/**
   * Test for SF bug #1309731.
   *
   * @cdk.bug 1309731
   */
  @Test
  public void testModelBuilder3D_keepChemObjectIDs() throws Exception {
    ModelBuilder3D mb3d = ModelBuilder3D.getInstance();

    IMolecule methanol = new org.openscience.cdk.Molecule();
    IChemObjectBuilder builder = methanol.getBuilder();

    IAtom carbon1 = builder.newInstance(IAtom.class, "C");
    carbon1.setID("carbon1");
    methanol.addAtom(carbon1);
    for (int i = 0; i < 3; i++) {
      IAtom hydrogen = builder.newInstance(IAtom.class, "H");
      methanol.addAtom(hydrogen);
      methanol.addBond(builder.newInstance(IBond.class, carbon1, hydrogen, IBond.Order.SINGLE));
    }
    IAtom oxygen1 = builder.newInstance(IAtom.class, "O");
    oxygen1.setID("oxygen1");
    methanol.addAtom(oxygen1);
    methanol.addBond(builder.newInstance(IBond.class, carbon1, oxygen1, IBond.Order.SINGLE));
    IAtom hydrogen = builder.newInstance(IAtom.class, "H");
    methanol.addAtom(hydrogen);
    methanol.addBond(builder.newInstance(IBond.class, hydrogen, oxygen1, IBond.Order.SINGLE));

    Assert.assertEquals(6, methanol.getAtomCount());
    Assert.assertEquals(5, methanol.getBondCount());

    mb3d.generate3DCoordinates(methanol, false);

    checkAverageBondLength(methanol);
    Assert.assertEquals("carbon1", carbon1.getID());
    Assert.assertEquals("oxygen1", oxygen1.getID());
  }
  /** Converts an Atom to a MSML Atom element */
  protected AtomType convertAtom(IAtom atom, String parentID) {
    AtomType atomElement = new AtomType();
    String id = "";
    if (atom.getID() != null) {
      id = atom.getID();
    } else {
      id = Integer.toString(atom.hashCode());
    }
    String atomID = parentID + PREFIX_ATOM + id;
    atomElement.setId(atomID);
    atomElement.setCustomId("" + id);
    // atom name
    atomElement.setTitle(atom.getAtomTypeName());
    // element name
    atomElement.setElementType(atom.getSymbol());
    double x, y, z;
    // set choords
    if (atom.getPoint3d() != null) {
      x = atom.getPoint3d().x;
      y = atom.getPoint3d().y;
      z = atom.getPoint3d().z;
    } else { // what if mol in 2d? -> has to use getPoint2d
      x = atom.getPoint2d().x;
      y = atom.getPoint2d().y;
      z = 0.0;
    }
    if (atom.getFormalCharge() != null) {
      atomElement.setFormalCharge(BigInteger.valueOf(atom.getFormalCharge()));
    }
    atomElement.setX3(new Float(x));
    atomElement.setY3(new Float(y));
    atomElement.setZ3(new Float(z));

    return atomElement;
  }
  @Test
  public void testBond() throws Exception {
    String cmlString =
        "<molecule id='m1'><atomArray><atom id='a1'/><atom id='a2'/></atomArray><bondArray><bond id='b1' atomRefs2='a1 a2'/></bondArray></molecule>";

    IChemFile chemFile = parseCMLString(cmlString);
    IMolecule mol = checkForSingleMoleculeFile(chemFile);

    Assert.assertEquals(2, mol.getAtomCount());
    Assert.assertEquals(1, mol.getBondCount());
    org.openscience.cdk.interfaces.IBond bond = mol.getBond(0);
    Assert.assertEquals(2, bond.getAtomCount());
    IAtom atom1 = bond.getAtom(0);
    IAtom atom2 = bond.getAtom(1);
    Assert.assertEquals("a1", atom1.getID());
    Assert.assertEquals("a2", atom2.getID());
  }
  @Test
  public void testAtomId3() throws Exception {
    String cmlString = "<molecule id='m1'><atomArray atomID='a1 a2 a3'/></molecule>";

    IChemFile chemFile = parseCMLString(cmlString);
    IMolecule mol = checkForSingleMoleculeFile(chemFile);

    Assert.assertEquals(3, mol.getAtomCount());
    IAtom atom = mol.getAtom(1);
    Assert.assertEquals("a2", atom.getID());
  }
  /**
   * Read a Reaction from a file in MDL RXN format
   *
   * @return The Reaction that was read from the MDL file.
   */
  private IReaction readReaction(IChemObjectBuilder builder) throws CDKException {
    IReaction reaction = builder.newReaction();
    try {
      input.readLine(); // first line should be $RXN
      input.readLine(); // second line
      input.readLine(); // third line
      input.readLine(); // fourth line
    } catch (IOException exception) {
      logger.debug(exception);
      throw new CDKException("Error while reading header of RXN file", exception);
    }

    int reactantCount = 0;
    int productCount = 0;
    try {
      String countsLine = input.readLine();
      /* this line contains the number of reactants
      and products */
      StringTokenizer tokenizer = new StringTokenizer(countsLine);
      reactantCount = Integer.valueOf(tokenizer.nextToken()).intValue();
      logger.info("Expecting " + reactantCount + " reactants in file");
      productCount = Integer.valueOf(tokenizer.nextToken()).intValue();
      logger.info("Expecting " + productCount + " products in file");
    } catch (Exception exception) {
      logger.debug(exception);
      throw new CDKException("Error while counts line of RXN file", exception);
    }

    // now read the reactants
    try {
      for (int i = 1; i <= reactantCount; i++) {
        StringBuffer molFile = new StringBuffer();
        input.readLine(); // announceMDLFileLine
        String molFileLine = "";
        do {
          molFileLine = input.readLine();
          molFile.append(molFileLine);
          molFile.append(System.getProperty("line.separator"));
        } while (!molFileLine.equals("M  END"));

        // read MDL molfile content
        // Changed this to mdlv2000 reader
        MDLV2000Reader reader =
            new MDLV2000Reader(new StringReader(molFile.toString()), super.mode);
        IMolecule reactant = (IMolecule) reader.read(builder.newMolecule());

        // add reactant
        reaction.addReactant(reactant);
      }
    } catch (CDKException exception) {
      // rethrow exception from MDLReader
      throw exception;
    } catch (Exception exception) {
      logger.debug(exception);
      throw new CDKException("Error while reading reactant", exception);
    }

    // now read the products
    try {
      for (int i = 1; i <= productCount; i++) {
        StringBuffer molFile = new StringBuffer();
        input.readLine(); // String announceMDLFileLine =
        String molFileLine = "";
        do {
          molFileLine = input.readLine();
          molFile.append(molFileLine);
          molFile.append(System.getProperty("line.separator"));
        } while (!molFileLine.equals("M  END"));

        // read MDL molfile content
        MDLV2000Reader reader = new MDLV2000Reader(new StringReader(molFile.toString()));
        IMolecule product = (IMolecule) reader.read(builder.newMolecule());

        // add reactant
        reaction.addProduct(product);
      }
    } catch (CDKException exception) {
      // rethrow exception from MDLReader
      throw exception;
    } catch (Exception exception) {
      logger.debug(exception);
      throw new CDKException("Error while reading products", exception);
    }

    // now try to map things, if wanted
    logger.info("Reading atom-atom mapping from file");
    // distribute all atoms over two AtomContainer's
    IAtomContainer reactingSide = builder.newAtomContainer();
    java.util.Iterator molecules = reaction.getReactants().molecules().iterator();
    while (molecules.hasNext()) {
      reactingSide.add((IMolecule) molecules.next());
    }
    IAtomContainer producedSide = builder.newAtomContainer();
    molecules = reaction.getProducts().molecules().iterator();
    while (molecules.hasNext()) {
      producedSide.add((IMolecule) molecules.next());
    }

    // map the atoms
    int mappingCount = 0;
    //        IAtom[] reactantAtoms = reactingSide.getAtoms();
    //        IAtom[] producedAtoms = producedSide.getAtoms();
    for (int i = 0; i < reactingSide.getAtomCount(); i++) {
      for (int j = 0; j < producedSide.getAtomCount(); j++) {
        IAtom eductAtom = reactingSide.getAtom(i);
        IAtom productAtom = producedSide.getAtom(j);
        if (eductAtom.getID() != null && eductAtom.getID().equals(productAtom.getID())) {
          reaction.addMapping(builder.newMapping(eductAtom, productAtom));
          mappingCount++;
          break;
        }
      }
    }
    logger.info("Mapped atom pairs: " + mappingCount);

    return reaction;
  }
Beispiel #6
0
 @Override
 public BoundsTree layout(IAtom atom, Graphics2D g) {
   Rectangle2D idBounds;
   this.currentObject = atom;
   String id = atom.getID();
   IAtomContainer molecule = null;
   if (this.parent != null) {
     molecule = (IAtomContainer) this.parent.getCurrentObject();
   }
   this.boundsTree = new BoundsTree(atom.getID());
   if (molecule == null || this.shouldDraw(atom, molecule)) {
     Integer implicitHydrogenCount;
     this.boundsTree.add(id + ":symbol", this.layoutAtomSymbol(atom, g));
     if (this.isCharged(atom)) {
       Rectangle2D chargeBounds = this.layoutCharge(atom, g);
       this.boundsTree.add(id + ":charge", chargeBounds);
     }
     if (this.params.drawImplicitHydrogens
         && (implicitHydrogenCount = atom.getImplicitHydrogenCount()) != null
         && implicitHydrogenCount > 0) {
       int align = 1;
       if (molecule != null) {
         GeometryTools.getBestAlignmentForLabel((IAtomContainer) molecule, (IAtom) atom);
       }
       LabelManager.AnnotationPosition suggestedPosition =
           this.labelManager.alignmentToAnnotationPosition(align);
       if (atom.getSymbol().equals("O")
           && (molecule == null || molecule.getConnectedAtomsCount(atom) == 0)) {
         suggestedPosition = LabelManager.AnnotationPosition.W;
       }
       if (this.labelManager.isUsed(atom, suggestedPosition)) {
         suggestedPosition = this.labelManager.getNextSparePosition(atom);
       }
       this.labelManager.setUsedPosition(atom, suggestedPosition);
       Rectangle2D hBounds =
           this.layoutImplicitHydrogens(atom, implicitHydrogenCount, suggestedPosition, g);
       if (hBounds != null) {
         this.boundsTree.add(id + ":hs", hBounds);
       }
     }
   } else if (this.params.drawRS && this.chiralMap.containsKey(atom)) {
     this.boundsTree.add(
         id + ":chiral", this.layoutChiralSymbol(atom, this.chiralMap.get(atom), g));
   } else {
     Point2d p = atom.getPoint2d();
     this.boundsTree.add(id + ":symbol", new Point2D.Double(p.x, p.y));
   }
   if (this.params.drawAtomID
       && molecule != null
       && (idBounds = this.layoutAtomID(atom, molecule, g)) != null) {
     this.boundsTree.add(id + ":id", idBounds);
   }
   if (this.params.drawLonePairs && molecule != null) {
     int lonePairCount = 0;
     for (ILonePair lonePair : molecule.lonePairs()) {
       if (!lonePair.contains(atom)) {
         continue;
       }
       ++lonePairCount;
     }
     if (lonePairCount > 0) {
       Stroke stroke = g.getStroke();
       g.setStroke(new BasicStroke(0.05f));
       this.layoutElectronPairs(atom, molecule, lonePairCount, g);
       g.setStroke(stroke);
     }
   }
   return this.boundsTree;
 }
Beispiel #7
0
 public Rectangle2D layoutAtomID(IAtom atom, IAtomContainer container, Graphics2D g) {
   String atomID = atom.getID();
   if (atomID == null) {
     return null;
   }
   g.setFont(this.atomSymbolFont);
   Point2d p = atom.getPoint2d();
   Rectangle2D atomSymbolBounds =
       this.shouldDraw(atom, container)
           ? this.getTextBounds(g, atom.getSymbol())
           : new Rectangle2D.Double(p.x, p.y, 1.0, 1.0);
   g.setFont(this.atomIDFont);
   Rectangle2D bounds = this.getTextBounds(g, atomID);
   Point2d pID = new Point2d(p);
   LabelManager.AnnotationPosition suggestedPosition =
       this.labelManager.alignmentToAnnotationPosition(
           GeometryTools.getBestAlignmentForLabelXY((IAtomContainer) container, (IAtom) atom));
   LabelManager.AnnotationPosition pos =
       this.labelManager.isUsed(atom, suggestedPosition)
           ? this.labelManager.getNextSparePosition(atom)
           : suggestedPosition;
   double aW2 = atomSymbolBounds.getWidth() / 2.0;
   double bW2 = bounds.getWidth() / 2.0;
   double aH2 = atomSymbolBounds.getHeight() / 2.0;
   double bH2 = bounds.getHeight() / 2.0;
   if (null != pos)
     switch (pos) {
       case N:
         pID.y -= aH2 + bH2;
         break;
       case NE:
         pID.x += aW2 + bW2;
         pID.y -= aH2 + bH2;
         break;
       case E:
         pID.x += aW2 + bW2;
         break;
       case SE:
         pID.x += aW2 + bW2;
         pID.y += aH2 + bH2;
         break;
       case S:
         pID.y += aH2 + bH2;
         break;
       case SW:
         pID.x -= aW2 + bW2;
         pID.y += aH2 + bH2;
         break;
       case W:
         pID.x -= aW2 + bW2;
         break;
       case NW:
         pID.x -= aW2 + bW2;
         pID.y -= aH2 + bH2;
         break;
       default:
         pID.x += aW2 + bW2;
         break;
     }
   if (pos != null) {
     this.labelManager.setUsedPosition(atom, pos);
   }
   g.setFont(this.atomSymbolFont);
   return new Rectangle2D.Double(
       pID.x - bounds.getWidth() / 2.0,
       pID.y - bounds.getHeight() / 2.0,
       bounds.getWidth(),
       bounds.getHeight());
 }