src/openbabel/rotamer.cpp

/**********************************************************************
rotamer.cpp - Handle rotamer list data.
 
Copyright (C) 1998, 1999, 2000-2002 OpenEye Scientific Software, Inc.
Some portions Copyright (C) 2001-2005 by Geoffrey R. Hutchison
 
This file is part of the Open Babel project.
For more information, see <http://openbabel.sourceforge.net/>
 
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation version 2 of the License.
 
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU General Public License for more details.
***********************************************************************/

#include "rotamer.hpp"
#include "mol.hpp"
#include "obutil.hpp"
#include "rotor.hpp"

#define OB_TITLE_SIZE     254
#define OB_BINARY_SETWORD 32

using namespace std;

namespace OpenBabel
{

//test byte ordering
static int SINT = 0x00000001;
static unsigned char *STPTR = (unsigned char*)&SINT;
const bool SwabInt = (STPTR[0]!=0);

#if !HAVE_RINT
inline double rint(double x)
{
    return ( (x < 0.0) ? ceil(x-0.5) : floor(x+0.5));
}
#endif

void SetRotorToAngle(double *c,OBAtom **ref,double ang,vector<int> atoms);

int Swab(int i)
{
    unsigned char tmp[4],c;
    memcpy(tmp,(char*)&i,sizeof(int));
    c = tmp[0];
    tmp[0] = tmp[3];
    tmp[3] = c;
    c = tmp[1];
    tmp[1] = tmp[2];
    tmp[2] = c;
    memcpy((char*)&i,tmp,sizeof(int));
    return(i);
}

OBRotamerList::~OBRotamerList()
{
    vector<unsigned char*>::iterator i;
    for (i = _vrotamer.begin();i != _vrotamer.end();i++)
        delete [] *i;

    vector<pair<OBAtom**,vector<int> > >::iterator j;
    for (j = _vrotor.begin();j != _vrotor.end();j++)
        delete [] j->first;

    //Delete the interal base coordinate list
    unsigned int k;
    for (k=0 ; k<_c.size() ; k++)
        delete [] _c[k];
}

void OBRotamerList::GetReferenceArray(unsigned char *ref)
{
    int j;
    vector<pair<OBAtom**,vector<int> > >::iterator i;
    for (j=0,i = _vrotor.begin();i != _vrotor.end();i++)
    {
        ref[j++] = (unsigned char)(i->first[0])->GetIdx();
        ref[j++] = (unsigned char)(i->first[1])->GetIdx();
        ref[j++] = (unsigned char)(i->first[2])->GetIdx();
        ref[j++] = (unsigned char)(i->first[3])->GetIdx();
    }
}

void OBRotamerList::Setup(OBMol &mol,OBRotorList &rl)
{
    //clear the old stuff out if necessary
    _vres.clear();
    vector<unsigned char*>::iterator j;
    for (j = _vrotamer.begin();j != _vrotamer.end();j++)
        delete [] *j;
    _vrotamer.clear();

    vector<pair<OBAtom**,vector<int> > >::iterator k;
    for (k = _vrotor.begin();k != _vrotor.end();k++)
        delete [] k->first;
    _vrotor.clear();

    //create the new list
    OBRotor *rotor;
    vector<OBRotor*>::iterator i;
    vector<int> children;

    int ref[4];
    OBAtom **atomlist;
    for (rotor = rl.BeginRotor(i);rotor;rotor = rl.NextRotor(i))
    {
        atomlist = new OBAtom* [4];
        rotor->GetDihedralAtoms(ref);
        atomlist[0] = mol.GetAtom(ref[0]);
        atomlist[1] = mol.GetAtom(ref[1]);
        atomlist[2] = mol.GetAtom(ref[2]);
        atomlist[3] = mol.GetAtom(ref[3]);
        mol.FindChildren(children,ref[1],ref[2]);
        _vrotor.push_back(pair<OBAtom**,vector<int> > (atomlist,children));
        _vres.push_back(rotor->GetResolution());
    }

    vector<double>::iterator n;
    vector<vector<double> >::iterator m;
    for (m = _vres.begin();m != _vres.end();m++)
        for (n = m->begin();n != m->end();n++)
            *n *= RAD_TO_DEG;
}

void OBRotamerList::Setup(OBMol &mol,unsigned char *ref,int nrotors)
{
    //clear the old stuff out if necessary
    _vres.clear();
    vector<unsigned char*>::iterator j;
    for (j = _vrotamer.begin();j != _vrotamer.end();j++)
        delete [] *j;
    _vrotamer.clear();

    vector<pair<OBAtom**,vector<int> > >::iterator k;
    for (k = _vrotor.begin();k != _vrotor.end();k++)
        delete [] k->first;
    _vrotor.clear();

    //create the new list
    int i;
    vector<int> children;

    int refatoms[4];
    OBAtom **atomlist;
    for (i = 0; i < nrotors; i++)
    {
        atomlist = new OBAtom* [4];
        refatoms[0] = (int)ref[i*4  ];
        refatoms[1] = (int)ref[i*4+1];
        refatoms[2] = (int)ref[i*4+2];
        refatoms[3] = (int)ref[i*4+3];
        mol.FindChildren(children,refatoms[1],refatoms[2]);
        atomlist[0] = mol.GetAtom(refatoms[0]);
        atomlist[1] = mol.GetAtom(refatoms[1]);
        atomlist[2] = mol.GetAtom(refatoms[2]);
        atomlist[3] = mol.GetAtom(refatoms[3]);
        _vrotor.push_back(pair<OBAtom**,vector<int> > (atomlist,children));
    }

}

void OBRotamerList::AddRotamer(double *c)
{
    int idx,size;
    double angle,res=255.0f/360.0f;
    vector3 v1,v2,v3,v4;

    unsigned char *rot = new unsigned char [_vrotor.size()+1];
    rot[0] = (char) 0;

    vector<pair<OBAtom**,vector<int> > >::iterator i;
    for (size=1,i = _vrotor.begin();i != _vrotor.end();i++,size++)
    {
        idx = (i->first[0])->GetCIdx();
        v1.Set(c[idx],c[idx+1],c[idx+2]);
        idx = (i->first[1])->GetCIdx();
        v2.Set(c[idx],c[idx+1],c[idx+2]);
        idx = (i->first[2])->GetCIdx();
        v3.Set(c[idx],c[idx+1],c[idx+2]);
        idx = (i->first[3])->GetCIdx();
        v4.Set(c[idx],c[idx+1],c[idx+2]);

        angle = CalcTorsionAngle(v1,v2,v3,v4);
        while (angle < 0.0f)
            angle += 360.0f;
        while (angle > 360.0f)
            angle -= 360.0f;
        rot[size] = (unsigned char)rint(angle*res);
    }

    _vrotamer.push_back(rot);
}

void OBRotamerList::AddRotamer(int *arr)
{
    unsigned int i;
    double angle,res=255.0f/360.0f;

    unsigned char *rot = new unsigned char [_vrotor.size()+1];
    rot[0] = (unsigned char)arr[0];

    for (i = 0;i < _vrotor.size();i++)
    {
        angle = _vres[i][arr[i+1]];
        while (angle < 0.0f)
            angle += 360.0f;
        while (angle > 360.0f)
            angle -= 360.0f;
        rot[i+1] = (unsigned char)rint(angle*res);
    }
    _vrotamer.push_back(rot);
}

void OBRotamerList::AddRotamer(unsigned char *arr)
{
    unsigned int i;
    double angle,res=255.0f/360.0f;

    unsigned char *rot = new unsigned char [_vrotor.size()+1];
    rot[0] = (unsigned char)arr[0];

    for (i = 0;i < _vrotor.size();i++)
    {
        angle = _vres[i][(int)arr[i+1]];
        while (angle < 0.0f)
            angle += 360.0f;
        while (angle > 360.0f)
            angle -= 360.0f;
        rot[i+1] = (unsigned char)rint(angle*res);
    }
    _vrotamer.push_back(rot);
}

void OBRotamerList::AddRotamers(unsigned char *arr,int nrotamers)
{
    unsigned int size;
    int i;

    size = (unsigned int)_vrotor.size()+1;
    for (i = 0;i < nrotamers;i++)
    {
        unsigned char *rot = new unsigned char [size];
        memcpy(rot,&arr[i*size],sizeof(char)*size);
        _vrotamer.push_back(rot);
    }
}

void OBRotamerList::ExpandConformerList(OBMol &mol,vector<double*> &clist)
{
    unsigned int j;
    double angle,invres=360.0f/255.0f;
    unsigned char *conf;
    vector<double*> tmpclist;
    vector<unsigned char*>::iterator i;

    for (i = _vrotamer.begin();i != _vrotamer.end();i++)
    {
        conf = *i;
        double *c = new double [mol.NumAtoms()*3];
        memcpy(c,clist[(int)conf[0]],sizeof(double)*mol.NumAtoms()*3);

        for (j = 0;j < _vrotor.size();j++)
        {
            angle = invres*((double)conf[j+1]);
            if (angle > 180.0)
                angle -= 360.0;
            SetRotorToAngle(c,_vrotor[j].first,angle,_vrotor[j].second);
        }
        tmpclist.push_back(c);
    }

    //transfer the conf list
    vector<double*>::iterator k;
    for (k = clist.begin();k != clist.end();k++)
        delete [] *k;
    clist = tmpclist;
}

//! Create a conformer list using the internal base set of coordinates
vector<double*> OBRotamerList::CreateConformerList(OBMol& mol)
{
    unsigned int j;
    double angle,invres=360.0f/255.0f;
    unsigned char *conf;
    vector<double*> tmpclist;
    vector<unsigned char*>::iterator i;

    for (i = _vrotamer.begin();i != _vrotamer.end();i++)
    {
        conf = *i;
        double *c = new double [mol.NumAtoms()*3];
        memcpy(c,_c[(int)conf[0]],sizeof(double)*mol.NumAtoms()*3);

        for (j = 0;j < _vrotor.size();j++)
        {
            angle = invres*((double)conf[j+1]);
            if (angle > 180.0)
                angle -= 360.0;
            SetRotorToAngle(c,_vrotor[j].first,angle,_vrotor[j].second);
        }
        tmpclist.push_back(c);
    }

    return tmpclist;
}

//Copies the coordinates in bc, NOT the pointers, into the object
void OBRotamerList::SetBaseCoordinateSets(vector<double*> bc, unsigned int N)
{
    unsigned int i,j;

    //Clear out old data
    for (i=0 ; i<_c.size() ; i++)
        delete [] _c[i];
    _c.clear();

    //Copy new data
    double *c = NULL;
    double *cc= NULL;
    for (i=0 ; i<bc.size() ; i++)
    {
        c = new double [3*N];
        cc = bc[i];
        for (j=0 ; j<3*N ; j++)
            c[j] = cc[j];
        _c.push_back(c);
    }
    _NBaseCoords = N;
}

//! Rotate the coordinates of 'atoms'
//! such that tor == ang - atoms in 'tor' should be ordered such 
//! that the 3rd atom is the pivot around which atoms rotate
//! ang is in degrees
void SetRotorToAngle(double *c, OBAtom **ref,double ang,vector<int> atoms)
{
  double v1x,v1y,v1z,v2x,v2y,v2z,v3x,v3y,v3z;
  double c1x,c1y,c1z,c2x,c2y,c2z,c3x,c3y,c3z;
  double c1mag,c2mag,radang,costheta,m[9];
  double x,y,z,mag,rotang,sn,cs,t,tx,ty,tz;

  int tor[4];
  tor[0] = ref[0]->GetCIdx();
  tor[1] = ref[1]->GetCIdx();
  tor[2] = ref[2]->GetCIdx();
  tor[3] = ref[3]->GetCIdx();

  //
  //calculate the torsion angle
  //
  v1x = c[tor[0]]   - c[tor[1]];   v2x = c[tor[1]]   - c[tor[2]];
  v1y = c[tor[0]+1] - c[tor[1]+1]; v2y = c[tor[1]+1] - c[tor[2]+1];
  v1z = c[tor[0]+2] - c[tor[1]+2]; v2z = c[tor[1]+2] - c[tor[2]+2];
  v3x = c[tor[2]]   - c[tor[3]];
  v3y = c[tor[2]+1] - c[tor[3]+1];
  v3z = c[tor[2]+2] - c[tor[3]+2];

  c1x = v1y*v2z - v1z*v2y;   c2x = v2y*v3z - v2z*v3y;
  c1y = -v1x*v2z + v1z*v2x;  c2y = -v2x*v3z + v2z*v3x;
  c1z = v1x*v2y - v1y*v2x;   c2z = v2x*v3y - v2y*v3x;
  c3x = c1y*c2z - c1z*c2y;
  c3y = -c1x*c2z + c1z*c2x;
  c3z = c1x*c2y - c1y*c2x; 
  
  c1mag = c1x*c1x + c1y*c1y + c1z*c1z;
  c2mag = c2x*c2x + c2y*c2y + c2z*c2z;
  if (c1mag*c2mag < 0.01) costheta = 1.0; //avoid div by zero error
  else costheta = (c1x*c2x + c1y*c2y + c1z*c2z)/(sqrt(c1mag*c2mag));

  if (costheta < -0.999999) costheta = -0.999999f;
  if (costheta >  0.999999) costheta =  0.999999f;
                              
  if ((v2x*c3x + v2y*c3y + v2z*c3z) > 0.0) radang = -acos(costheta);
  else                                     radang = acos(costheta);

  //
  // now we have the torsion angle (radang) - set up the rot matrix
  //

  //find the difference between current and requested
  rotang = (DEG_TO_RAD*ang) - radang; 

  sn = sin(rotang); cs = cos(rotang);t = 1 - cs;
  //normalize the rotation vector
  mag = sqrt(v2x*v2x + v2y*v2y + v2z*v2z);
  x = v2x/mag; y = v2y/mag; z = v2z/mag;
  
  //set up the rotation matrix
  m[0]= t*x*x + cs;     m[1] = t*x*y + sn*z;  m[2] = t*x*z - sn*y;
  m[3] = t*x*y - sn*z;  m[4] = t*y*y + cs;    m[5] = t*y*z + sn*x;
  m[6] = t*x*z + sn*y;  m[7] = t*y*z - sn*x;  m[8] = t*z*z + cs;

  //
  //now the matrix is set - time to rotate the atoms
  //
  tx = c[tor[1]];ty = c[tor[1]+1];tz = c[tor[1]+2];
  vector<int>::iterator i;int j;
  for (i = atoms.begin();i != atoms.end();i++)
    {
      j = ((*i)-1)*3;
      c[j] -= tx;c[j+1] -= ty;c[j+2]-= tz;
      x = c[j]*m[0] + c[j+1]*m[1] + c[j+2]*m[2];
      y = c[j]*m[3] + c[j+1]*m[4] + c[j+2]*m[5];
      z = c[j]*m[6] + c[j+1]*m[7] + c[j+2]*m[8];
      c[j] = x; c[j+1] = y; c[j+2] = z;
      c[j] += tx;c[j+1] += ty;c[j+2] += tz;
    }
}

int PackCoordinate(double c[3],double max[3])
{
    int tmp;
    float cf;
    cf = c[0];
    tmp  = ((int)(cf*max[0])) << 20;
    cf = c[1];
    tmp |= ((int)(cf*max[1])) << 10;
    cf = c[2];
    tmp |= ((int)(cf*max[2]));
    return(tmp);
}

void UnpackCoordinate(double c[3],double max[3],int tmp)
{
    float cf;
    cf = (float)(tmp>>20);
    c[0] = cf;
    c[0] *= max[0];
    cf = (float)((tmp&0xffc00)>>10);
    c[1] = cf;
    c[1] *= max[1];
    cf = (float)(tmp&0x3ff);
    c[2] = cf;
    c[2] *= max[2];
}

} //namespace OpenBabel

//! \file rotamer.cpp
//! \brief Handle rotamer list data.
Revision:	2440
Committed:	Wed Nov 16 19:42:11 2005 UTC (18 years, 7 months ago) by tim
File size:	12652 byte(s)
Log Message:	adding openbabel
#	Content
1	/**********************************************************************
2	rotamer.cpp - Handle rotamer list data.
3
4	Copyright (C) 1998, 1999, 2000-2002 OpenEye Scientific Software, Inc.
5	Some portions Copyright (C) 2001-2005 by Geoffrey R. Hutchison
6
7	This file is part of the Open Babel project.
8	For more information, see <http://openbabel.sourceforge.net/>
9
10	This program is free software; you can redistribute it and/or modify
11	it under the terms of the GNU General Public License as published by
12	the Free Software Foundation version 2 of the License.
13
14	This program is distributed in the hope that it will be useful,
15	but WITHOUT ANY WARRANTY; without even the implied warranty of
16	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17	GNU General Public License for more details.
18	***********************************************************************/
19
20	#include "rotamer.hpp"
21	#include "mol.hpp"
22	#include "obutil.hpp"
23	#include "rotor.hpp"
24
25	#define OB_TITLE_SIZE 254
26	#define OB_BINARY_SETWORD 32
27
28	using namespace std;
29
30	namespace OpenBabel
31	{
32
33	//test byte ordering
34	static int SINT = 0x00000001;
35	static unsigned char STPTR = (unsigned char)&SINT;
36	const bool SwabInt = (STPTR[0]!=0);
37
38	#if !HAVE_RINT
39	inline double rint(double x)
40	{
41	return ( (x < 0.0) ? ceil(x-0.5) : floor(x+0.5));
42	}
43	#endif
44
45	void SetRotorToAngle(double c,OBAtom *ref,double ang,vector<int> atoms);
46
47	int Swab(int i)
48	{
49	unsigned char tmp[4],c;
50	memcpy(tmp,(char*)&i,sizeof(int));
51	c = tmp[0];
52	tmp[0] = tmp[3];
53	tmp[3] = c;
54	c = tmp[1];
55	tmp[1] = tmp[2];
56	tmp[2] = c;
57	memcpy((char*)&i,tmp,sizeof(int));
58	return(i);
59	}
60
61	OBRotamerList::~OBRotamerList()
62	{
63	vector<unsigned char*>::iterator i;
64	for (i = _vrotamer.begin();i != _vrotamer.end();i++)
65	delete [] *i;
66
67	vector<pair<OBAtom**,vector<int> > >::iterator j;
68	for (j = _vrotor.begin();j != _vrotor.end();j++)
69	delete [] j->first;
70
71	//Delete the interal base coordinate list
72	unsigned int k;
73	for (k=0 ; k<_c.size() ; k++)
74	delete [] _c[k];
75	}
76
77	void OBRotamerList::GetReferenceArray(unsigned char *ref)
78	{
79	int j;
80	vector<pair<OBAtom**,vector<int> > >::iterator i;
81	for (j=0,i = _vrotor.begin();i != _vrotor.end();i++)
82	{
83	ref[j++] = (unsigned char)(i->first[0])->GetIdx();
84	ref[j++] = (unsigned char)(i->first[1])->GetIdx();
85	ref[j++] = (unsigned char)(i->first[2])->GetIdx();
86	ref[j++] = (unsigned char)(i->first[3])->GetIdx();
87	}
88	}
89
90	void OBRotamerList::Setup(OBMol &mol,OBRotorList &rl)
91	{
92	//clear the old stuff out if necessary
93	_vres.clear();
94	vector<unsigned char*>::iterator j;
95	for (j = _vrotamer.begin();j != _vrotamer.end();j++)
96	delete [] *j;
97	_vrotamer.clear();
98
99	vector<pair<OBAtom**,vector<int> > >::iterator k;
100	for (k = _vrotor.begin();k != _vrotor.end();k++)
101	delete [] k->first;
102	_vrotor.clear();
103
104	//create the new list
105	OBRotor *rotor;
106	vector<OBRotor*>::iterator i;
107	vector<int> children;
108
109	int ref[4];
110	OBAtom **atomlist;
111	for (rotor = rl.BeginRotor(i);rotor;rotor = rl.NextRotor(i))
112	{
113	atomlist = new OBAtom* [4];
114	rotor->GetDihedralAtoms(ref);
115	atomlist[0] = mol.GetAtom(ref[0]);
116	atomlist[1] = mol.GetAtom(ref[1]);
117	atomlist[2] = mol.GetAtom(ref[2]);
118	atomlist[3] = mol.GetAtom(ref[3]);
119	mol.FindChildren(children,ref[1],ref[2]);
120	_vrotor.push_back(pair<OBAtom**,vector<int> > (atomlist,children));
121	_vres.push_back(rotor->GetResolution());
122	}
123
124	vector<double>::iterator n;
125	vector<vector<double> >::iterator m;
126	for (m = _vres.begin();m != _vres.end();m++)
127	for (n = m->begin();n != m->end();n++)
128	n = RAD_TO_DEG;
129	}
130
131	void OBRotamerList::Setup(OBMol &mol,unsigned char *ref,int nrotors)
132	{
133	//clear the old stuff out if necessary
134	_vres.clear();
135	vector<unsigned char*>::iterator j;
136	for (j = _vrotamer.begin();j != _vrotamer.end();j++)
137	delete [] *j;
138	_vrotamer.clear();
139
140	vector<pair<OBAtom**,vector<int> > >::iterator k;
141	for (k = _vrotor.begin();k != _vrotor.end();k++)
142	delete [] k->first;
143	_vrotor.clear();
144
145	//create the new list
146	int i;
147	vector<int> children;
148
149	int refatoms[4];
150	OBAtom **atomlist;
151	for (i = 0; i < nrotors; i++)
152	{
153	atomlist = new OBAtom* [4];
154	refatoms[0] = (int)ref[i*4 ];
155	refatoms[1] = (int)ref[i*4+1];
156	refatoms[2] = (int)ref[i*4+2];
157	refatoms[3] = (int)ref[i*4+3];
158	mol.FindChildren(children,refatoms[1],refatoms[2]);
159	atomlist[0] = mol.GetAtom(refatoms[0]);
160	atomlist[1] = mol.GetAtom(refatoms[1]);
161	atomlist[2] = mol.GetAtom(refatoms[2]);
162	atomlist[3] = mol.GetAtom(refatoms[3]);
163	_vrotor.push_back(pair<OBAtom**,vector<int> > (atomlist,children));
164	}
165
166	}
167
168	void OBRotamerList::AddRotamer(double *c)
169	{
170	int idx,size;
171	double angle,res=255.0f/360.0f;
172	vector3 v1,v2,v3,v4;
173
174	unsigned char *rot = new unsigned char [_vrotor.size()+1];
175	rot[0] = (char) 0;
176
177	vector<pair<OBAtom**,vector<int> > >::iterator i;
178	for (size=1,i = _vrotor.begin();i != _vrotor.end();i++,size++)
179	{
180	idx = (i->first[0])->GetCIdx();
181	v1.Set(c[idx],c[idx+1],c[idx+2]);
182	idx = (i->first[1])->GetCIdx();
183	v2.Set(c[idx],c[idx+1],c[idx+2]);
184	idx = (i->first[2])->GetCIdx();
185	v3.Set(c[idx],c[idx+1],c[idx+2]);
186	idx = (i->first[3])->GetCIdx();
187	v4.Set(c[idx],c[idx+1],c[idx+2]);
188
189	angle = CalcTorsionAngle(v1,v2,v3,v4);
190	while (angle < 0.0f)
191	angle += 360.0f;
192	while (angle > 360.0f)
193	angle -= 360.0f;
194	rot[size] = (unsigned char)rint(angle*res);
195	}
196
197	_vrotamer.push_back(rot);
198	}
199
200	void OBRotamerList::AddRotamer(int *arr)
201	{
202	unsigned int i;
203	double angle,res=255.0f/360.0f;
204
205	unsigned char *rot = new unsigned char [_vrotor.size()+1];
206	rot[0] = (unsigned char)arr[0];
207
208	for (i = 0;i < _vrotor.size();i++)
209	{
210	angle = _vres[i][arr[i+1]];
211	while (angle < 0.0f)
212	angle += 360.0f;
213	while (angle > 360.0f)
214	angle -= 360.0f;
215	rot[i+1] = (unsigned char)rint(angle*res);
216	}
217	_vrotamer.push_back(rot);
218	}
219
220	void OBRotamerList::AddRotamer(unsigned char *arr)
221	{
222	unsigned int i;
223	double angle,res=255.0f/360.0f;
224
225	unsigned char *rot = new unsigned char [_vrotor.size()+1];
226	rot[0] = (unsigned char)arr[0];
227
228	for (i = 0;i < _vrotor.size();i++)
229	{
230	angle = _vres[i][(int)arr[i+1]];
231	while (angle < 0.0f)
232	angle += 360.0f;
233	while (angle > 360.0f)
234	angle -= 360.0f;
235	rot[i+1] = (unsigned char)rint(angle*res);
236	}
237	_vrotamer.push_back(rot);
238	}
239
240	void OBRotamerList::AddRotamers(unsigned char *arr,int nrotamers)
241	{
242	unsigned int size;
243	int i;
244
245	size = (unsigned int)_vrotor.size()+1;
246	for (i = 0;i < nrotamers;i++)
247	{
248	unsigned char *rot = new unsigned char [size];
249	memcpy(rot,&arr[isize],sizeof(char)size);
250	_vrotamer.push_back(rot);
251	}
252	}
253
254	void OBRotamerList::ExpandConformerList(OBMol &mol,vector<double*> &clist)
255	{
256	unsigned int j;
257	double angle,invres=360.0f/255.0f;
258	unsigned char *conf;
259	vector<double*> tmpclist;
260	vector<unsigned char*>::iterator i;
261
262	for (i = _vrotamer.begin();i != _vrotamer.end();i++)
263	{
264	conf = *i;
265	double c = new double [mol.NumAtoms()3];
266	memcpy(c,clist[(int)conf[0]],sizeof(double)mol.NumAtoms()3);
267
268	for (j = 0;j < _vrotor.size();j++)
269	{
270	angle = invres*((double)conf[j+1]);
271	if (angle > 180.0)
272	angle -= 360.0;
273	SetRotorToAngle(c,_vrotor[j].first,angle,_vrotor[j].second);
274	}
275	tmpclist.push_back(c);
276	}
277
278	//transfer the conf list
279	vector<double*>::iterator k;
280	for (k = clist.begin();k != clist.end();k++)
281	delete [] *k;
282	clist = tmpclist;
283	}
284
285	//! Create a conformer list using the internal base set of coordinates
286	vector<double*> OBRotamerList::CreateConformerList(OBMol& mol)
287	{
288	unsigned int j;
289	double angle,invres=360.0f/255.0f;
290	unsigned char *conf;
291	vector<double*> tmpclist;
292	vector<unsigned char*>::iterator i;
293
294	for (i = _vrotamer.begin();i != _vrotamer.end();i++)
295	{
296	conf = *i;
297	double c = new double [mol.NumAtoms()3];
298	memcpy(c,_c[(int)conf[0]],sizeof(double)mol.NumAtoms()3);
299
300	for (j = 0;j < _vrotor.size();j++)
301	{
302	angle = invres*((double)conf[j+1]);
303	if (angle > 180.0)
304	angle -= 360.0;
305	SetRotorToAngle(c,_vrotor[j].first,angle,_vrotor[j].second);
306	}
307	tmpclist.push_back(c);
308	}
309
310	return tmpclist;
311	}
312
313	//Copies the coordinates in bc, NOT the pointers, into the object
314	void OBRotamerList::SetBaseCoordinateSets(vector<double*> bc, unsigned int N)
315	{
316	unsigned int i,j;
317
318	//Clear out old data
319	for (i=0 ; i<_c.size() ; i++)
320	delete [] _c[i];
321	_c.clear();
322
323	//Copy new data
324	double *c = NULL;
325	double *cc= NULL;
326	for (i=0 ; i<bc.size() ; i++)
327	{
328	c = new double [3*N];
329	cc = bc[i];
330	for (j=0 ; j<3*N ; j++)
331	c[j] = cc[j];
332	_c.push_back(c);
333	}
334	_NBaseCoords = N;
335	}
336
337	//! Rotate the coordinates of 'atoms'
338	//! such that tor == ang - atoms in 'tor' should be ordered such
339	//! that the 3rd atom is the pivot around which atoms rotate
340	//! ang is in degrees
341	void SetRotorToAngle(double c, OBAtom *ref,double ang,vector<int> atoms)
342	{
343	double v1x,v1y,v1z,v2x,v2y,v2z,v3x,v3y,v3z;
344	double c1x,c1y,c1z,c2x,c2y,c2z,c3x,c3y,c3z;
345	double c1mag,c2mag,radang,costheta,m[9];
346	double x,y,z,mag,rotang,sn,cs,t,tx,ty,tz;
347
348	int tor[4];
349	tor[0] = ref[0]->GetCIdx();
350	tor[1] = ref[1]->GetCIdx();
351	tor[2] = ref[2]->GetCIdx();
352	tor[3] = ref[3]->GetCIdx();
353
354	//
355	//calculate the torsion angle
356	//
357	v1x = c[tor[0]] - c[tor[1]]; v2x = c[tor[1]] - c[tor[2]];
358	v1y = c[tor[0]+1] - c[tor[1]+1]; v2y = c[tor[1]+1] - c[tor[2]+1];
359	v1z = c[tor[0]+2] - c[tor[1]+2]; v2z = c[tor[1]+2] - c[tor[2]+2];
360	v3x = c[tor[2]] - c[tor[3]];
361	v3y = c[tor[2]+1] - c[tor[3]+1];
362	v3z = c[tor[2]+2] - c[tor[3]+2];
363
364	c1x = v1yv2z - v1zv2y; c2x = v2yv3z - v2zv3y;
365	c1y = -v1xv2z + v1zv2x; c2y = -v2xv3z + v2zv3x;
366	c1z = v1xv2y - v1yv2x; c2z = v2xv3y - v2yv3x;
367	c3x = c1yc2z - c1zc2y;
368	c3y = -c1xc2z + c1zc2x;
369	c3z = c1xc2y - c1yc2x;
370
371	c1mag = c1xc1x + c1yc1y + c1z*c1z;
372	c2mag = c2xc2x + c2yc2y + c2z*c2z;
373	if (c1mag*c2mag < 0.01) costheta = 1.0; //avoid div by zero error
374	else costheta = (c1xc2x + c1yc2y + c1zc2z)/(sqrt(c1magc2mag));
375
376	if (costheta < -0.999999) costheta = -0.999999f;
377	if (costheta > 0.999999) costheta = 0.999999f;
378
379	if ((v2xc3x + v2yc3y + v2z*c3z) > 0.0) radang = -acos(costheta);
380	else radang = acos(costheta);
381
382	//
383	// now we have the torsion angle (radang) - set up the rot matrix
384	//
385
386	//find the difference between current and requested
387	rotang = (DEG_TO_RAD*ang) - radang;
388
389	sn = sin(rotang); cs = cos(rotang);t = 1 - cs;
390	//normalize the rotation vector
391	mag = sqrt(v2xv2x + v2yv2y + v2z*v2z);
392	x = v2x/mag; y = v2y/mag; z = v2z/mag;
393
394	//set up the rotation matrix
395	m[0]= txx + cs; m[1] = txy + snz; m[2] = txz - sny;
396	m[3] = txy - snz; m[4] = tyy + cs; m[5] = tyz + snx;
397	m[6] = txz + sny; m[7] = tyz - snx; m[8] = tzz + cs;
398
399	//
400	//now the matrix is set - time to rotate the atoms
401	//
402	tx = c[tor[1]];ty = c[tor[1]+1];tz = c[tor[1]+2];
403	vector<int>::iterator i;int j;
404	for (i = atoms.begin();i != atoms.end();i++)
405	{
406	j = ((i)-1)3;
407	c[j] -= tx;c[j+1] -= ty;c[j+2]-= tz;
408	x = c[j]m[0] + c[j+1]m[1] + c[j+2]*m[2];
409	y = c[j]m[3] + c[j+1]m[4] + c[j+2]*m[5];
410	z = c[j]m[6] + c[j+1]m[7] + c[j+2]*m[8];
411	c[j] = x; c[j+1] = y; c[j+2] = z;
412	c[j] += tx;c[j+1] += ty;c[j+2] += tz;
413	}
414	}
415
416	int PackCoordinate(double c[3],double max[3])
417	{
418	int tmp;
419	float cf;
420	cf = c[0];
421	tmp = ((int)(cf*max[0])) << 20;
422	cf = c[1];
423	tmp \|= ((int)(cf*max[1])) << 10;
424	cf = c[2];
425	tmp \|= ((int)(cf*max[2]));
426	return(tmp);
427	}
428
429	void UnpackCoordinate(double c[3],double max[3],int tmp)
430	{
431	float cf;
432	cf = (float)(tmp>>20);
433	c[0] = cf;
434	c[0] *= max[0];
435	cf = (float)((tmp&0xffc00)>>10);
436	c[1] = cf;
437	c[1] *= max[1];
438	cf = (float)(tmp&0x3ff);
439	c[2] = cf;
440	c[2] *= max[2];
441	}
442
443	} //namespace OpenBabel
444
445	//! \file rotamer.cpp
446	//! \brief Handle rotamer list data.