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46 #define TRICLINIC(box) (box[YY][XX]!=0 || box[ZZ][XX]!=0 || box[ZZ][YY]!=0)
53 ecenterTRIC
, /* 0.5*(a+b+c) */
54 ecenterRECT
, /* (0.5*a[x],0.5*b[y],0.5*c[z]) */
55 ecenterZERO
, /* (0,0,0) */
56 ecenterDEF
= ecenterTRIC
59 int ePBC2npbcdim(int ePBC
);
60 /* Returns the number of dimensions that use pbc, starting at X */
62 int inputrec2nboundeddim(t_inputrec
*ir
);
63 /* Returns the number of dimensions in which
64 * the coordinates of the particles are bounded, starting at X.
67 void dump_pbc(FILE *fp
,t_pbc
*pbc
);
68 /* Dump the contents of the pbc structure to the file */
70 const char *check_box(int ePBC
,matrix box
);
71 /* Returns NULL if the box is supported by Gromacs.
72 * Otherwise is returns a string with the problem.
73 * When ePBC=-1, the type of pbc is guessed from the box matrix.
76 real
max_cutoff2(int ePBC
,matrix box
);
77 /* Returns the square of the maximum cut-off allowed for the box,
78 * taking into account that the grid neighborsearch code and pbc_dx
79 * only check combinations of single box-vector shifts.
82 int guess_ePBC(matrix box
);
83 /* Guesses the type of periodic boundary conditions using the box */
85 gmx_bool
correct_box(FILE *fplog
,int step
,tensor box
,t_graph
*graph
);
86 /* Checks for un-allowed box angles and corrects the box
87 * and the integer shift vectors in the graph (if graph!=NULL) if necessary.
88 * Returns TRUE when the box was corrected.
91 int ndof_com(t_inputrec
*ir
);
92 /* Returns the number of degrees of freedom of the center of mass */
94 void set_pbc(t_pbc
*pbc
,int ePBC
,matrix box
);
95 /* Initiate the periodic boundary conditions.
96 * pbc_dx will not use pbc and return the normal difference vector
97 * when one or more of the diagonal elements of box are zero.
98 * When ePBC=-1, the type of pbc is guessed from the box matrix.
101 t_pbc
*set_pbc_dd(t_pbc
*pbc
,int ePBC
,
102 gmx_domdec_t
*dd
,gmx_bool bSingleDir
,matrix box
);
103 /* As set_pbc, but additionally sets that correct distances can
104 * be obtained using (combinations of) single box-vector shifts.
105 * Should be used with pbc_dx_aiuc.
106 * If dd!=NULL pbc is not used for directions
107 * with dd->nc[i]==1 with bSingleDir==TRUE or
108 * with dd->nc[i]<=2 with bSingleDir==FALSE.
109 * Returns pbc when pbc operations are required, NULL otherwise.
112 void pbc_dx(const t_pbc
*pbc
,const rvec x1
, const rvec x2
, rvec dx
);
113 /* Calculate the correct distance vector from x2 to x1 and put it in dx.
114 * set_pbc must be called before ever calling this routine.
116 * For triclinic boxes pbc_dx does not necessarily return the shortest
117 * distance vector. If pbc->bLimitDistance=TRUE an atom pair with
118 * distance vector dx with norm2(dx) > pbc->limit_distance2 could
119 * have a shorter distance, but not shorter than sqrt(pbc->limit_distance2).
120 * pbc->limit_distance2 is always larger than max_cutoff2(box).
121 * For the standard rhombic dodecahedron and truncated octahedron
122 * pbc->bLimitDistance=FALSE and thus all distances are correct.
125 int pbc_dx_aiuc(const t_pbc
*pbc
,const rvec x1
,const rvec x2
,rvec dx
);
126 /* Calculate the correct distance vector from x2 to x1 and put it in dx,
127 * This function can only be used when all atoms are in the rectangular
128 * or triclinic unit-cell.
129 * Returns the ishift required to shift x1 at closest distance to x2;
130 * i.e. if 0<=ishift<SHIFTS then x1 - x2 + shift_vec[ishift] = dx
131 * (see calc_shifts below on how to obtain shift_vec)
132 * set_pbc_dd or set_pbc must be called before ever calling this routine.
134 void pbc_dx_d(const t_pbc
*pbc
,const dvec x1
, const dvec x2
, dvec dx
);
135 /* As pbc_dx, but for double precision vectors.
136 * set_pbc must be called before ever calling this routine.
139 gmx_bool
image_rect(ivec xi
,ivec xj
,ivec box_size
,
140 real rlong2
,int *shift
,real
*r2
);
141 /* Calculate the distance between xi and xj for a rectangular box.
142 * When the distance is SMALLER than rlong2 return TRUE, return
143 * the shift code in shift and the distance in r2. When the distance is
144 * >= rlong2 return FALSE;
145 * It is assumed that rlong2 is scaled the same way as the ivecs xi and xj.
148 gmx_bool
image_tri(ivec xi
,ivec xj
,imatrix box
,
149 real rlong2
,int *shift
,real
*r2
);
150 /* Calculate the distance between xi and xj for a triclinic box.
151 * When the distance is SMALLER than rlong2 return TRUE, return
152 * the shift code in shift and the distance in r2. When the distance is
153 * >= rlong2 return FALSE;
154 * It is assumed that rlong2 is scaled the same way as the ivecs xi and xj.
157 gmx_bool
image_cylindric(ivec xi
,ivec xj
,ivec box_size
,real rlong2
,
158 int *shift
,real
*r2
);
159 /* Calculate the distance between xi and xj for a rectangular box
160 * using a cylindric cutoff for long-range only.
161 * When the distance is SMALLER than rlong2 (in X and Y dir.)
162 * return TRUE, return
163 * the shift code in shift and the distance in r2. When the distance is
164 * >= rlong2 return FALSE;
165 * It is assumed that rlong2 is scaled the same way as the ivecs xi and xj.
168 void calc_shifts(matrix box
,rvec shift_vec
[]);
169 /* This routine calculates ths shift vectors necessary to use the
173 void calc_box_center(int ecenter
,matrix box
,rvec box_center
);
174 /* Calculates the center of the box.
175 * See the description for the enum ecenter above.
178 void calc_triclinic_images(matrix box
,rvec img
[]);
179 /* Calculates the NTRICIMG box images */
181 void calc_compact_unitcell_vertices(int ecenter
,matrix box
,
183 /* Calculates the NCUCVERT vertices of a compact unitcell */
185 int *compact_unitcell_edges(void);
186 /* Return an array of unitcell edges of length NCUCEDGE*2,
187 * this is an index in vert[], which is calculated by calc_unitcell_vertices.
188 * The index consists of NCUCEDGE pairs of vertex indices.
189 * The index does not change, so it needs to be retrieved only once.
191 void put_atom_in_box(matrix box
,rvec x
);
193 void put_atoms_in_box(matrix box
,int natoms
,rvec x
[]);
194 /* These routines puts ONE or ALL atoms in the box, not caring
195 * about charge groups!
196 * Also works for triclinic cells.
199 void put_atoms_in_triclinic_unitcell(int ecenter
,matrix box
,
200 int natoms
,rvec x
[]);
201 /* This puts ALL atoms in the triclinic unit cell, centered around the
202 * box center as calculated by calc_box_center.
205 const char *put_atoms_in_compact_unitcell(int ePBC
,int ecenter
,
207 int natoms
,rvec x
[]);
208 /* This puts ALL atoms at the closest distance for the center of the box
209 * as calculated by calc_box_center.
210 * Will return NULL is everything went ok and a warning string if not
211 * all atoms could be placed in the unitcell. This can happen for some
212 * triclinic unitcells, see the comment at pbc_dx above.
213 * When ePBC=-1, the type of pbc is guessed from the box matrix.