = l; return;
case 1 : *he = -h; *ke = -k; *le = l; return;
case 2 : *he = -k; *ke = h; *le = l; return;
case 3 : *he = k; *ke = -h; *le = l; return;
case 4 : *he = -h; *ke = k; *le = -l; return;
case 5 : *he = h; *ke = -k; *le = -l; return;
case 6 : *he = k; *ke = h; *le = -l; return;
case 7 : *he = -k; *ke = -h; *le = -l; return;
}
}
if ( strcmp(sym, "6") == 0 ) {
switch ( idx ) {
case 0 : *he = h; *ke = k; *le = l; return;
case 1 : *he = i; *ke = h; *le = l; return;
case 2 : *he = k; *ke = i; *le = l; return;
case 3 : *he = -h; *ke = -k; *le = l; return;
case 4 : *he = -i; *ke = -h; *le = l; return;
case 5 : *he = -k; *ke = -i; *le = l; return;
}
}
if ( strcmp(sym, "6/m") == 0 ) {
switch ( idx ) {
case 0 : *he = h; *ke = k; *le = l; return;
case 1 : *he = i; *ke = h; *le = l; return;
case 2 : *he = k; *ke = i; *le = l; return;
case 3 : *he = -h; *ke = -k; *le = l; return;
case 4 : *he = -i; *ke = -h; *le = l; return;
case 5 : *he = -k; *ke = -i; *le = l; return;
case 6 : *he = h; *ke = k; *le = -l; return;
case 7 : *he = i; *ke = h; *le = -l; return;
case 8 : *he = k; *ke = i; *le = -l; return;
case 9 : *he = -h; *ke = -k; *le = -l; return;
case 10 : *he = -i; *ke = -h; *le = -l; return;
case 11 : *he = -k; *ke = -i; *le = -l; return;
}
}
if ( strcmp(sym, "6/mmm") == 0 ) {
switch ( idx ) {
case 0 : *he = h; *ke = k; *le = l; return;
case 1 : *he = i; *ke = h; *le = l; return;
case 2 : *he = k; *ke = i; *le = l; return;
case 3 : *he = -h; *ke = -k; *le = l; return;
case 4 : *he = -i; *ke = -h; *le = l; return;
case 5 : *he = -k; *ke = -i; *le = l; return;
case 6 : *he = k; *ke = h; *le = -l; return;
case 7 : *he = h; *ke = i; *le = -l; return;
case 8 : *he = i; *ke = k; *le = -l; return;
case 9 : *he = -k; *ke = -h; *le = -l; return;
case 10 : *he = -h; *ke = -i; *le = -l; return;
case 11 : *he = -i; *ke = -k; *le = -l; return;
case 12 : *he = -h; *ke = -k; *le = -l; return;
case 13 : *he = -i; *ke = -h; *le = -l; return;
case 14 : *he = -k; *ke = -i; *le = -l; return;
case 15 : *he = h; *ke = k; *le = -l; return;
case 16 : *he = i; *ke = h; *le = -l; return;
case 17 : *he = k; *ke = i; *le = -l; return;
case 18 : *he = -k; *ke = -h; *le = l; return;
case 19 : *he = -h; *ke = -i; *le = l; return;
case 20 : *he = -i; *ke = -k; *le = l; return;
case 21 : *he = k; *ke = h; *le = l; return;
case 22 : *he = h; *ke = i; *le = l; return;
case 23 : *he = i; *ke = k; *le = l; return;
}
}
/* TODO: Add more groups here */
ERROR("Unrecognised symmetry '%s'\n", sym);
abort();
}
/* Given a reflection and a point group, this returns (by reference) the indices
* of the "idx"th equivalent reflection, taking special positions into account.
* It returns "idx" if successful. Otherwise, it returns the number of
* equivalents for the particular reflection (taking special positions into
* account). Therefore, set idx=-1 to get the number of equivalents. */
static int special_position(signed int hs, signed int ks, signed int ls,
signed int *hp, signed int *kp, signed int *lp,
const char *sym, signed int idx)
{
int n_general;
int i;
ReflItemList *equivs;
int n_equivs = 0;
if ( idx == 0 ) {
/* Index zero is always the original reflection */
*hp = hs; *kp = ks; *lp = ls;
return 0;
}
equivs = new_items();
n_general = num_general_equivs(sym);
for ( i=0; i<n_general; i++ ) {
signed int h, k, l;
/* Get equivalent according to the holohedral group */
get_general_equiv(hs, ks, ls, &h, &k, &l, sym, i);
/* Already got this one? */
if ( find_item(equivs, h, k, l) ) continue;
if ( n_equivs == idx ) {
*hp = h;
*kp = k;
*lp = l;
delete_items(equivs);
return n_equivs;
}
add_item(equivs, h, k, l);
n_equivs++;
}
delete_items(equivs);
return n_equivs;
}
void get_equiv(signed int h, signed int k, signed int l,
signed int *he, signed int *ke, signed int *le,
const char *sym, int idx)
{
special_position(h, k, l, he, ke, le, sym, idx);
}
int num_equivs(signed int h, signed int k, signed int l, const char *sym)
{
return special_position(h, k, l, NULL, NULL, NULL, sym, -1);
}
void get_asymm(signed int h, signed int k, signed int l,
signed int *hp, signed int *kp, signed int *lp,
const char *sym)
{
int nequiv = num_equivs(h, k, l, sym);
int p;
SYM_DEBUG("------ %i %i %i\n", h, k, l);
for ( p=0; p<nequiv; p++ ) {
signed int he, ke, le;
get_equiv(h, k, l, &he, &ke, &le, sym, p);
SYM_DEBUG("%i : %i %i %i\n", p, he, ke, le);
CHECK_COND(he, ke, le, sym);
}
/* Should never reach here */
ERROR("No match found in %s for %i %i %i\n", sym, h, k, l);
abort();
}
const char *get_holohedral(const char *sym)
{
/* Triclinic */
if ( strcmp(sym, "1") == 0 ) return "-1";
if ( strcmp(sym, "-1") == 0 ) return "-1";
/* Tetragonal */
if ( strcmp(sym, "422") == 0 ) return "4/mmm";
/* Hexagonal */
if ( strcmp(sym, "6") == 0 ) return "6/mmm";
if ( strcmp(sym, "6/m") == 0 ) return "6/mmm";
if ( strcmp(sym, "6/mmm") == 0 ) return "6/mmm";
/* TODO: Add more groups here */
ERROR("Couldn't find holohedral point group for '%s'\n", sym);
abort();
}
/* This is kind of like a "numerical" left coset decomposition.
* Given a reflection index and a point group, it returns the list of twinning
* possibilities.
*
* To count the number of possibilities, use num_items() on the result.
*/
static ReflItemList *coset_decomp(signed int hs, signed int ks, signed int ls,
const char *holo, const char *mero)
{
int n_mero, n_holo;
int i;
signed int h, k, l;
ReflItemList *twins = new_items();
/* Start by putting the given reflection into the asymmetric cell
* for its (probably merohedral) point group. */
get_asymm(hs, ks, ls, &h, &k, &l, mero);
/* How many equivalents in the holohedral point group are not
* equivalents according to the (possibly) merohedral group? */
n_holo = num_general_equivs(holo);
n_mero = num_general_equivs(mero);
for ( i=0; i<n_holo; i++ ) {
signed int h_holo, k_holo, l_holo;
signed int hs_holo, ks_holo, ls_holo;
/* Get equivalent according to the holohedral group */
get_general_equiv(h, k, l, &hs_holo, &ks_holo, &ls_holo,
holo, i);
/* Put it into the asymmetric cell for the merohedral group */
get_asymm(hs_holo, ks_holo, ls_holo,
&h_holo, &k_holo, &l_holo, mero);
/* Already got this one?
* Note: The list "twins" starts empty, so the first iteration
* (i=0) will add the original reflection to the list along with
* the identity operation. */
if ( find_item(twins, h_holo, k_holo, l_holo) ) continue;
add_item_with_op(twins, h_holo, k_holo, l_holo, i);
}
return twins;
}
/* Work out the twinning possibilities for this pattern.
* To use the result, call get_general_equiv() on each reflection using
* the holohedral point group (use get_holohedral() for this), and for "idx"
* give each "op" field from the list returned by this function. */
ReflItemList *get_twins(ReflItemList *items, const char *holo, const char *mero)
{
int i;
ReflItemList *ops = new_items();
int expected, actual;
/* Run the coset decomposition for every reflection in the "pattern",
* and see which gives the highest number of possibilities. This
* approach takes into account that a pattern consisting entirely of
* special reflections might have fewer twin possibilities. */
for ( i=0; i<num_items(items); i++ ) {
signed int h, k, l;
struct refl_item *item;
ReflItemList *new_ops;
item = get_item(items, i);
h = item->h;
k = item->k;
l = item->l;
new_ops = coset_decomp(h, k, l, holo, mero);
union_op_items(ops, new_ops);
delete_items(new_ops);
}
/* Idiot check */
actual = num_items(ops);
expected = num_general_equivs(holo) / num_general_equivs(mero);
if ( actual != expected ) {
ERROR("I couldn't find the number of twin laws that I expected."
" This is an internal error, and shouldn't happen. "
"Sorry.\n");
abort();
}
return ops;
}
static void scold_user_about_symmetry(signed int h, signed int k, signed int l,
signed int he, signed int ke,
signed int le)
{
ERROR("Symmetrically equivalent reflection (%i %i %i) found for "
"%i %i %i in the input.\n", he, ke, le, h, k, l);
ERROR("This indicates that you lied to me about the symmetry of the "
"input reflections. ");
ERROR("I won't be able to give you a meaningful result in this "
"situation, so I'm going to give up right now. ");
ERROR("Please reconsider your previous processing of the data, and "
"perhaps try again with a lower symmetry for the '-y' option.\n");
abort();
}
int find_unique_equiv(ReflItemList *items, signed int h, signed int k,
signed int l, const char *mero, signed int *hu,
signed int *ku, signed int *lu)
{
int i;
int found = 0;
for ( i=0; i<num_equivs(h, k, l, mero); i++ ) {
signed int he, ke, le;
int f;
get_equiv(h, k, l, &he, &ke, &le, mero, i);
f = find_item(items, he, ke, le);
/* There must only be one equivalent. If there are more, it
* indicates that the user lied about the input symmetry. */
if ( f && found ) {
scold_user_about_symmetry(he, ke, le, *hu, *ku, *lu);
}
if ( f && !found ) {
*hu = he; *ku = ke; *lu = le;
found = 1;
}
}
return found;
}
/* Returns true if the point group is 23, m-3, 432, -43m or m-3m
* (i.e. T, Th, O, Td or Oh) */
int is_polyhedral(const char *sym)
{
/* Triclinic */
if ( strcmp(sym, "1") == 0 ) return 0;
if ( strcmp(sym, "-1") == 0 ) return 0;
/* Tetragonal */
if ( strcmp(sym, "422") == 0 ) return 0;
/* Hexagonal */
if ( strcmp(sym, "6") == 0 ) return 0;
if ( strcmp(sym, "6/m") == 0 ) return 0;
if ( strcmp(sym, "6/mmm") == 0 ) return 0;
/* TODO: Add more groups here */
ERROR("Don't know if '%s' is polyhedral or not.\n", sym);
abort();
}
/* Returns the order of the characteristic axis of proper or improper rotation
* for the point group. This should be the rotation about the c axis. */
int rotational_order(const char *sym)
{
/* Triclinic */
if ( strcmp(sym, "1") == 0 ) return 1;
if ( strcmp(sym, "-1") == 0 ) return 2 ;
/* Tetragonal */
if ( strcmp(sym, "422") == 0 ) return 4;
/* Hexagonal */
if ( strcmp(sym, "6") == 0 ) return 6;
if ( strcmp(sym, "6/m") == 0 ) return 6;
if ( strcmp(sym, "6/mmm") == 0 ) return 6;
/* TODO: Add more groups here */
ERROR("Couldn't find rotational order for '%s'.\n", sym);
abort();
}
int has_perpendicular_mirror(const char *sym)
{
/* Triclinic */
if ( strcmp(sym, "1") == 0 ) return 0;
if ( strcmp(sym, "-1") == 0 ) return 0;
/* Tetragonal */
if ( strcmp(sym, "422") == 0 ) return 0;
/* Hexagonal */
if ( strcmp(sym, "6") == 0 ) return 0;
if ( strcmp(sym, "6/m") == 0 ) return 1;
if ( strcmp(sym, "6/mmm") == 0 ) return 1;
/* TODO: Add more groups here */
ERROR("Couldn't find mirror definition for '%s'.\n", sym);
abort();
}
int has_bisecting_mirror_or_diad(const char *sym)
{
/* Triclinic */
if ( strcmp(sym, "1") == 0 ) return 0;
if ( strcmp(sym, "-1") == 0 ) return 0;
/* Tetragonal */
if ( strcmp(sym, "422") == 0 ) return 0;
/* Hexagonal */
if ( strcmp(sym, "6") == 0 ) return 0;
if ( strcmp(sym, "6/m") == 0 ) return 1;
if ( strcmp(sym, "6/mmm") == 0 ) return 1;
/* TODO: Add more groups here */
ERROR("Couldn't find mirror definition for '%s'.\n", sym);
abort();
}
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