Ejemplo n.º 1
0
  void OBAtomTyper::AssignTypes(OBMol &mol)
  {
    if (!_init)
      Init();

    obErrorLog.ThrowError(__FUNCTION__,
                          "Ran OpenBabel::AssignTypes", obAuditMsg);

    mol.SetAtomTypesPerceived();

    vector<vector<int> >::iterator j;
    vector<pair<OBSmartsPattern*,string> >::iterator i;

    for (i = _vexttyp.begin();i != _vexttyp.end();++i)
      if (i->first->Match(mol))
        {
          _mlist = i->first->GetMapList();
          for (j = _mlist.begin();j != _mlist.end();++j)
            mol.GetAtom((*j)[0])->SetType(i->second);
        }

    // Special cases
    vector<OBAtom*>::iterator a;
    OBAtom* atom;
    for (atom = mol.BeginAtom(a); atom; atom = mol.NextAtom(a)) {
      // guanidinium. Fixes PR#1800964
      if (strncasecmp(atom->GetType(),"C2", 2) == 0) {
        int guanidineN = 0;
        OBAtom *nbr;
        vector<OBBond*>::iterator k;
        for (nbr = atom->BeginNbrAtom(k);nbr;nbr = atom->NextNbrAtom(k)) {
          if (strncasecmp(nbr->GetType(),"Npl", 3) == 0 ||
              strncasecmp(nbr->GetType(),"N2", 2) == 0 ||
              strncasecmp(nbr->GetType(),"Ng+", 3) == 0)
            ++guanidineN;
        }
        if (guanidineN == 3)
          atom->SetType("C+");

      } // end C2 carbon for guanidinium

    } // end special cases
  }
Ejemplo n.º 2
0
  bool PDBFormat::WriteMolecule(OBBase* pOb, OBConversion* pConv)
  {
    OBMol* pmol = dynamic_cast<OBMol*>(pOb);
    if(pmol==NULL)
      return false;

    //Define some references so we can use the old parameter names
    ostream &ofs = *pConv->GetOutStream();
    OBMol &mol = *pmol;

    unsigned int i;
    char buffer[BUFF_SIZE];
    char type_name[10], padded_name[10];
    char the_res[10];
    char the_chain = ' ';
    const char *element_name;
    int res_num;
    bool het=true;
    int model_num = 0;
    if (!pConv->IsLast() || pConv->GetOutputIndex() > 1)
      { // More than one molecule record
        model_num = pConv->GetOutputIndex(); // MODEL 1-based index
        snprintf(buffer, BUFF_SIZE, "MODEL %8d", model_num);
        ofs << buffer << endl;
      }

    // write back all fields (REMARKS, HELIX, SHEET, SITE, ...)
    bool compndWritten = false;
    bool authorWritten = false;
    std::vector<OBGenericData*> pairData = mol.GetAllData(OBGenericDataType::PairData);
    for (std::vector<OBGenericData*>::iterator data = pairData.begin(); data != pairData.end(); ++data) {
      OBPairData *pd = static_cast<OBPairData*>(*data);
      string attr = pd->GetAttribute();

      // filter to make sure we are writing pdb fields only
      if (attr != "HEADER" && attr != "OBSLTE" && attr != "TITLE" && attr != "SPLIT" &&
          attr != "CAVEAT" && attr != "COMPND" && attr != "SOURCE" && attr != "KEYWDS" &&
          attr != "EXPDTA" && attr != "NUMMDL" && attr != "MDLTYP" && attr != "AUTHOR" &&
          attr != "REVDAT" && attr != "SPRSDE" && attr != "JRNL" && attr != "REMARK" &&
          attr != "DBREF" && attr != "DBREF1" && attr != "DBREF2" && attr != "SEQADV" &&
          attr != "SEQRES" && attr != "MODRES" && attr != "HET" && attr != "HETNAM" &&
          attr != "HETSYN" && attr != "FORMUL" && attr != "HELIX" && attr != "SHEET" &&
          attr != "SSBOND" && attr != "LINK" && attr != "CISPEP" && attr != "SITE" &&
          attr != "ORIGX1" && attr != "ORIGX2" && attr != "ORIGX3" && attr != "SCALE1" &&
          attr != "SCALE2" && attr != "SCALE3" && attr != "MATRIX1" && attr != "MATRIX2" &&
          attr != "MATRIX3" && attr != "MODEL")
        continue;

      if (attr == "COMPND")
        compndWritten = true;
      if (attr == "AUTHOR")
        authorWritten = true;

      // compute spacing needed. HELIX, SITE, HET, ... are trimmed when reading
      int nSpacing = 6 - attr.size();
      for (int i = 0; i < nSpacing; ++i)
        attr += " ";


      std::string lines = pd->GetValue();
      string::size_type last = 0;
      string::size_type pos = lines.find('\n');
      while (last != string::npos) {
        string line = lines.substr(last, pos - last);
        if (pos == string::npos)
          last = string::npos;
        else
          last = pos + 1;
        pos = lines.find('\n', last);

        ofs << attr << line << endl;
      }
    }

    if (!compndWritten) {
      if (strlen(mol.GetTitle()) > 0)
        snprintf(buffer, BUFF_SIZE, "COMPND    %s ",mol.GetTitle());
      else
        snprintf(buffer, BUFF_SIZE, "COMPND    UNNAMED");
      ofs << buffer << endl;
    }

    if (!authorWritten) {
      snprintf(buffer, BUFF_SIZE, "AUTHOR    GENERATED BY OPEN BABEL %s",BABEL_VERSION);
      ofs << buffer << endl;
    }

    // Write CRYST1 record, containing unit cell parameters, space group
    // and Z value (supposed to be 1)
    if (pmol->HasData(OBGenericDataType::UnitCell))
      {
        OBUnitCell *pUC = (OBUnitCell*)pmol->GetData(OBGenericDataType::UnitCell);
        if(pUC->GetSpaceGroup()){
          string tmpHM=pUC->GetSpaceGroup()->GetHMName();
          // Do we have an extended HM symbol, with origin choice as ":1" or ":2" ? If so, remove it.
          size_t n=tmpHM.find(":");
          if(n!=string::npos) tmpHM=tmpHM.substr(0,n);
          snprintf(buffer, BUFF_SIZE,
                   "CRYST1%9.3f%9.3f%9.3f%7.2f%7.2f%7.2f %-11s 1",
                   pUC->GetA(), pUC->GetB(), pUC->GetC(),
                   pUC->GetAlpha(), pUC->GetBeta(), pUC->GetGamma(),
                   tmpHM.c_str());
        }
        else
          snprintf(buffer, BUFF_SIZE,
                   "CRYST1%9.3f%9.3f%9.3f%7.2f%7.2f%7.2f %-11s 1",
                   pUC->GetA(), pUC->GetB(), pUC->GetC(),
                   pUC->GetAlpha(), pUC->GetBeta(), pUC->GetGamma(),
                   "P1");

        ofs << buffer << endl;
      }

    // before we write any records, we should check to see if any coord < -1000
    // which will cause errors in the formatting

    double minX, minY, minZ;
    minX = minY = minZ = -999.0f;
    FOR_ATOMS_OF_MOL(a, mol)
      {
        if (a->GetX() < minX)
          minX = a->GetX();
        if (a->GetY() < minY)
          minY = a->GetY();
        if (a->GetZ() < minZ)
          minZ = a->GetZ();
      }
    vector3 transV = VZero;
    if (minX < -999.0)
      transV.SetX(-1.0*minX - 900.0);
    if (minY < -999.0)
      transV.SetY(-1.0*minY - 900.0);
    if (minZ < -999.0)
      transV.SetZ(-1.0*minZ - 900.0);

    // if minX, minY, or minZ was never changed, shift will be 0.0f
    // otherwise, move enough so that smallest coord is > -999.0f
    mol.Translate(transV);

    OBAtom *atom;
    OBResidue *res;
    for (i = 1; i <= mol.NumAtoms(); i++)
      {
        atom = mol.GetAtom(i);
        strncpy(type_name, etab.GetSymbol(atom->GetAtomicNum()), sizeof(type_name));
        type_name[sizeof(type_name) - 1] = '\0';

        //two char. elements are on position 13 and 14 one char. start at 14
        if (strlen(type_name) > 1)
          type_name[1] = toupper(type_name[1]);
        else
          {
            char tmp[10];
            strncpy(tmp, type_name, 9); // make sure to null-terminate tmp
            snprintf(type_name, sizeof(type_name), " %-3s", tmp);
          }

        if ( (res = atom->GetResidue()) != 0 )
          {
            het = res->IsHetAtom(atom);
            snprintf(the_res,4,"%s",(char*)res->GetName().c_str());
            the_res[4] = '\0';
            snprintf(type_name,5,"%s",(char*)res->GetAtomID(atom).c_str());
            the_chain = res->GetChain();

            //two char. elements are on position 13 and 14 one char. start at 14
            if (strlen(etab.GetSymbol(atom->GetAtomicNum())) == 1)
              {
                if (strlen(type_name) < 4)
                  {
                    char tmp[10];
                    strncpy(tmp, type_name, 9); // make sure to null-terminate tmp
                    snprintf(padded_name, sizeof(padded_name), " %-3s", tmp);
                    strncpy(type_name,padded_name,4);
                    type_name[4] = '\0';
                  }
                else
                  {
                    /*
                      type_name[4] = type_name[3];
                      type_name[3] = type_name[2];
                      type_name[2] = type_name[1];
                      type_name[1] = type_name[0];
                      type_name[0] = type_name[4];
                    */
                    type_name[4] = '\0';
                  }
              }
            res_num = res->GetNum();
          }
        else
          {
            strcpy(the_res,"UNK");
            the_res[3] = '\0';
            snprintf(padded_name,sizeof(padded_name), "%s",type_name);
            strncpy(type_name,padded_name,4);
            type_name[4] = '\0';
            res_num = 1;
          }

        element_name = etab.GetSymbol(atom->GetAtomicNum());

        int charge = atom->GetFormalCharge();
        char scharge[3] = { ' ', ' ', '\0' };
        if(0 != charge)
          {
            snprintf(scharge, 3, "%+d", charge);
            char tmp = scharge[1];
            scharge[1] = scharge[0];
            scharge[0] = tmp;
          }
        snprintf(buffer, BUFF_SIZE, "%s%5d %-4s %-3s %c%4d    %8.3f%8.3f%8.3f  1.00  0.00          %2s%2s\n",
                 het?"HETATM":"ATOM  ",
                 i,
                 type_name,
                 the_res,
                 the_chain,
                 res_num,
                 atom->GetX(),
                 atom->GetY(),
                 atom->GetZ(),
                 element_name,
                 scharge);
        ofs << buffer;
      }

    OBAtom *nbr;
    vector<OBBond*>::iterator k;
    for (i = 1; i <= mol.NumAtoms(); i ++)
      {
        atom = mol.GetAtom(i);
        if (atom->GetValence() == 0)
          continue; // no need to write a CONECT record -- no bonds

        snprintf(buffer, BUFF_SIZE, "CONECT%5d", i);
        ofs << buffer;
        // Write out up to 4 real bonds per line PR#1711154
        int currentValence = 0;
        for (nbr = atom->BeginNbrAtom(k);nbr;nbr = atom->NextNbrAtom(k))
          {
            snprintf(buffer, BUFF_SIZE, "%5d", nbr->GetIdx());
            ofs << buffer;
            if (++currentValence % 4 == 0) {
              // Add the trailing space to finish this record
              ofs << "                                       \n";
              // write the start of a new CONECT record
              snprintf(buffer, BUFF_SIZE, "CONECT%5d", i);
              ofs << buffer;
            }
          }

        // Add trailing spaces
        int remainingValence = atom->GetValence() % 4;
        for (int count = 0; count < (4 - remainingValence); count++) {
          snprintf(buffer, BUFF_SIZE, "     ");
          ofs << buffer;
        }
        ofs << "                                       \n";
      }

    snprintf(buffer, BUFF_SIZE, "MASTER        0    0    0    0    0    0    0    0 ");
    ofs << buffer;
    snprintf(buffer, BUFF_SIZE, "%4d    0 %4d    0\n",mol.NumAtoms(),mol.NumAtoms());
    ofs << buffer;

    ofs << "END\n";
    if (model_num) {
      ofs << "ENDMDL" << endl;
    }

    return(true);
  }
Ejemplo n.º 3
0
  bool BGFFormat::WriteMolecule(OBBase* pOb, OBConversion* pConv)
  {
    OBMol* pmol = dynamic_cast<OBMol*>(pOb);
    if(pmol==NULL)
      return false;

    //Define some references so we can use the old parameter names
    ostream &ofs = *pConv->GetOutStream();
    OBMol &mol = *pmol;

    vector<OBAtom*>::iterator i;
    int max_val;
    OBAtom *atom;
    char buffer[BUFF_SIZE];
    char elmnt_typ[8], dreid_typ[8], atm_sym[16], max_val_str[8];

    mol.Kekulize();

    ofs << "BIOGRF 200\n";
    snprintf(buffer, BUFF_SIZE, "DESCRP %s\n",mol.GetTitle());
    ofs << buffer;
    snprintf(buffer, BUFF_SIZE, "REMARK BGF file created by Open Babel %s\n",BABEL_VERSION);
    ofs << "FORCEFIELD DREIDING  \n";

    // write unit cell if available
    if (mol.HasData(OBGenericDataType::UnitCell))
      {
        OBUnitCell *uc = (OBUnitCell*)mol.GetData(OBGenericDataType::UnitCell);
        // e.g. CRYSTX    49.30287   49.23010   25.45631   90.00008   89.99995   57.10041
        snprintf(buffer, BUFF_SIZE,
                 "CRYSTX%12.5f%12.5f%12.5f%12.5f%12.5f%12.5f",
                 uc->GetA(), uc->GetB(), uc->GetC(),
                 uc->GetAlpha() , uc->GetBeta(), uc->GetGamma());
        ofs << buffer << "\n";
      }

    ofs << "FORMAT ATOM   (a6,1x,i5,1x,a5,1x,a3,1x,a1,1x,a5,3f10.5,1x,a5,i3,i2,1x,f8.5)\n";

    ttab.SetFromType("INT");

    for (atom = mol.BeginAtom(i);atom;atom = mol.NextAtom(i))
      {
        strncpy(elmnt_typ,etab.GetSymbol(atom->GetAtomicNum()), 7); // make sure to null-terminate
        elmnt_typ[sizeof(elmnt_typ) - 1] = '0';
        ToUpper(elmnt_typ);

        ttab.SetToType("DRE");
        ttab.Translate(dreid_typ,atom->GetType());
        ttab.SetToType("HAD");
        ttab.Translate(max_val_str,atom->GetType());
        max_val = atoi(max_val_str);
        if (max_val == 0)
          max_val = 1;
        snprintf(atm_sym,16,"%s%d",elmnt_typ,atom->GetIdx());
        snprintf(buffer,BUFF_SIZE,"%6s %5d %-5s %3s %1s %5s%10.5f%10.5f%10.5f %-5s%3d%2d %8.5f\n",
                "HETATM",
                atom->GetIdx(),
                atm_sym,
                "RES",
                "A",
                "444",
                atom->GetX(),
                atom->GetY(),
                atom->GetZ(),
                dreid_typ,
                max_val,
                0,
                atom->GetPartialCharge());
        ofs << buffer;
      }
    ofs<< "FORMAT CONECT (a6,12i6)\n\n";

    OBAtom *nbr;
    vector<OBBond*>::iterator j;
    for (atom = mol.BeginAtom(i);atom;atom = mol.NextAtom(i))
      if (atom->GetValence())
        {
          snprintf(buffer,BUFF_SIZE,"CONECT%6d",atom->GetIdx());
          ofs << buffer;
          for (nbr = atom->BeginNbrAtom(j);nbr;nbr = atom->NextNbrAtom(j))
            {
              snprintf(buffer,BUFF_SIZE,"%6d",nbr->GetIdx());
              ofs << buffer;
            }
          ofs << endl;

          snprintf(buffer,BUFF_SIZE,"ORDER %6d",atom->GetIdx());
          ofs << buffer;
          for (nbr = atom->BeginNbrAtom(j);nbr;nbr = atom->NextNbrAtom(j))
            {
              snprintf(buffer,BUFF_SIZE,"%6d",(*j)->GetBO());
              ofs << buffer;
            }
          ofs << endl;
        }

    ofs << "END" << endl;
    return(true);
  }
Ejemplo n.º 4
0
  bool PDBFormat::WriteMolecule(OBBase* pOb, OBConversion* pConv)
  {
    OBMol* pmol = dynamic_cast<OBMol*>(pOb);
    if(pmol==NULL)
      return false;

    //Define some references so we can use the old parameter names
    ostream &ofs = *pConv->GetOutStream();
    OBMol &mol = *pmol;

    unsigned int i;
    char buffer[BUFF_SIZE];
    char type_name[10], padded_name[10];
    char the_res[10];
    char the_chain = ' ';
    const char *element_name;
    int res_num;
    bool het=true;
    int model_num = 0;
    if (!pConv->IsLast() || pConv->GetOutputIndex() > 1)
      { // More than one molecule record
        model_num = pConv->GetOutputIndex(); // MODEL 1-based index
        snprintf(buffer, BUFF_SIZE, "MODEL %8d", model_num);
        ofs << buffer << endl;
      }

    if (strlen(mol.GetTitle()) > 0)
      snprintf(buffer, BUFF_SIZE, "COMPND    %s ",mol.GetTitle());
    else
      snprintf(buffer, BUFF_SIZE, "COMPND    UNNAMED");
    ofs << buffer << endl;

    snprintf(buffer, BUFF_SIZE, "AUTHOR    GENERATED BY OPEN BABEL %s",BABEL_VERSION);
    ofs << buffer << endl;

    // Write CRYST1 record, containing unit cell parameters, space group
    // and Z value (supposed to be 1)
    if (pmol->HasData(OBGenericDataType::UnitCell))
      {
        OBUnitCell *pUC = (OBUnitCell*)pmol->GetData(OBGenericDataType::UnitCell);
	
        snprintf(buffer, BUFF_SIZE,
                 "CRYST1%9.3f%9.3f%9.3f%7.2f%7.2f%7.2f %-11s 1",
                 pUC->GetA(), pUC->GetB(), pUC->GetC(),
                 pUC->GetAlpha(), pUC->GetBeta(), pUC->GetGamma(),
                 pUC->GetSpaceGroup() ?
                 pUC->GetSpaceGroup()->GetHMName().c_str() : "P1");
        ofs << buffer << endl;
      }

    // before we write any records, we should check to see if any coord < -1000
    // which will cause errors in the formatting

    double minX, minY, minZ;
    minX = minY = minZ = -999.0f;
    FOR_ATOMS_OF_MOL(a, mol)
      {
        if (a->GetX() < minX)
          minX = a->GetX();
        if (a->GetY() < minY)
          minY = a->GetY();
        if (a->GetZ() < minZ)
          minZ = a->GetZ();
      }
    vector3 transV = VZero;
    if (minX < -999.0)
      transV.SetX(-1.0*minX - 900.0);
    if (minY < -999.0)
      transV.SetY(-1.0*minY - 900.0);
    if (minZ < -999.0)
      transV.SetZ(-1.0*minZ - 900.0);

    // if minX, minY, or minZ was never changed, shift will be 0.0f
    // otherwise, move enough so that smallest coord is > -999.0f
    mol.Translate(transV);

    OBAtom *atom;
    OBResidue *res;
    for (i = 1; i <= mol.NumAtoms(); i++)
      {
        atom = mol.GetAtom(i);
        strncpy(type_name, etab.GetSymbol(atom->GetAtomicNum()), sizeof(type_name));
        type_name[sizeof(type_name) - 1] = '\0';

        //two char. elements are on position 13 and 14 one char. start at 14
        if (strlen(type_name) > 1)
          type_name[1] = toupper(type_name[1]);
        else
          {
            char tmp[10];
            strncpy(tmp, type_name, 10);
            snprintf(type_name, sizeof(type_name), " %-3s", tmp);
          }

        if ( (res = atom->GetResidue()) != 0 )
          {
            het = res->IsHetAtom(atom);
            snprintf(the_res,4,"%s",(char*)res->GetName().c_str());
            snprintf(type_name,5,"%s",(char*)res->GetAtomID(atom).c_str());
            the_chain = res->GetChain();

            //two char. elements are on position 13 and 14 one char. start at 14
            if (strlen(etab.GetSymbol(atom->GetAtomicNum())) == 1)
              {
                if (strlen(type_name) < 4)
                  {
                    char tmp[16];
                    strncpy(tmp, type_name, 16);
                    snprintf(padded_name, sizeof(padded_name), " %-3s", tmp);
                    strncpy(type_name,padded_name,4);
                    type_name[4] = '\0';
                  }
                else
                  {
                    /*
                      type_name[4] = type_name[3];
                      type_name[3] = type_name[2];
                      type_name[2] = type_name[1];
                      type_name[1] = type_name[0];
                      type_name[0] = type_name[4];
                    */
                    type_name[4] = '\0';
                  }
              }
            res_num = res->GetNum();
          }
        else
          {
            strcpy(the_res,"UNK");
            snprintf(padded_name,sizeof(padded_name), "%s",type_name);
            strncpy(type_name,padded_name,4);
            type_name[4] = '\0';
            res_num = 1;
          }

        element_name = etab.GetSymbol(atom->GetAtomicNum());
        
        int charge = atom->GetFormalCharge();
        char scharge[3] = { ' ', ' ', '\0' };
        if(0 != charge)
          {
            snprintf(scharge, 3, "%+d", charge);
            char tmp = scharge[1];
            scharge[1] = scharge[0];
            scharge[0] = tmp;
          }
        snprintf(buffer, BUFF_SIZE, "%s%5d %-4s %-3s %c%4d    %8.3f%8.3f%8.3f  1.00  0.00          %2s%2s\n",
                 het?"HETATM":"ATOM  ",
                 i,
                 type_name,
                 the_res,
                 the_chain,
                 res_num,
                 atom->GetX(),
                 atom->GetY(),
                 atom->GetZ(),
                 element_name,
                 scharge);
        ofs << buffer;
      }

    OBAtom *nbr;
    vector<OBBond*>::iterator k;
    for (i = 1; i <= mol.NumAtoms(); i ++)
      {
        atom = mol.GetAtom(i);
        if (atom->GetValence() == 0)
          continue; // no need to write a CONECT record -- no bonds

        snprintf(buffer, BUFF_SIZE, "CONECT%5d", i);
        ofs << buffer;
        // Write out up to 4 real bonds per line PR#1711154
        unsigned int currentValence = 0;
        for (nbr = atom->BeginNbrAtom(k);nbr;nbr = atom->NextNbrAtom(k))
          {
            unsigned int order = mol.GetBond(atom, nbr)->GetBondOrder();
            unsigned int it_order = 0;
            for( it_order = 0; it_order < order; it_order++ )
              {
                if (0 != currentValence && 0 == currentValence % 4)
                  {
                    // Add the trailing space to finish this record
                    ofs << "                                       \n";
                    // write the start of a new CONECT record
                    snprintf(buffer, BUFF_SIZE, "CONECT%5d", i);
                    ofs << buffer;              
                  }
                currentValence++;
                snprintf(buffer, BUFF_SIZE, "%5d", nbr->GetIdx());
                ofs << buffer;
              }
          }

        // Add trailing spaces
        unsigned int remainingValence = currentValence % 4;
        if( 0 < remainingValence )
          {
            for (int count = 0; count < (4 - remainingValence); count++) 
              {
                snprintf(buffer, BUFF_SIZE, "     ");
                ofs << buffer;
              }
          }
        ofs << "                                                 \n";
      }

    snprintf(buffer, BUFF_SIZE, "MASTER        0    0    0    0    0    0    0    0 ");
    ofs << buffer;
    snprintf(buffer, BUFF_SIZE, "%4d    0 %4d    0\n",mol.NumAtoms(),mol.NumAtoms());
    ofs << buffer;

    ofs << "END\n";
    if (model_num) {
      ofs << "ENDMDL" << endl;
    }

    return(true);
  }