Added selection examples.
[gromacs/qmmm-gamess-us.git] / include / gstat.h
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36 #ifndef _gstat_h
37 #define _gstat_h
39 #ifdef HAVE_CONFIG_H
40 #include <config.h>
41 #endif
43 #include "typedefs.h"
44 #include "statutil.h"
45 #include "mshift.h"
46 #include "rmpbc.h"
48 #ifdef __cplusplus
49 extern "C" {
50 #endif
52 /***********************************************
54 * A U T O C O R R E L A T I O N
56 ***********************************************/
58 extern real LegendreP(real x,unsigned long m);
60 #define eacNormal (1<<0)
61 #define eacCos (1<<1)
62 #define eacVector (1<<2)
63 #define eacRcross (1<<3 | eacVector)
64 #define eacP0 (1<<4 | eacVector)
65 #define eacP1 (1<<5 | eacVector)
66 #define eacP2 (1<<6 | eacVector)
67 #define eacP3 (1<<7 | eacVector)
68 #define eacP4 (1<<8 | eacVector)
69 #define eacIden (1<<9)
71 enum {
72 effnNONE, effnEXP1, effnEXP2, effnEXP3, effnVAC,
73 effnEXP5, effnEXP7, effnEXP9, effnERREST, effnNR
76 /* must correspond with 'leg' g_chi.c:727 */
77 enum { edPhi=0, edPsi, edOmega, edChi1, edChi2, edChi3, edChi4, edChi5, edChi6, edMax };
79 enum { edPrintST=0,edPrintRO } ;
81 #define NHISTO 360
82 #define NONCHI 3
83 #define MAXCHI edMax-NONCHI
84 #define NROT 4 /* number of rotamers: 1=g(-), 2=t, 3=g(+), 0=other */
86 typedef struct {
87 int minO,minC,H,N,C,O,Cn[MAXCHI+3];
88 } t_dihatms; /* Cn[0]=N, Cn[1]=Ca, Cn[2]=Cb etc. */
90 typedef struct {
91 char name[12];
92 int resnr;
93 int index; /* Index for amino acids (histograms) */
94 int j0[edMax]; /* Index in dih array (phi angle is first...) */
95 t_dihatms atm;
96 int b[edMax];
97 int ntr[edMax];
98 real S2[edMax];
99 real rot_occ[edMax][NROT];
101 } t_dlist;
103 extern int nfp_ffn[effnNR];
105 extern const char *s_ffn[effnNR+2];
107 extern const char *longs_ffn[effnNR];
109 int sffn2effn(const char **sffn);
110 /* Returns the ffn enum corresponding to the selected enum option in sffn */
112 extern t_pargs *add_acf_pargs(int *npargs,t_pargs *pa);
113 /* Add options for autocorr to the current set of options.
114 * *npargs must be initialised to the number of elements in pa,
115 * it will be incremented appropriately.
118 extern void cross_corr(int n,real f[],real g[],real corr[]);
119 /* Simple minded cross correlation algorithm */
121 extern real fit_acf(int ncorr,int fitfn,const output_env_t oenv,bool bVerbose,
122 real tbeginfit,real tendfit,real dt,real c1[],real *fit);
123 /* Fit an ACF to a given function */
125 extern void do_autocorr(const char *fn,const output_env_t oenv,
126 const char *title,
127 int nframes,int nitem,real **c1,
128 real dt,unsigned long mode,bool bAver);
129 /* Calls low_do_autocorr (see below). After calling add_acf_pargs */
131 extern void low_do_autocorr(const char *fn,const output_env_t oenv,
132 const char *title, int nframes,int nitem,
133 int nout,real **c1, real dt,unsigned long mode,
134 int nrestart, bool bAver,bool bNormalize,
135 bool bVerbose,real tbeginfit,real tendfit,
136 int nfitparm,int nskip);
138 * do_autocorr calculates autocorrelation functions for many things.
139 * It takes a 2 d array containing nitem arrays of length nframes
140 * for each item the ACF is calculated.
142 * A number of "modes" exist for computation of the ACF
144 * if (mode == eacNormal) {
145 * C(t) = < X (tau) * X (tau+t) >
147 * else if (mode == eacCos) {
148 * C(t) = < cos (X(tau) - X(tau+t)) >
150 * else if (mode == eacIden) { **not fully supported yet**
151 * C(t) = < (X(tau) == X(tau+t)) >
153 * else if (mode == eacVector) {
154 * C(t) = < X(tau) * X(tau+t)
156 * else if (mode == eacP1) {
157 * C(t) = < cos (X(tau) * X(tau+t) >
159 * else if (mode == eacP2) {
160 * C(t) = 1/2 * < 3 cos (X(tau) * X(tau+t) - 1 >
162 * else if (mode == eacRcross) {
163 * C(t) = < ( X(tau) * X(tau+t) )^2 >
166 * For modes eacVector, eacP1, eacP2 and eacRcross the input should be
167 * 3 x nframes long, where each triplet is taken as a 3D vector
169 * For mode eacCos inputdata must be in radians, not degrees!
171 * Other parameters are:
173 * fn is output filename (.xvg) where the correlation function(s) are printed
174 * title is the title in the output file
175 * nframes is the number of frames in the time series
176 * nitem is the number of items
177 * c1 is an array of dimension [ 0 .. nitem-1 ] [ 0 .. nframes-1 ]
178 * on output, this array is filled with the correlation function
179 * to reduce storage
180 * nrestart is the number of steps between restarts for direct ACFs
181 * (i.e. without FFT) When set to 1 all points are used as
182 * time origin for averaging
183 * dt is the time between frames
184 * bAver If set, all ndih C(t) functions are averaged into a single
185 * C(t)
186 * (bFour If set, will use fast fourier transform (FFT) for evaluating
187 * the ACF: removed option, now on the command line only)
188 * bNormalize If set, all ACFs will be normalized to start at 0
189 * nskip Determines whether steps a re skipped in the output
192 typedef struct {
193 const char *name; /* Description of the J coupling constant */
194 real A,B,C; /* Karplus coefficients */
195 real offset; /* Offset for dihedral angle in histogram (e.g. -M_PI/3) */
196 real Jc; /* Resulting Jcoupling */
197 real Jcsig; /* Standard deviation in Jc */
198 } t_karplus;
200 extern void calc_distribution_props(int nh,int histo[],
201 real start,int nkkk, t_karplus kkk[],
202 real *S2);
203 /* This routine takes a dihedral distribution and calculates
204 * coupling constants and dihedral order parameters of it.
206 * nh is the number of points
207 * histo is the array of datapoints which is assumed to span
208 * 2 M_PI radians
209 * start is the starting angle of the histogram, this can be either 0
210 * or -M_PI
211 * nkkk is the number of karplus sets (multiple coupling constants may be
212 * derived from a single angle)
213 * kkk are the constants for calculating J coupling constants using a
214 * Karplus equation according to
217 * J = A cos theta + B cos theta + C
219 * where theta is phi - offset (phi is the angle in the histogram)
220 * offset is subtracted from phi before substitution in the Karplus
221 * equation
222 * S2 is the resulting dihedral order parameter
227 /***********************************************
229 * F I T R O U T I N E S
231 ***********************************************/
232 extern void do_expfit(int ndata,real c1[],real dt,
233 real begintimefit,real endtimefit);
235 extern void expfit(int n, real x[], real y[], real Dy[],
236 real *a, real *sa,
237 real *b, real *sb);
238 /* This procedure fits y=exp(a+bx) for n (x,y) pairs to determine a and b.
239 * The uncertainties in the y values must be in the vector Dy.
240 * The standard deviations of a and b, sa and sb, are also calculated.
242 * Routine from Computers in physics, 7(3) (1993), p. 280-285.
245 extern void ana_dih_trans(const char *fn_trans,const char *fn_histo,
246 real **dih,int nframes,int nangles,
247 const char *grpname,real t0,real dt,bool bRb,
248 const output_env_t oenv);
250 * Analyse dihedral transitions, by counting transitions per dihedral
251 * and per frame. The total number of transitions is printed to
252 * stderr, as well as the average time between transitions.
254 * is wrapper to low_ana_dih_trans, which also passes in and out the
255 number of transitions per dihedral per residue. that uses struc dlist
256 which is not external, so pp2shift.h must be included.
258 * Dihedrals are supposed to be in either of three minima,
259 * (trans, gauche+, gauche-)
261 * fn_trans output file name for #transitions per timeframe
262 * fn_histo output file name for transition time histogram
263 * dih the actual dihedral angles
264 * nframes number of times frames
265 * nangles number of angles
266 * grpname a string for the header of plots
267 * t0,dt starting time resp. time between time frames
268 * bRb determines whether the polymer convention is used
269 * (trans = 0)
272 extern void low_ana_dih_trans(bool bTrans, const char *fn_trans,
273 bool bHisto, const char *fn_histo, int maxchi,
274 real **dih, int nlist, t_dlist dlist[],
275 int nframes, int nangles, const char *grpname,
276 int xity[], real t0, real dt, bool bRb,
277 real core_frac, const output_env_t oenv);
278 /* as above but passes dlist so can copy occupancies into it, and xity[]
279 * (1..nangles, corresp to dih[this][], so can have non-3 multiplicity of
280 * rotamers. Also production of xvg output files is conditional
281 * and the fractional width of each rotamer can be set ie for a 3 fold
282 * dihedral with core_frac = 0.5 only the central 60 degrees is assigned
283 * to each rotamer, the rest goes to rotamer zero */
287 extern void read_ang_dih(const char *trj_fn,
288 bool bAngles,bool bSaveAll,bool bRb,bool bPBC,
289 int maxangstat,int angstat[],
290 int *nframes,real **time,
291 int isize,atom_id index[],
292 real **trans_frac,
293 real **aver_angle,
294 real *dih[],
295 const output_env_t oenv);
297 * Read a trajectory and calculate angles and dihedrals.
299 * trj_fn file name of trajectory
300 * tpb_fn file name of tpb file
301 * bAngles do we have to read angles or dihedrals
302 * bSaveAll do we have to store all in the dih array
303 * bRb do we have Ryckaert-Bellemans dihedrals (trans = 0)
304 * bPBC compute angles module 2 Pi
305 * maxangstat number of entries in distribution array
306 * angstat angle distribution
307 * *nframes number of frames read
308 * time simulation time at each time frame
309 * isize number of entries in the index, when angles 3*number of angles
310 * else 4*number of angles
311 * index atom numbers that define the angles or dihedrals
312 * (i,j,k) resp (i,j,k,l)
313 * trans_frac number of dihedrals in trans
314 * aver_angle average angle at each time frame
315 * dih all angles at each time frame
318 extern void make_histo(FILE *log,
319 int ndata,real data[],int npoints,int histo[],
320 real minx,real maxx);
322 * Make a histogram from data. The min and max of the data array can
323 * be determined (if minx == 0 and maxx == 0)
324 * and the index in the histogram is computed from
325 * ind = npoints/(max(data) - min(data))
327 * log write error output to this file
328 * ndata number of points in data
329 * data data points
330 * npoints number of points in histogram
331 * histo histogram array. This is NOT set to zero, to allow you
332 * to add multiple histograms
333 * minx start of the histogram
334 * maxx end of the histogram
335 * if both are 0, these values are computed by the routine itself
338 extern void normalize_histo(int npoints,int histo[],real dx,real normhisto[]);
340 * Normalize a histogram so that the integral over the histo is 1
342 * npoints number of points in the histo array
343 * histo input histogram
344 * dx distance between points on the X-axis
345 * normhisto normalized output histogram
348 extern real fit_function(int eFitFn,real *parm,real x);
349 /* Returns the value of fit function eFitFn at x */
351 /* Use Levenberg-Marquardt method to fit to a nfitparm parameter exponential */
352 /* or to a transverse current autocorrelation function */
353 /* Or: "There is no KILL like OVERKILL", Dr. Ir. D. van der Spoel */
354 extern real do_lmfit(int ndata,real c1[],real sig[],real dt,real *x,
355 real begintimefit,real endtimefit,const output_env_t oenv,
356 bool bVerbose, int eFitFn,real fitparms[],int fix);
357 /* Returns integral.
358 * If x == NULL, the timestep dt will be used to create a time axis.
359 * fix fixes fit parameter i at it's starting value, when the i'th bit
360 * of fix is set.
363 extern real evaluate_integral(int n,real x[],real y[],real dy[],
364 real aver_start,real *stddev);
365 /* Integrate data in y, and, if given, use dy as weighting
366 * aver_start should be set to a value where the function has
367 * converged to 0.
370 extern real print_and_integrate(FILE *fp,int n,real dt,
371 real c[],real *fit,int nskip);
372 /* Integrate the data in c[] from 0 to n using trapezium rule.
373 * If fp != NULL output is written to it
374 * nskip determines whether all elements are written to the output file
375 * (written when i % nskip == 0)
376 * If fit != NULL the fit is also written.
379 extern int get_acfnout(void);
380 /* Return the output length for the correlation function
381 * Works only AFTER do_auto_corr has been called!
384 extern int get_acffitfn(void);
385 /* Return the fit function type.
386 * Works only AFTER do_auto_corr has been called!
389 /* Routines from pp2shift (anadih.c etc.) */
391 extern void do_pp2shifts(FILE *fp,int nframes,
392 int nlist,t_dlist dlist[],real **dih);
394 extern bool has_dihedral(int Dih,t_dlist *dl);
396 extern t_dlist *mk_dlist(FILE *log,
397 t_atoms *atoms, int *nlist,
398 bool bPhi, bool bPsi, bool bChi, bool bHChi,
399 int maxchi,int r0,int naa,char **aa);
401 extern void pr_dlist(FILE *fp,int nl,t_dlist dl[],real dt, int printtype,
402 bool bPhi, bool bPsi,bool bChi,bool bOmega, int maxchi);
404 extern int pr_trans(FILE *fp,int nl,t_dlist dl[],real dt,int Xi);
406 extern void mk_chi_lookup (int **lookup, int maxchi, real **dih,
407 int nlist, t_dlist dlist[]) ;
409 extern void mk_multiplicity_lookup (int *xity, int maxchi, real **dih,
410 int nlist, t_dlist dlist[],int nangle) ;
412 extern void get_chi_product_traj (real **dih,int nframes,int nangles,
413 int nlist,int maxchi, t_dlist dlist[],
414 real time[], int **lookup,int *xity,
415 bool bRb,bool bNormalize,
416 real core_frac,bool bAll,const char *fnall,
417 const output_env_t oenv);
419 extern void print_one (const output_env_t oenv, const char *base,
420 const char *name,
421 const char *title, const char *ylabel,int nf,
422 real time[],real data[]);
424 /* Routines from g_hbond */
425 extern void analyse_corr(int n,real t[],real ct[],real nt[],real kt[],
426 real sigma_ct[],real sigma_nt[],real sigma_kt[],
427 real fit_start,real temp,real smooth_tail_start,
428 const output_env_t oenv);
430 extern void compute_derivative(int nn,real x[],real y[],real dydx[]);
432 #ifdef __cplusplus
434 #endif
436 #endif