src/brains/ForceField.cpp

/*
 * Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
 *
 * The University of Notre Dame grants you ("Licensee") a
 * non-exclusive, royalty free, license to use, modify and
 * redistribute this software in source and binary code form, provided
 * that the following conditions are met:
 *
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 *
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the
 *    distribution.
 *
 * This software is provided "AS IS," without a warranty of any
 * kind. All express or implied conditions, representations and
 * warranties, including any implied warranty of merchantability,
 * fitness for a particular purpose or non-infringement, are hereby
 * excluded.  The University of Notre Dame and its licensors shall not
 * be liable for any damages suffered by licensee as a result of
 * using, modifying or distributing the software or its
 * derivatives. In no event will the University of Notre Dame or its
 * licensors be liable for any lost revenue, profit or data, or for
 * direct, indirect, special, consequential, incidental or punitive
 * damages, however caused and regardless of the theory of liability,
 * arising out of the use of or inability to use software, even if the
 * University of Notre Dame has been advised of the possibility of
 * such damages.
 *
 * SUPPORT OPEN SCIENCE!  If you use OpenMD or its source code in your
 * research, please cite the appropriate papers when you publish your
 * work.  Good starting points are:
 *                                                                      
 * [1]  Meineke, et al., J. Comp. Chem. 26, 252-271 (2005).             
 * [2]  Fennell & Gezelter, J. Chem. Phys. 124, 234104 (2006).          
 * [3]  Sun, Lin & Gezelter, J. Chem. Phys. 128, 24107 (2008).          
 * [4]  Vardeman & Gezelter, in progress (2009).                        
 */
 
/**
 * @file ForceField.cpp
 * @author tlin
 * @date 11/04/2004
 * @time 22:51am
 * @version 1.0
 */
  
#include <algorithm>
#include "UseTheForce/ForceField.hpp"
#include "utils/simError.h"
#include "utils/Tuple.hpp"
namespace OpenMD {

  ForceField::ForceField() { 

    char* tempPath; 
    tempPath = getenv("FORCE_PARAM_PATH");
    
    if (tempPath == NULL) {
      //convert a macro from compiler to a string in c++
      STR_DEFINE(ffPath_, FRC_PATH );
    } else {
      ffPath_ = tempPath;
    }
  }

  /**
   * getAtomType by string
   *
   * finds the requested atom type in this force field using the string
   * name of the atom type.
   */
  AtomType* ForceField::getAtomType(const std::string &at) {
    std::vector<std::string> keys;
    keys.push_back(at);
    return atomTypeCont_.find(keys);
  }

  /**
   * getAtomType by ident
   *
   * finds the requested atom type in this force field using the
   * integer ident instead of the string name of the atom type.
   */
  AtomType* ForceField::getAtomType(int ident) {   
    std::string at = atypeIdentToName.find(ident)->second;
    return getAtomType(at);
  }

  BondType* ForceField::getBondType(const std::string &at1, 
                                    const std::string &at2) {
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    

    //try exact match first
    BondType* bondType = bondTypeCont_.find(keys);
    if (bondType) {
      return bondType;
    } else {
      AtomType* atype1;
      AtomType* atype2;
      std::vector<std::string> at1key;
      at1key.push_back(at1);
      atype1 = atomTypeCont_.find(at1key);
  
      std::vector<std::string> at2key;
      at2key.push_back(at2);
      atype2 = atomTypeCont_.find(at2key);

      // query atom types for their chains of responsibility
      std::vector<AtomType*> at1Chain = atype1->allYourBase();
      std::vector<AtomType*> at2Chain = atype2->allYourBase();

      std::vector<AtomType*>::iterator i;
      std::vector<AtomType*>::iterator j;

      int ii = 0;
      int jj = 0;
      int bondTypeScore;

      std::vector<std::pair<int, std::vector<std::string> > > foundBonds;

      for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
        jj = 0;
        for (j = at2Chain.begin(); j != at2Chain.end(); j++) {

          bondTypeScore = ii + jj;

          std::vector<std::string> myKeys;
          myKeys.push_back((*i)->getName());
          myKeys.push_back((*j)->getName());

          BondType* bondType = bondTypeCont_.find(myKeys);
          if (bondType) {
            foundBonds.push_back(std::make_pair(bondTypeScore, myKeys));
          }
          jj++;
        }
        ii++;
      }


      if (foundBonds.size() > 0) {
        // sort the foundBonds by the score:
        std::sort(foundBonds.begin(), foundBonds.end());
     
        int bestScore = foundBonds[0].first;
        std::vector<std::string> theKeys = foundBonds[0].second;
        
        BondType* bestType = bondTypeCont_.find(theKeys);
        
        return bestType;
      } else {
        //if no exact match found, try wild card match
        return bondTypeCont_.find(keys, wildCardAtomTypeName_);      
      }
    }
  }
  
  BendType* ForceField::getBendType(const std::string &at1, 
                                    const std::string &at2,
                                    const std::string &at3) {
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    keys.push_back(at3);    

    //try exact match first
    BendType* bendType = bendTypeCont_.find(keys);
    if (bendType) {
      return bendType;
    } else {

      AtomType* atype1;
      AtomType* atype2;
      AtomType* atype3;
      std::vector<std::string> at1key;
      at1key.push_back(at1);
      atype1 = atomTypeCont_.find(at1key);
  
      std::vector<std::string> at2key;
      at2key.push_back(at2);
      atype2 = atomTypeCont_.find(at2key);

      std::vector<std::string> at3key;
      at3key.push_back(at3);
      atype3 = atomTypeCont_.find(at3key);

      // query atom types for their chains of responsibility
      std::vector<AtomType*> at1Chain = atype1->allYourBase();
      std::vector<AtomType*> at2Chain = atype2->allYourBase();
      std::vector<AtomType*> at3Chain = atype3->allYourBase();

      std::vector<AtomType*>::iterator i;
      std::vector<AtomType*>::iterator j;
      std::vector<AtomType*>::iterator k;

      int ii = 0;
      int jj = 0;
      int kk = 0;
      int IKscore;

      std::vector<tuple3<int, int, std::vector<std::string> > > foundBends;

      for (j = at2Chain.begin(); j != at2Chain.end(); j++) {
        ii = 0;
        for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
          kk = 0;
          for (k = at3Chain.begin(); k != at3Chain.end(); k++) {
          
            IKscore = ii + kk;

            std::vector<std::string> myKeys;
            myKeys.push_back((*i)->getName());
            myKeys.push_back((*j)->getName());
            myKeys.push_back((*k)->getName());

            BendType* bendType = bendTypeCont_.find(myKeys);
            if (bendType) { 
              foundBends.push_back( make_tuple3(jj, IKscore, myKeys) );
            }
            kk++;
          }
          ii++;
        }
        jj++;
      }
      
      if (foundBends.size() > 0) {
        std::sort(foundBends.begin(), foundBends.end());
        int jscore = foundBends[0].first;
        int ikscore = foundBends[0].second;
        std::vector<std::string> theKeys = foundBends[0].third;       
        
        BendType* bestType = bendTypeCont_.find(theKeys);  
        return bestType;
      } else {        
        //if no exact match found, try wild card match
        return bendTypeCont_.find(keys, wildCardAtomTypeName_);      
      }
    }
  }

  TorsionType* ForceField::getTorsionType(const std::string &at1, 
                                          const std::string &at2,
                                          const std::string &at3, 
                                          const std::string &at4) {
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    keys.push_back(at3);    
    keys.push_back(at4);    


    //try exact match first
    TorsionType* torsionType = torsionTypeCont_.find(keys);
    if (torsionType) {
      return torsionType;
    } else {

      AtomType* atype1;
      AtomType* atype2;
      AtomType* atype3;
      AtomType* atype4;
      std::vector<std::string> at1key;
      at1key.push_back(at1);
      atype1 = atomTypeCont_.find(at1key);
  
      std::vector<std::string> at2key;
      at2key.push_back(at2);
      atype2 = atomTypeCont_.find(at2key);

      std::vector<std::string> at3key;
      at3key.push_back(at3);
      atype3 = atomTypeCont_.find(at3key);

      std::vector<std::string> at4key;
      at4key.push_back(at4);
      atype4 = atomTypeCont_.find(at4key);

      // query atom types for their chains of responsibility
      std::vector<AtomType*> at1Chain = atype1->allYourBase();
      std::vector<AtomType*> at2Chain = atype2->allYourBase();
      std::vector<AtomType*> at3Chain = atype3->allYourBase();
      std::vector<AtomType*> at4Chain = atype4->allYourBase();

      std::vector<AtomType*>::iterator i;
      std::vector<AtomType*>::iterator j;
      std::vector<AtomType*>::iterator k;
      std::vector<AtomType*>::iterator l;

      int ii = 0;
      int jj = 0;
      int kk = 0;
      int ll = 0;
      int ILscore;
      int JKscore;

      std::vector<tuple3<int, int, std::vector<std::string> > > foundTorsions;

      for (j = at2Chain.begin(); j != at2Chain.end(); j++) {
        kk = 0;
        for (k = at3Chain.begin(); k != at3Chain.end(); k++) {
          ii = 0;       
          for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
            ll = 0;
            for (l = at4Chain.begin(); l != at4Chain.end(); l++) {
          
              ILscore = ii + ll;
              JKscore = jj + kk;

              std::vector<std::string> myKeys;
              myKeys.push_back((*i)->getName());
              myKeys.push_back((*j)->getName());
              myKeys.push_back((*k)->getName());
              myKeys.push_back((*l)->getName());

              TorsionType* torsionType = torsionTypeCont_.find(myKeys);
              if (torsionType) { 
                foundTorsions.push_back( make_tuple3(JKscore, ILscore, myKeys) );
              }
              ll++;
            }
            ii++;
          }
          kk++;
        }
        jj++;
      }
      
      if (foundTorsions.size() > 0) {
        std::sort(foundTorsions.begin(), foundTorsions.end());
        int jkscore = foundTorsions[0].first;
        int ilscore = foundTorsions[0].second;
        std::vector<std::string> theKeys = foundTorsions[0].third;
        
        TorsionType* bestType = torsionTypeCont_.find(theKeys);
        return bestType;
      } else {
        //if no exact match found, try wild card match
        return torsionTypeCont_.find(keys, wildCardAtomTypeName_);
      }
    }
  }

  InversionType* ForceField::getInversionType(const std::string &at1, 
                                              const std::string &at2,
                                              const std::string &at3, 
                                              const std::string &at4) {
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    keys.push_back(at3);    
    keys.push_back(at4);    

    //try exact match first
    InversionType* inversionType = inversionTypeCont_.permutedFindSkippingFirstElement(keys);
    if (inversionType) {
      return inversionType;
    } else {
      
      AtomType* atype1;
      AtomType* atype2;
      AtomType* atype3;
      AtomType* atype4;
      std::vector<std::string> at1key;
      at1key.push_back(at1);
      atype1 = atomTypeCont_.find(at1key);
      
      std::vector<std::string> at2key;
      at2key.push_back(at2);
      atype2 = atomTypeCont_.find(at2key);
      
      std::vector<std::string> at3key;
      at3key.push_back(at3);
      atype3 = atomTypeCont_.find(at3key);
      
      std::vector<std::string> at4key;
      at4key.push_back(at4);
      atype4 = atomTypeCont_.find(at4key);

      // query atom types for their chains of responsibility
      std::vector<AtomType*> at1Chain = atype1->allYourBase();
      std::vector<AtomType*> at2Chain = atype2->allYourBase();
      std::vector<AtomType*> at3Chain = atype3->allYourBase();
      std::vector<AtomType*> at4Chain = atype4->allYourBase();

      std::vector<AtomType*>::iterator i;
      std::vector<AtomType*>::iterator j;
      std::vector<AtomType*>::iterator k;
      std::vector<AtomType*>::iterator l;

      int ii = 0;
      int jj = 0;
      int kk = 0;
      int ll = 0;
      int Iscore;
      int JKLscore;
      
      std::vector<tuple3<int, int, std::vector<std::string> > > foundInversions;
      
      for (j = at2Chain.begin(); j != at2Chain.end(); j++) {
        kk = 0;
        for (k = at3Chain.begin(); k != at3Chain.end(); k++) {
          ii = 0;       
          for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
            ll = 0;
            for (l = at4Chain.begin(); l != at4Chain.end(); l++) {
              
              Iscore = ii;
              JKLscore = jj + kk + ll;
              
              std::vector<std::string> myKeys;
              myKeys.push_back((*i)->getName());
              myKeys.push_back((*j)->getName());
              myKeys.push_back((*k)->getName());
              myKeys.push_back((*l)->getName());
              
              InversionType* inversionType = inversionTypeCont_.permutedFindSkippingFirstElement(myKeys);
              if (inversionType) { 
                foundInversions.push_back( make_tuple3(Iscore, JKLscore, myKeys) );
              }
              ll++;
            }
            ii++;
          }
          kk++;
        }
        jj++;
      }
         
      if (foundInversions.size() > 0) {
        std::sort(foundInversions.begin(), foundInversions.end());
        int iscore = foundInversions[0].first;
        int jklscore = foundInversions[0].second;
        std::vector<std::string> theKeys = foundInversions[0].third;
        
        InversionType* bestType = inversionTypeCont_.permutedFindSkippingFirstElement(theKeys);
        return bestType;
      } else {
        //if no exact match found, try wild card match
        return inversionTypeCont_.find(keys, wildCardAtomTypeName_);
      }
    }
  }
  
  NonBondedInteractionType* ForceField::getNonBondedInteractionType(const std::string &at1, const std::string &at2) {
    
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    
    //try exact match first
    NonBondedInteractionType* nbiType = nonBondedInteractionTypeCont_.find(keys);
    if (nbiType) {
      return nbiType;
    } else {
      AtomType* atype1;
      AtomType* atype2;
      std::vector<std::string> at1key;
      at1key.push_back(at1);
      atype1 = atomTypeCont_.find(at1key);
      
      std::vector<std::string> at2key;
      at2key.push_back(at2);
      atype2 = atomTypeCont_.find(at2key);
      
      // query atom types for their chains of responsibility
      std::vector<AtomType*> at1Chain = atype1->allYourBase();
      std::vector<AtomType*> at2Chain = atype2->allYourBase();
      
      std::vector<AtomType*>::iterator i;
      std::vector<AtomType*>::iterator j;
      
      int ii = 0;
      int jj = 0;
      int nbiTypeScore;
      
      std::vector<std::pair<int, std::vector<std::string> > > foundNBI;
      
      for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
        jj = 0;
        for (j = at2Chain.begin(); j != at2Chain.end(); j++) {
          
          nbiTypeScore = ii + jj;
          
          std::vector<std::string> myKeys;
          myKeys.push_back((*i)->getName());
          myKeys.push_back((*j)->getName());
          
          NonBondedInteractionType* nbiType = nonBondedInteractionTypeCont_.find(myKeys);
          if (nbiType) {
            foundNBI.push_back(std::make_pair(nbiTypeScore, myKeys));
          }
          jj++;
        }
        ii++;
      }
      
      
      if (foundNBI.size() > 0) {
        // sort the foundNBI by the score:
        std::sort(foundNBI.begin(), foundNBI.end());
        
        int bestScore = foundNBI[0].first;
        std::vector<std::string> theKeys = foundNBI[0].second;
        
        NonBondedInteractionType* bestType = nonBondedInteractionTypeCont_.find(theKeys);        
        return bestType;
      } else {
        //if no exact match found, try wild card match
        return nonBondedInteractionTypeCont_.find(keys, wildCardAtomTypeName_);
      }
    }
  }
  
  BondType* ForceField::getExactBondType(const std::string &at1, 
                                         const std::string &at2){ 
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    return bondTypeCont_.find(keys);
  }
  
  BendType* ForceField::getExactBendType(const std::string &at1, 
                                         const std::string &at2,
                                         const std::string &at3){ 
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    keys.push_back(at3);    
    return bendTypeCont_.find(keys);
  }
  
  TorsionType* ForceField::getExactTorsionType(const std::string &at1, 
                                               const std::string &at2,
                                               const std::string &at3, 
                                               const std::string &at4){ 
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    keys.push_back(at3);    
    keys.push_back(at4);   
    return torsionTypeCont_.find(keys);
  }
  
  InversionType* ForceField::getExactInversionType(const std::string &at1, 
                                                   const std::string &at2,
                                                   const std::string &at3, 
                                                   const std::string &at4){ 
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    keys.push_back(at3);    
    keys.push_back(at4);   
    return inversionTypeCont_.find(keys);
  }
  
  NonBondedInteractionType* ForceField::getExactNonBondedInteractionType(const std::string &at1, const std::string &at2){ 
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    return nonBondedInteractionTypeCont_.find(keys);
  }
  

  bool ForceField::addAtomType(const std::string &at, AtomType* atomType) {
    std::vector<std::string> keys;
    keys.push_back(at);
    atypeIdentToName[atomType->getIdent()] = at;
    return atomTypeCont_.add(keys, atomType);
  }

  bool ForceField::replaceAtomType(const std::string &at, AtomType* atomType) {
    std::vector<std::string> keys;
    keys.push_back(at);
    atypeIdentToName[atomType->getIdent()] = at;
    return atomTypeCont_.replace(keys, atomType);
  }

  bool ForceField::addBondType(const std::string &at1, const std::string &at2,
                               BondType* bondType) {
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    return bondTypeCont_.add(keys, bondType);    
  }
  
  bool ForceField::addBendType(const std::string &at1, const std::string &at2,
                               const std::string &at3, BendType* bendType) {
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    keys.push_back(at3);    
    return bendTypeCont_.add(keys, bendType);
  }
  
  bool ForceField::addTorsionType(const std::string &at1, 
                                  const std::string &at2,
                                  const std::string &at3, 
                                  const std::string &at4, 
                                  TorsionType* torsionType) {
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    keys.push_back(at3);    
    keys.push_back(at4);    
    return torsionTypeCont_.add(keys, torsionType);
  }

  bool ForceField::addInversionType(const std::string &at1, 
                                    const std::string &at2,
                                    const std::string &at3, 
                                    const std::string &at4, 
                                    InversionType* inversionType) {
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    keys.push_back(at3);    
    keys.push_back(at4);    
    return inversionTypeCont_.add(keys, inversionType);
  }
  
  bool ForceField::addNonBondedInteractionType(const std::string &at1, 
                                               const std::string &at2, 
                                               NonBondedInteractionType* nbiType) {
    std::vector<std::string> keys;
    keys.push_back(at1);
    keys.push_back(at2);    
    return nonBondedInteractionTypeCont_.add(keys, nbiType);
  }
  
  RealType ForceField::getRcutFromAtomType(AtomType* at) {
    /**@todo */
    GenericData* data;
    RealType rcut = 0.0;
    
    if (at->isLennardJones()) {
      data = at->getPropertyByName("LennardJones");
      if (data != NULL) {
        LJParamGenericData* ljData = dynamic_cast<LJParamGenericData*>(data);
        
        if (ljData != NULL) {
          LJParam ljParam = ljData->getData();
          
          //by default use 2.5*sigma as cutoff radius
          rcut = 2.5 * ljParam.sigma;
          
        } else {
          sprintf( painCave.errMsg,
                   "Can not cast GenericData to LJParam\n");
          painCave.severity = OPENMD_ERROR;
          painCave.isFatal = 1;
          simError();          
        }            
      } else {
        sprintf( painCave.errMsg, "Can not find Parameters for LennardJones\n");
        painCave.severity = OPENMD_ERROR;
        painCave.isFatal = 1;
        simError();          
      }
    }
    return rcut;    
  }
  

  ifstrstream* ForceField::openForceFieldFile(const std::string& filename) {
    std::string forceFieldFilename(filename);
    ifstrstream* ffStream = new ifstrstream();
    
    //try to open the force filed file in current directory first    
    ffStream->open(forceFieldFilename.c_str());
    if(!ffStream->is_open()){

      forceFieldFilename = ffPath_ + "/" + forceFieldFilename;
      ffStream->open( forceFieldFilename.c_str() );

      //if current directory does not contain the force field file,
      //try to open it in the path        
      if(!ffStream->is_open()){

        sprintf( painCave.errMsg,
                 "Error opening the force field parameter file:\n"
                 "\t%s\n"
                 "\tHave you tried setting the FORCE_PARAM_PATH environment "
                 "variable?\n",
                 forceFieldFilename.c_str() );
        painCave.severity = OPENMD_ERROR;
        painCave.isFatal = 1;
        simError();
      }
    }  
    return ffStream;
  }

} //end namespace OpenMD
Revision:	1629
Committed:	Wed Sep 14 21:15:17 2011 UTC (14 years, 1 month ago) by gezelter
Original Path:	*branches/development/src/UseTheForce/ForceField.cpp*
File size:	21455 byte(s)
Log Message:	Merging changes from old branch into development branch
#	Content
1	/*
2	* Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
3	*
4	* The University of Notre Dame grants you ("Licensee") a
5	* non-exclusive, royalty free, license to use, modify and
6	* redistribute this software in source and binary code form, provided
7	* that the following conditions are met:
8	*
9	* 1. Redistributions of source code must retain the above copyright
10	* notice, this list of conditions and the following disclaimer.
11	*
12	* 2. Redistributions in binary form must reproduce the above copyright
13	* notice, this list of conditions and the following disclaimer in the
14	* documentation and/or other materials provided with the
15	* distribution.
16	*
17	* This software is provided "AS IS," without a warranty of any
18	* kind. All express or implied conditions, representations and
19	* warranties, including any implied warranty of merchantability,
20	* fitness for a particular purpose or non-infringement, are hereby
21	* excluded. The University of Notre Dame and its licensors shall not
22	* be liable for any damages suffered by licensee as a result of
23	* using, modifying or distributing the software or its
24	* derivatives. In no event will the University of Notre Dame or its
25	* licensors be liable for any lost revenue, profit or data, or for
26	* direct, indirect, special, consequential, incidental or punitive
27	* damages, however caused and regardless of the theory of liability,
28	* arising out of the use of or inability to use software, even if the
29	* University of Notre Dame has been advised of the possibility of
30	* such damages.
31	*
32	* SUPPORT OPEN SCIENCE! If you use OpenMD or its source code in your
33	* research, please cite the appropriate papers when you publish your
34	* work. Good starting points are:
35	*
36	* [1] Meineke, et al., J. Comp. Chem. 26, 252-271 (2005).
37	* [2] Fennell & Gezelter, J. Chem. Phys. 124, 234104 (2006).
38	* [3] Sun, Lin & Gezelter, J. Chem. Phys. 128, 24107 (2008).
39	* [4] Vardeman & Gezelter, in progress (2009).
40	*/
41
42	/**
43	* @file ForceField.cpp
44	* @author tlin
45	* @date 11/04/2004
46	* @time 22:51am
47	* @version 1.0
48	*/
49
50	#include <algorithm>
51	#include "UseTheForce/ForceField.hpp"
52	#include "utils/simError.h"
53	#include "utils/Tuple.hpp"
54	namespace OpenMD {
55
56	ForceField::ForceField() {
57
58	char* tempPath;
59	tempPath = getenv("FORCE_PARAM_PATH");
60
61	if (tempPath == NULL) {
62	//convert a macro from compiler to a string in c++
63	STR_DEFINE(ffPath_, FRC_PATH );
64	} else {
65	ffPath_ = tempPath;
66	}
67	}
68
69	/**
70	* getAtomType by string
71	*
72	* finds the requested atom type in this force field using the string
73	* name of the atom type.
74	*/
75	AtomType* ForceField::getAtomType(const std::string &at) {
76	std::vector<std::string> keys;
77	keys.push_back(at);
78	return atomTypeCont_.find(keys);
79	}
80
81	/**
82	* getAtomType by ident
83	*
84	* finds the requested atom type in this force field using the
85	* integer ident instead of the string name of the atom type.
86	*/
87	AtomType* ForceField::getAtomType(int ident) {
88	std::string at = atypeIdentToName.find(ident)->second;
89	return getAtomType(at);
90	}
91
92	BondType* ForceField::getBondType(const std::string &at1,
93	const std::string &at2) {
94	std::vector<std::string> keys;
95	keys.push_back(at1);
96	keys.push_back(at2);
97
98	//try exact match first
99	BondType* bondType = bondTypeCont_.find(keys);
100	if (bondType) {
101	return bondType;
102	} else {
103	AtomType* atype1;
104	AtomType* atype2;
105	std::vector<std::string> at1key;
106	at1key.push_back(at1);
107	atype1 = atomTypeCont_.find(at1key);
108
109	std::vector<std::string> at2key;
110	at2key.push_back(at2);
111	atype2 = atomTypeCont_.find(at2key);
112
113	// query atom types for their chains of responsibility
114	std::vector<AtomType*> at1Chain = atype1->allYourBase();
115	std::vector<AtomType*> at2Chain = atype2->allYourBase();
116
117	std::vector<AtomType*>::iterator i;
118	std::vector<AtomType*>::iterator j;
119
120	int ii = 0;
121	int jj = 0;
122	int bondTypeScore;
123
124	std::vector<std::pair<int, std::vector<std::string> > > foundBonds;
125
126	for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
127	jj = 0;
128	for (j = at2Chain.begin(); j != at2Chain.end(); j++) {
129
130	bondTypeScore = ii + jj;
131
132	std::vector<std::string> myKeys;
133	myKeys.push_back((*i)->getName());
134	myKeys.push_back((*j)->getName());
135
136	BondType* bondType = bondTypeCont_.find(myKeys);
137	if (bondType) {
138	foundBonds.push_back(std::make_pair(bondTypeScore, myKeys));
139	}
140	jj++;
141	}
142	ii++;
143	}
144
145
146	if (foundBonds.size() > 0) {
147	// sort the foundBonds by the score:
148	std::sort(foundBonds.begin(), foundBonds.end());
149
150	int bestScore = foundBonds[0].first;
151	std::vector<std::string> theKeys = foundBonds[0].second;
152
153	BondType* bestType = bondTypeCont_.find(theKeys);
154
155	return bestType;
156	} else {
157	//if no exact match found, try wild card match
158	return bondTypeCont_.find(keys, wildCardAtomTypeName_);
159	}
160	}
161	}
162
163	BendType* ForceField::getBendType(const std::string &at1,
164	const std::string &at2,
165	const std::string &at3) {
166	std::vector<std::string> keys;
167	keys.push_back(at1);
168	keys.push_back(at2);
169	keys.push_back(at3);
170
171	//try exact match first
172	BendType* bendType = bendTypeCont_.find(keys);
173	if (bendType) {
174	return bendType;
175	} else {
176
177	AtomType* atype1;
178	AtomType* atype2;
179	AtomType* atype3;
180	std::vector<std::string> at1key;
181	at1key.push_back(at1);
182	atype1 = atomTypeCont_.find(at1key);
183
184	std::vector<std::string> at2key;
185	at2key.push_back(at2);
186	atype2 = atomTypeCont_.find(at2key);
187
188	std::vector<std::string> at3key;
189	at3key.push_back(at3);
190	atype3 = atomTypeCont_.find(at3key);
191
192	// query atom types for their chains of responsibility
193	std::vector<AtomType*> at1Chain = atype1->allYourBase();
194	std::vector<AtomType*> at2Chain = atype2->allYourBase();
195	std::vector<AtomType*> at3Chain = atype3->allYourBase();
196
197	std::vector<AtomType*>::iterator i;
198	std::vector<AtomType*>::iterator j;
199	std::vector<AtomType*>::iterator k;
200
201	int ii = 0;
202	int jj = 0;
203	int kk = 0;
204	int IKscore;
205
206	std::vector<tuple3<int, int, std::vector<std::string> > > foundBends;
207
208	for (j = at2Chain.begin(); j != at2Chain.end(); j++) {
209	ii = 0;
210	for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
211	kk = 0;
212	for (k = at3Chain.begin(); k != at3Chain.end(); k++) {
213
214	IKscore = ii + kk;
215
216	std::vector<std::string> myKeys;
217	myKeys.push_back((*i)->getName());
218	myKeys.push_back((*j)->getName());
219	myKeys.push_back((*k)->getName());
220
221	BendType* bendType = bendTypeCont_.find(myKeys);
222	if (bendType) {
223	foundBends.push_back( make_tuple3(jj, IKscore, myKeys) );
224	}
225	kk++;
226	}
227	ii++;
228	}
229	jj++;
230	}
231
232	if (foundBends.size() > 0) {
233	std::sort(foundBends.begin(), foundBends.end());
234	int jscore = foundBends[0].first;
235	int ikscore = foundBends[0].second;
236	std::vector<std::string> theKeys = foundBends[0].third;
237
238	BendType* bestType = bendTypeCont_.find(theKeys);
239	return bestType;
240	} else {
241	//if no exact match found, try wild card match
242	return bendTypeCont_.find(keys, wildCardAtomTypeName_);
243	}
244	}
245	}
246
247	TorsionType* ForceField::getTorsionType(const std::string &at1,
248	const std::string &at2,
249	const std::string &at3,
250	const std::string &at4) {
251	std::vector<std::string> keys;
252	keys.push_back(at1);
253	keys.push_back(at2);
254	keys.push_back(at3);
255	keys.push_back(at4);
256
257
258	//try exact match first
259	TorsionType* torsionType = torsionTypeCont_.find(keys);
260	if (torsionType) {
261	return torsionType;
262	} else {
263
264	AtomType* atype1;
265	AtomType* atype2;
266	AtomType* atype3;
267	AtomType* atype4;
268	std::vector<std::string> at1key;
269	at1key.push_back(at1);
270	atype1 = atomTypeCont_.find(at1key);
271
272	std::vector<std::string> at2key;
273	at2key.push_back(at2);
274	atype2 = atomTypeCont_.find(at2key);
275
276	std::vector<std::string> at3key;
277	at3key.push_back(at3);
278	atype3 = atomTypeCont_.find(at3key);
279
280	std::vector<std::string> at4key;
281	at4key.push_back(at4);
282	atype4 = atomTypeCont_.find(at4key);
283
284	// query atom types for their chains of responsibility
285	std::vector<AtomType*> at1Chain = atype1->allYourBase();
286	std::vector<AtomType*> at2Chain = atype2->allYourBase();
287	std::vector<AtomType*> at3Chain = atype3->allYourBase();
288	std::vector<AtomType*> at4Chain = atype4->allYourBase();
289
290	std::vector<AtomType*>::iterator i;
291	std::vector<AtomType*>::iterator j;
292	std::vector<AtomType*>::iterator k;
293	std::vector<AtomType*>::iterator l;
294
295	int ii = 0;
296	int jj = 0;
297	int kk = 0;
298	int ll = 0;
299	int ILscore;
300	int JKscore;
301
302	std::vector<tuple3<int, int, std::vector<std::string> > > foundTorsions;
303
304	for (j = at2Chain.begin(); j != at2Chain.end(); j++) {
305	kk = 0;
306	for (k = at3Chain.begin(); k != at3Chain.end(); k++) {
307	ii = 0;
308	for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
309	ll = 0;
310	for (l = at4Chain.begin(); l != at4Chain.end(); l++) {
311
312	ILscore = ii + ll;
313	JKscore = jj + kk;
314
315	std::vector<std::string> myKeys;
316	myKeys.push_back((*i)->getName());
317	myKeys.push_back((*j)->getName());
318	myKeys.push_back((*k)->getName());
319	myKeys.push_back((*l)->getName());
320
321	TorsionType* torsionType = torsionTypeCont_.find(myKeys);
322	if (torsionType) {
323	foundTorsions.push_back( make_tuple3(JKscore, ILscore, myKeys) );
324	}
325	ll++;
326	}
327	ii++;
328	}
329	kk++;
330	}
331	jj++;
332	}
333
334	if (foundTorsions.size() > 0) {
335	std::sort(foundTorsions.begin(), foundTorsions.end());
336	int jkscore = foundTorsions[0].first;
337	int ilscore = foundTorsions[0].second;
338	std::vector<std::string> theKeys = foundTorsions[0].third;
339
340	TorsionType* bestType = torsionTypeCont_.find(theKeys);
341	return bestType;
342	} else {
343	//if no exact match found, try wild card match
344	return torsionTypeCont_.find(keys, wildCardAtomTypeName_);
345	}
346	}
347	}
348
349	InversionType* ForceField::getInversionType(const std::string &at1,
350	const std::string &at2,
351	const std::string &at3,
352	const std::string &at4) {
353	std::vector<std::string> keys;
354	keys.push_back(at1);
355	keys.push_back(at2);
356	keys.push_back(at3);
357	keys.push_back(at4);
358
359	//try exact match first
360	InversionType* inversionType = inversionTypeCont_.permutedFindSkippingFirstElement(keys);
361	if (inversionType) {
362	return inversionType;
363	} else {
364
365	AtomType* atype1;
366	AtomType* atype2;
367	AtomType* atype3;
368	AtomType* atype4;
369	std::vector<std::string> at1key;
370	at1key.push_back(at1);
371	atype1 = atomTypeCont_.find(at1key);
372
373	std::vector<std::string> at2key;
374	at2key.push_back(at2);
375	atype2 = atomTypeCont_.find(at2key);
376
377	std::vector<std::string> at3key;
378	at3key.push_back(at3);
379	atype3 = atomTypeCont_.find(at3key);
380
381	std::vector<std::string> at4key;
382	at4key.push_back(at4);
383	atype4 = atomTypeCont_.find(at4key);
384
385	// query atom types for their chains of responsibility
386	std::vector<AtomType*> at1Chain = atype1->allYourBase();
387	std::vector<AtomType*> at2Chain = atype2->allYourBase();
388	std::vector<AtomType*> at3Chain = atype3->allYourBase();
389	std::vector<AtomType*> at4Chain = atype4->allYourBase();
390
391	std::vector<AtomType*>::iterator i;
392	std::vector<AtomType*>::iterator j;
393	std::vector<AtomType*>::iterator k;
394	std::vector<AtomType*>::iterator l;
395
396	int ii = 0;
397	int jj = 0;
398	int kk = 0;
399	int ll = 0;
400	int Iscore;
401	int JKLscore;
402
403	std::vector<tuple3<int, int, std::vector<std::string> > > foundInversions;
404
405	for (j = at2Chain.begin(); j != at2Chain.end(); j++) {
406	kk = 0;
407	for (k = at3Chain.begin(); k != at3Chain.end(); k++) {
408	ii = 0;
409	for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
410	ll = 0;
411	for (l = at4Chain.begin(); l != at4Chain.end(); l++) {
412
413	Iscore = ii;
414	JKLscore = jj + kk + ll;
415
416	std::vector<std::string> myKeys;
417	myKeys.push_back((*i)->getName());
418	myKeys.push_back((*j)->getName());
419	myKeys.push_back((*k)->getName());
420	myKeys.push_back((*l)->getName());
421
422	InversionType* inversionType = inversionTypeCont_.permutedFindSkippingFirstElement(myKeys);
423	if (inversionType) {
424	foundInversions.push_back( make_tuple3(Iscore, JKLscore, myKeys) );
425	}
426	ll++;
427	}
428	ii++;
429	}
430	kk++;
431	}
432	jj++;
433	}
434
435	if (foundInversions.size() > 0) {
436	std::sort(foundInversions.begin(), foundInversions.end());
437	int iscore = foundInversions[0].first;
438	int jklscore = foundInversions[0].second;
439	std::vector<std::string> theKeys = foundInversions[0].third;
440
441	InversionType* bestType = inversionTypeCont_.permutedFindSkippingFirstElement(theKeys);
442	return bestType;
443	} else {
444	//if no exact match found, try wild card match
445	return inversionTypeCont_.find(keys, wildCardAtomTypeName_);
446	}
447	}
448	}
449
450	NonBondedInteractionType* ForceField::getNonBondedInteractionType(const std::string &at1, const std::string &at2) {
451
452	std::vector<std::string> keys;
453	keys.push_back(at1);
454	keys.push_back(at2);
455
456	//try exact match first
457	NonBondedInteractionType* nbiType = nonBondedInteractionTypeCont_.find(keys);
458	if (nbiType) {
459	return nbiType;
460	} else {
461	AtomType* atype1;
462	AtomType* atype2;
463	std::vector<std::string> at1key;
464	at1key.push_back(at1);
465	atype1 = atomTypeCont_.find(at1key);
466
467	std::vector<std::string> at2key;
468	at2key.push_back(at2);
469	atype2 = atomTypeCont_.find(at2key);
470
471	// query atom types for their chains of responsibility
472	std::vector<AtomType*> at1Chain = atype1->allYourBase();
473	std::vector<AtomType*> at2Chain = atype2->allYourBase();
474
475	std::vector<AtomType*>::iterator i;
476	std::vector<AtomType*>::iterator j;
477
478	int ii = 0;
479	int jj = 0;
480	int nbiTypeScore;
481
482	std::vector<std::pair<int, std::vector<std::string> > > foundNBI;
483
484	for (i = at1Chain.begin(); i != at1Chain.end(); i++) {
485	jj = 0;
486	for (j = at2Chain.begin(); j != at2Chain.end(); j++) {
487
488	nbiTypeScore = ii + jj;
489
490	std::vector<std::string> myKeys;
491	myKeys.push_back((*i)->getName());
492	myKeys.push_back((*j)->getName());
493
494	NonBondedInteractionType* nbiType = nonBondedInteractionTypeCont_.find(myKeys);
495	if (nbiType) {
496	foundNBI.push_back(std::make_pair(nbiTypeScore, myKeys));
497	}
498	jj++;
499	}
500	ii++;
501	}
502
503
504	if (foundNBI.size() > 0) {
505	// sort the foundNBI by the score:
506	std::sort(foundNBI.begin(), foundNBI.end());
507
508	int bestScore = foundNBI[0].first;
509	std::vector<std::string> theKeys = foundNBI[0].second;
510
511	NonBondedInteractionType* bestType = nonBondedInteractionTypeCont_.find(theKeys);
512	return bestType;
513	} else {
514	//if no exact match found, try wild card match
515	return nonBondedInteractionTypeCont_.find(keys, wildCardAtomTypeName_);
516	}
517	}
518	}
519
520	BondType* ForceField::getExactBondType(const std::string &at1,
521	const std::string &at2){
522	std::vector<std::string> keys;
523	keys.push_back(at1);
524	keys.push_back(at2);
525	return bondTypeCont_.find(keys);
526	}
527
528	BendType* ForceField::getExactBendType(const std::string &at1,
529	const std::string &at2,
530	const std::string &at3){
531	std::vector<std::string> keys;
532	keys.push_back(at1);
533	keys.push_back(at2);
534	keys.push_back(at3);
535	return bendTypeCont_.find(keys);
536	}
537
538	TorsionType* ForceField::getExactTorsionType(const std::string &at1,
539	const std::string &at2,
540	const std::string &at3,
541	const std::string &at4){
542	std::vector<std::string> keys;
543	keys.push_back(at1);
544	keys.push_back(at2);
545	keys.push_back(at3);
546	keys.push_back(at4);
547	return torsionTypeCont_.find(keys);
548	}
549
550	InversionType* ForceField::getExactInversionType(const std::string &at1,
551	const std::string &at2,
552	const std::string &at3,
553	const std::string &at4){
554	std::vector<std::string> keys;
555	keys.push_back(at1);
556	keys.push_back(at2);
557	keys.push_back(at3);
558	keys.push_back(at4);
559	return inversionTypeCont_.find(keys);
560	}
561
562	NonBondedInteractionType* ForceField::getExactNonBondedInteractionType(const std::string &at1, const std::string &at2){
563	std::vector<std::string> keys;
564	keys.push_back(at1);
565	keys.push_back(at2);
566	return nonBondedInteractionTypeCont_.find(keys);
567	}
568
569
570	bool ForceField::addAtomType(const std::string &at, AtomType* atomType) {
571	std::vector<std::string> keys;
572	keys.push_back(at);
573	atypeIdentToName[atomType->getIdent()] = at;
574	return atomTypeCont_.add(keys, atomType);
575	}
576
577	bool ForceField::replaceAtomType(const std::string &at, AtomType* atomType) {
578	std::vector<std::string> keys;
579	keys.push_back(at);
580	atypeIdentToName[atomType->getIdent()] = at;
581	return atomTypeCont_.replace(keys, atomType);
582	}
583
584	bool ForceField::addBondType(const std::string &at1, const std::string &at2,
585	BondType* bondType) {
586	std::vector<std::string> keys;
587	keys.push_back(at1);
588	keys.push_back(at2);
589	return bondTypeCont_.add(keys, bondType);
590	}
591
592	bool ForceField::addBendType(const std::string &at1, const std::string &at2,
593	const std::string &at3, BendType* bendType) {
594	std::vector<std::string> keys;
595	keys.push_back(at1);
596	keys.push_back(at2);
597	keys.push_back(at3);
598	return bendTypeCont_.add(keys, bendType);
599	}
600
601	bool ForceField::addTorsionType(const std::string &at1,
602	const std::string &at2,
603	const std::string &at3,
604	const std::string &at4,
605	TorsionType* torsionType) {
606	std::vector<std::string> keys;
607	keys.push_back(at1);
608	keys.push_back(at2);
609	keys.push_back(at3);
610	keys.push_back(at4);
611	return torsionTypeCont_.add(keys, torsionType);
612	}
613
614	bool ForceField::addInversionType(const std::string &at1,
615	const std::string &at2,
616	const std::string &at3,
617	const std::string &at4,
618	InversionType* inversionType) {
619	std::vector<std::string> keys;
620	keys.push_back(at1);
621	keys.push_back(at2);
622	keys.push_back(at3);
623	keys.push_back(at4);
624	return inversionTypeCont_.add(keys, inversionType);
625	}
626
627	bool ForceField::addNonBondedInteractionType(const std::string &at1,
628	const std::string &at2,
629	NonBondedInteractionType* nbiType) {
630	std::vector<std::string> keys;
631	keys.push_back(at1);
632	keys.push_back(at2);
633	return nonBondedInteractionTypeCont_.add(keys, nbiType);
634	}
635
636	RealType ForceField::getRcutFromAtomType(AtomType* at) {
637	/*@todo /
638	GenericData* data;
639	RealType rcut = 0.0;
640
641	if (at->isLennardJones()) {
642	data = at->getPropertyByName("LennardJones");
643	if (data != NULL) {
644	LJParamGenericData* ljData = dynamic_cast<LJParamGenericData*>(data);
645
646	if (ljData != NULL) {
647	LJParam ljParam = ljData->getData();
648
649	//by default use 2.5*sigma as cutoff radius
650	rcut = 2.5 * ljParam.sigma;
651
652	} else {
653	sprintf( painCave.errMsg,
654	"Can not cast GenericData to LJParam\n");
655	painCave.severity = OPENMD_ERROR;
656	painCave.isFatal = 1;
657	simError();
658	}
659	} else {
660	sprintf( painCave.errMsg, "Can not find Parameters for LennardJones\n");
661	painCave.severity = OPENMD_ERROR;
662	painCave.isFatal = 1;
663	simError();
664	}
665	}
666	return rcut;
667	}
668
669
670	ifstrstream* ForceField::openForceFieldFile(const std::string& filename) {
671	std::string forceFieldFilename(filename);
672	ifstrstream* ffStream = new ifstrstream();
673
674	//try to open the force filed file in current directory first
675	ffStream->open(forceFieldFilename.c_str());
676	if(!ffStream->is_open()){
677
678	forceFieldFilename = ffPath_ + "/" + forceFieldFilename;
679	ffStream->open( forceFieldFilename.c_str() );
680
681	//if current directory does not contain the force field file,
682	//try to open it in the path
683	if(!ffStream->is_open()){
684
685	sprintf( painCave.errMsg,
686	"Error opening the force field parameter file:\n"
687	"\t%s\n"
688	"\tHave you tried setting the FORCE_PARAM_PATH environment "
689	"variable?\n",
690	forceFieldFilename.c_str() );
691	painCave.severity = OPENMD_ERROR;
692	painCave.isFatal = 1;
693	simError();
694	}
695	}
696	return ffStream;
697	}
698
699	} //end namespace OpenMD