/********************************************************************** obrotate = rotate a tortional bond matched by a SMART pattern Copyright (C) 2003 Fabien Fontaine Some portions Copyright (C) 2004-2005 Geoffrey R. Hutchison Some portions Copyright (C) 2008 Tim Vandermeersch This file is part of the Open Babel project. For more information, see 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. ***********************************************************************/ /* Require a SMART pattern, a file containing molecule coordinates 4 atoms of the SMART pattern to define the tortional, an angle value The angle value must be in degree the 2 atoms of the rotating bond must be bonded but the 2 others not the part of the molecule on the side of the second atom is kept fixed whereas the part on the side of the third atom is rotated. example of command line: obrotate "[nH]ccccc[O,C][C,O]" test.sdf 1 6 7 8 180.0 */ // used to set import/export for Cygwin DLLs #ifdef WIN32 #define USING_OBDLL #endif #include #include #include #include #include //#include #include #include using namespace std; using namespace OpenBabel; /////////////////////////////////////////////////////////////////////////////// //! \brief Set a tortional bond to a given angle int main(int argc,char **argv) { OBAtom *a1, *a2, *a3, *a4; unsigned int smartor[4]= {0,0,0,0};// atoms of the tortional in the SMART float angle = 0; // tortional angle value to set in degree char *FileIn = nullptr, *Pattern = nullptr; unsigned int i, t, errflg = 0; int c; string err; bool changeAll = false; // default to only change the last matching torsion // parse the command line -- optional -a flag to change all matching torsions if (argc < 8 || argc > 9) { errflg++; } else { // Fetch the option and shift values after the option if (argc == 9) { int curArg = 0; while (curArg < 9) { if (strcmp(argv[curArg], "-a") == 0) { changeAll = true; break; } ++curArg; } // We expect -a and so changeAll should be true if (!changeAll) errflg++; // now let's shift values while (curArg < 8) { argv[curArg] = argv[curArg+1]; } } FileIn = argv[2]; Pattern = argv[1]; // Read the atom position for(i=3, t=0; i<7; ++i, ++t) { c = sscanf(argv[i], "%u", &smartor[t]); if (c != 1) { errflg++; // error in arguments, quit and warn user break; } } c = sscanf(argv[7], "%f", &angle); if (c != 1) { errflg++; // error in arguments, quit and warn user } if (argc == 9) { if (strcmp(argv[8], "-a") == 0) changeAll = true; else errflg++; // error in arguments, quit and warn user } } if (errflg) { cerr << "Usage: obrotate \"PATTERN\" [-a]" << endl; exit(-1); } // create pattern OBSmartsPattern sp; sp.Init(Pattern); if (sp.NumAtoms() < 4) { cerr << "obrotate: The number of atoms in the SMART pattern must be higher than 3." << endl; exit(-1); } for (i=0; i<4; ++i) { if ( smartor[i] < 1 || smartor[i] > sp.NumAtoms()) { cerr << "obrotate: The torsional atom values must be between 1 and " << sp.NumAtoms() << ", which is the number of atoms in the SMART pattern." << endl; exit(-1); } } OBConversion conv; //NF... OBFormat* format = conv.FormatFromExt(FileIn); if(!(format && conv.SetInAndOutFormats(format, format))) { //in and out formats same cerr << "obrotate: cannot read and/or write this file format!" << endl; exit (-1); } //...NF //Open the molecule file ifstream ifs; // Read the file ifs.open(FileIn); if (!ifs) { cerr << "obrotate: cannot read input file!" << endl; exit (-1); } OBMol mol; vector< vector > maplist; // list of matched atoms vector< vector >::iterator m; // and its iterators // int tindex; // Set the angles for (;;) { mol.Clear(); //NF ifs >> mol; // Read molecule conv.Read(&mol,&ifs); //NF if (mol.Empty()) break; if (sp.Match(mol)) { // if match perform rotation maplist = sp.GetUMapList(); // get unique matches if (maplist.size() > 1) cerr << "obrotate: Found " << maplist.size() << " matches. Only last one will be rotated." << endl; // look at all the mapping atom but save only the last one. for (m = maplist.begin(); m != maplist.end(); ++m) { a1 = mol.GetAtom( (*m)[ smartor[0] - 1] ); a2 = mol.GetAtom( (*m)[ smartor[1] - 1] ); a3 = mol.GetAtom( (*m)[ smartor[2] - 1] ); a4 = mol.GetAtom( (*m)[ smartor[3] - 1] ); if (changeAll) mol.SetTorsion(a1, a2, a3, a4, angle * DEG_TO_RAD); } if ( !a2->IsConnected(a3) ) { cerr << "obrotate: The atoms of the rotating bond must be bonded." << endl; exit(-1); } if (!changeAll) mol.SetTorsion(a1, a2, a3, a4, angle * DEG_TO_RAD); } else { cerr << "obrotate: Found 0 matches for the SMARTS pattern." << endl; exit(-1); } //NF cout << mol; conv.Write(&mol,&cout); //NF } return(0); } /* obrotate man page*/ /** \page obrotate batch-rotate dihedral angles matching SMARTS patterns * * \n * \par SYNOPSIS * * \b obrotate '' \ \ \ \ \ \ * * \par DESCRIPTION * * The obrotate program rotates the torsional (dihedral) angle of a specified * bond in molecules to that defined by the user. In other words, it does the * same as a user setting an angle in a molecular modelling package, but much * faster and in batch mode. * \n\n * The four atom IDs required are indexes into the SMARTS pattern, which starts * at atom 1. The angle supplied is in degrees. The two atoms used to set * the dihedral angle \ and \ do not need to be connected * to the atoms of the bond \ and \ in any way. *\n\n * The order of the atoms matters -- the portion of the molecule attached to * \ and \ remain fixed, but the portion bonded to \ and & \ moves. * * \par EXAMPLES * - Let's say that you want to define the conformation of a large number of * molecules with a pyridyl scaffold and substituted with an aliphatic chain * at the 3-position, for example for docking or 3D-QSAR purposes. * \n\n * To set the value of the first dihedral angle to 90 degrees:\n * obrotate "c1ccncc1CCC" pyridines.sdf 5 6 7 8 90 * \n * Here 6 and 7 define the bond to rotate in the SMARTS patter, i.e., c1-C and * atoms 5 and 8 define the particular dihedral angle to rotate. * - Since the atoms to define the dihedral do not need to be directly * connected, the nitrogen in the pyridine can be used:\n * obrotate "c1ccncc1CCC" pyridines.sdf 4 6 7 8 90 * * - Keep the pyridyl ring fixed and moves the aliphatic chain:\n * obrotate "c1ccncc1CCC" pyridines.sdf 5 6 7 8 90 * - Keep the aliphatic chain fixed and move the pyridyl ring:\n * obrotate "c1ccncc1CCC" pyridines.sdf 8 7 6 5 90 * * \par AUTHORS * * The obrotate program was contributed by \b Fabien \b Fontaine. * * Open Babel is currently maintained by \b Geoff \b Hutchison, \b Chris \b Morley and \b Michael \b Banck. * * For more contributors to Open Babel, see http://openbabel.org/THANKS.shtml * * \par COPYRIGHT * Copyright (C) 1998-2001 by OpenEye Scientific Software, Inc. * Some portions Copyright (C) 2001-2005 by Geoffrey R. Hutchison \n \n * 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.\n \n * 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. * * \par SEE ALSO * The web pages for Open Babel can be found at: http://openbabel.org/ \n * A guide for constructing SMARTS patterns can be found at: http://www.daylight.com/dayhtml/doc/theory/theory.smarts.html **/