public bool IsSaturated(IAtom atom, IAtomContainer container)
{
var type = atomTypeList.GetAtomType(atom.AtomTypeName);
if (type == null)
{
throw new CDKException($"Atom type is not a recognized CDK atom type: {atom.AtomTypeName}");
}
if (type.FormalNeighbourCount == null)
{
throw new CDKException($"Atom type is too general; cannot decide the number of implicit hydrogen to add for: {atom.AtomTypeName}");
}
if (type.GetProperty <object>(CDKPropertyName.PiBondCount) == null)
{
throw new CDKException($"Atom type is too general; cannot determine the number of pi bonds for: {atom.AtomTypeName}");
}
var bondOrderSum = container.GetBondOrderSum(atom);
var maxBondOrder = container.GetMaximumBondOrder(atom);
int?hcount = atom.ImplicitHydrogenCount == null ? 0 : atom.ImplicitHydrogenCount;
int piBondCount = type.GetProperty <int?>(CDKPropertyName.PiBondCount).Value;
int formalNeighborCount = type.FormalNeighbourCount.Value;
int typeMaxBondOrder = piBondCount + 1;
int typeBondOrderSum = formalNeighborCount + piBondCount;
if (bondOrderSum + hcount == typeBondOrderSum && maxBondOrder.Numeric() <= typeMaxBondOrder)
{
return(true);
}
return(false);
}
/// <summary>
/// Determines if the atom can be of type <see cref="IAtomType"/>. That is, it sees if this
/// <see cref="IAtomType"/> only differs in bond orders, or implicit hydrogen count.
/// </summary>
private static bool CouldMatchAtomType(IAtomContainer container, IAtom atom, IAtomType type)
{
var bondOrderSum = container.GetBondOrderSum(atom);
var maxBondOrder = container.GetMaximumBondOrder(atom);
return(CouldMatchAtomType(atom, bondOrderSum, maxBondOrder, type));
}
/// <summary>
/// Checks if the current atom has exceeded its bond order sum value.
/// </summary>
/// <param name="atom">The Atom to check</param>
/// <param name="ac">The atom container context</param>
/// <returns>oversaturated or not</returns>
public bool IsOverSaturated(IAtom atom, IAtomContainer ac)
{
var atomTypes = structgenATF.GetAtomTypes(atom.Symbol);
if (!atomTypes.Any())
{
return(false);
}
var bondOrderSum = ac.GetBondOrderSum(atom);
var maxBondOrder = ac.GetMaximumBondOrder(atom);
var hcount = atom.ImplicitHydrogenCount ?? 0;
var charge = atom.FormalCharge ?? 0;
try
{
Debug.WriteLine($"*** Checking saturation of atom {ac.Atoms.IndexOf(atom)} ***");
Debug.WriteLine($"bondOrderSum: {bondOrderSum}");
Debug.WriteLine($"maxBondOrder: {maxBondOrder}");
Debug.WriteLine($"hcount: {hcount}");
}
catch (Exception)
{
}
foreach (var atomType in atomTypes)
{
if (bondOrderSum - charge + hcount > atomType.BondOrderSum)
{
Debug.WriteLine("*** Good ! ***");
return(true);
}
}
Debug.WriteLine("*** Bad ! ***");
return(false);
}
/// <summary>
/// Checks whether an atom is saturated by comparing it with known atom types.
/// </summary>
/// <returns><see langword="true"/> if the atom is an pseudo atom and when the element is not in the list.</returns>
public bool IsSaturated(IAtom atom, IAtomContainer container)
{
if (atom is IPseudoAtom)
{
Debug.WriteLine("don't figure it out... it simply does not lack H's");
return(true);
}
var atomTypes = structgenATF.GetAtomTypes(atom.Symbol);
if (atomTypes.Any())
{
Trace.TraceWarning($"Missing entry in atom type list for {atom.Symbol}");
return(true);
}
var bondOrderSum = container.GetBondOrderSum(atom);
var maxBondOrder = container.GetMaximumBondOrder(atom);
var hcount = atom.ImplicitHydrogenCount.Value;
var charge = atom.FormalCharge.Value;
Debug.WriteLine($"Checking saturation of atom {atom.Symbol}");
Debug.WriteLine($"bondOrderSum: {bondOrderSum}");
Debug.WriteLine($"maxBondOrder: {maxBondOrder}");
Debug.WriteLine($"hcount: {hcount}");
Debug.WriteLine($"charge: {charge}");
bool elementPlusChargeMatches = false;
foreach (var type in atomTypes)
{
if (CouldMatchAtomType(atom, bondOrderSum, maxBondOrder, type))
{
if (bondOrderSum + hcount == type.BondOrderSum &&
!BondManipulator.IsHigherOrder(maxBondOrder, type.MaxBondOrder))
{
Debug.WriteLine($"We have a match: {type}");
Debug.WriteLine($"Atom is saturated: {atom.Symbol}");
return(true);
}
else
{
// ok, the element and charge matche, but unfulfilled
elementPlusChargeMatches = true;
}
} // else: formal charges don't match
}
if (elementPlusChargeMatches)
{
Debug.WriteLine("No, atom is not saturated.");
return(false);
}
// ok, the found atom was not in the list
Trace.TraceError("Could not find atom type!");
throw new CDKException($"The atom with element {atom.Symbol} and charge {charge} is not found.");
}
/// <summary>
/// Checks whether an atom is saturated by comparing it with known atom types.
/// </summary>
public bool IsSaturated(IAtom atom, IAtomContainer ac)
{
var atomTypes = structgenATF.GetAtomTypes(atom.Symbol);
if (!atomTypes.Any())
{
return(true);
}
double bondOrderSum = 0;
var maxBondOrder = BondOrder.Unset;
int hcount = 0;
int charge = 0;
bool isInited = false;
foreach (var atomType in atomTypes)
{
if (!isInited)
{
isInited = true;
bondOrderSum = ac.GetBondOrderSum(atom);
maxBondOrder = ac.GetMaximumBondOrder(atom);
hcount = atom.ImplicitHydrogenCount ?? 0;
charge = atom.FormalCharge ?? 0;
try
{
Debug.WriteLine($"*** Checking saturation of atom {atom.Symbol} {ac.Atoms.IndexOf(atom)} ***");
Debug.WriteLine($"bondOrderSum: {bondOrderSum}");
Debug.WriteLine($"maxBondOrder: {maxBondOrder}");
Debug.WriteLine($"hcount: {hcount}");
}
catch (Exception exc)
{
Debug.WriteLine(exc);
}
}
if (bondOrderSum - charge + hcount == atomType.BondOrderSum &&
!BondManipulator.IsHigherOrder(maxBondOrder, atomType.MaxBondOrder))
{
Debug.WriteLine("*** Good ! ***");
return(true);
}
}
Debug.WriteLine("*** Bad ! ***");
return(false);
}
private static void SetActiveCenters(IAtomContainer reactant, int length, bool checkPrev, AtomCheck atomCheck)
{
var hcg = new HOSECodeGenerator();
foreach (var atomi in reactant.Atoms)
{
if (reactant.GetConnectedSingleElectrons(atomi).Count() == 1)
{
IEnumerable <IAtom> atom1s = null;
if (checkPrev)
{
hcg.GetSpheres(reactant, atomi, length - 1, true);
atom1s = hcg.GetNodesInSphere(length - 1);
}
hcg.GetSpheres(reactant, atomi, length, true);
foreach (var atoml in hcg.GetNodesInSphere(length))
{
if (atoml != null &&
!atoml.IsInRing &&
(atoml.FormalCharge ?? 0) == 0 &&
!atoml.AtomicNumber.Equals(AtomicNumbers.H) &&
reactant.GetMaximumBondOrder(atoml) == BondOrder.Single)
{
foreach (var atomR in reactant.GetConnectedAtoms(atoml))
{
if (atom1s != null && atom1s.Contains(atomR))
{
continue;
}
if (atomCheck(atomR))
{
atomi.IsReactiveCenter = true;
atoml.IsReactiveCenter = true;
atomR.IsReactiveCenter = true;
reactant.GetBond(atomR, atoml).IsReactiveCenter = true;;
}
}
}
}
}
}
}
public bool HasPerfectConfiguration(IAtom atom, IAtomContainer ac)
{
var bondOrderSum = ac.GetBondOrderSum(atom);
var maxBondOrder = ac.GetMaximumBondOrder(atom);
var atomTypes = structgenATF.GetAtomTypes(atom.Symbol);
if (!atomTypes.Any())
{
return(true);
}
Debug.WriteLine("*** Checking for perfect configuration ***");
try
{
Debug.WriteLine($"Checking configuration of atom {ac.Atoms.IndexOf(atom)}");
Debug.WriteLine($"Atom has bondOrderSum = {bondOrderSum}");
Debug.WriteLine($"Atom has max = {bondOrderSum}");
}
catch (Exception)
{
}
foreach (var atomType in atomTypes)
{
if (bondOrderSum == atomType.BondOrderSum && maxBondOrder == atomType.MaxBondOrder)
{
try
{
Debug.WriteLine($"Atom {ac.Atoms.IndexOf(atom)} has perfect configuration");
}
catch (Exception)
{
}
return(true);
}
}
try
{
Debug.WriteLine($"*** Atom {ac.Atoms.IndexOf(atom)} has imperfect configuration ***");
}
catch (Exception)
{
}
return(false);
}
/// <summary>
/// Calculate the electronegativity of orbitals pi.
/// </summary>
/// <param name="ac"></param>
/// <param name="atom">atom for which effective atom electronegativity should be calculated</param>
/// <param name="maxIterations">The maximal number of Iteration</param>
/// <param name="maxResonStruc">The maximal number of Resonance Structures</param>
/// <returns>Electronegativity of orbitals pi.</returns>
public double CalculatePiElectronegativity(IAtomContainer ac, IAtom atom, int maxIterations, int maxResonStruc)
{
MaxIterations = maxIterations;
MaxResonanceStructures = maxResonStruc;
double electronegativity = 0;
try
{
if (!ac.Equals(acOldP))
{
molPi = ac.Builder.NewAtomContainer(ac);
peoe = new GasteigerMarsiliPartialCharges();
peoe.AssignGasteigerMarsiliSigmaPartialCharges(molPi, true);
var iSet = ac.Builder.NewAtomContainerSet();
iSet.Add(molPi);
iSet.Add(molPi);
gasteigerFactors = pepe.AssignrPiMarsilliFactors(iSet);
acOldP = ac;
}
IAtom atomi = molPi.Atoms[ac.Atoms.IndexOf(atom)];
int atomPosition = molPi.Atoms.IndexOf(atomi);
int stepSize = pepe.StepSize;
int start = (stepSize * (atomPosition) + atomPosition);
double q = atomi.Charge.Value;
if (molPi.GetConnectedLonePairs(molPi.Atoms[atomPosition]).Any() ||
molPi.GetMaximumBondOrder(atomi) != BondOrder.Single || atomi.FormalCharge != 0)
{
return((gasteigerFactors[1][start]) + (q * gasteigerFactors[1][start + 1]) + (gasteigerFactors[1][start + 2] * (q * q)));
}
}
catch (Exception e)
{
Trace.TraceError(e.StackTrace);
}
return(electronegativity);
}
/// <summary>
/// Calculate the count of atoms of the largest pi system in the supplied <see cref="IAtomContainer"/>.
/// </summary>
/// <returns>the number of atoms in the largest pi system of this AtomContainer</returns>
public Result Calculate(IAtomContainer container)
{
container = (IAtomContainer)container.Clone();
if (checkAromaticity)
{
AtomContainerManipulator.PercieveAtomTypesAndConfigureAtoms(container);
Aromaticity.CDKLegacy.Apply(container);
}
int largestPiSystemAtomsCount = 0;
//Set all VisitedFlags to False
for (int i = 0; i < container.Atoms.Count; i++)
{
container.Atoms[i].IsVisited = false;
}
for (int i = 0; i < container.Atoms.Count; i++)
{
//Possible pi System double bond or triple bond, charge, N or O (free electron pair)
if ((container.GetMaximumBondOrder(container.Atoms[i]) != BondOrder.Single ||
Math.Abs(container.Atoms[i].FormalCharge.Value) >= 1 ||
container.Atoms[i].IsAromatic ||
container.Atoms[i].AtomicNumber.Equals(AtomicNumbers.N) ||
container.Atoms[i].AtomicNumber.Equals(AtomicNumbers.O)) &&
!container.Atoms[i].IsVisited)
{
var startSphere = new List <IAtom>();
var path = new List <IAtom>();
startSphere.Add(container.Atoms[i]);
BreadthFirstSearch(container, startSphere, path);
if (path.Count > largestPiSystemAtomsCount)
{
largestPiSystemAtomsCount = path.Count;
}
}
}
return(new Result(largestPiSystemAtomsCount));
}
/// <summary>
/// Finds the AtomType matching the Atom's element symbol, formal charge and
/// hybridization state.
/// </summary>
/// <param name="atomContainer">AtomContainer</param>
/// <param name="atom">the target atom</param>
/// <exception cref="CDKException">Exception thrown if something goes wrong</exception>
/// <returns>the matching AtomType</returns>
public IEnumerable <IAtomType> PossibleAtomTypes(IAtomContainer atomContainer, IAtom atom)
{
var bondOrderSum = atomContainer.GetBondOrderSum(atom);
var maxBondOrder = atomContainer.GetMaximumBondOrder(atom);
var charge = atom.FormalCharge.Value;
var hcount = atom.ImplicitHydrogenCount.Value;
var types = factory.GetAtomTypes(atom.Symbol);
foreach (var type in types)
{
Debug.WriteLine(" ... matching atom ", atom, " vs ", type);
if (bondOrderSum - charge + hcount <= type.BondOrderSum &&
!BondManipulator.IsHigherOrder(maxBondOrder, type.MaxBondOrder))
{
yield return(type);
}
}
Debug.WriteLine(" No Match");
yield break;
}
/// <summary>
/// Performs a breadthFirstSearch in an AtomContainer starting with a
/// particular sphere, which usually consists of one start atom, and searches
/// for a pi system.
/// </summary>
/// <param name="container">The AtomContainer to be searched</param>
/// <param name="sphere">A sphere of atoms to start the search with</param>
/// <param name="path">An array list which stores the atoms belonging to the pi system</param>
/// <exception cref="CDKException"></exception>
private void BreadthFirstSearch(IAtomContainer container, List <IAtom> sphere, List <IAtom> path)
{
IAtom nextAtom;
var newSphere = new List <IAtom>();
foreach (var atom in sphere)
{
var bonds = container.GetConnectedBonds(atom);
foreach (var bond in bonds)
{
nextAtom = ((IBond)bond).GetConnectedAtom(atom);
if ((container.GetMaximumBondOrder(nextAtom) != BondOrder.Single ||
Math.Abs(nextAtom.FormalCharge.Value) >= 1 || nextAtom.IsAromatic ||
nextAtom.AtomicNumber.Equals(AtomicNumbers.N) ||
nextAtom.AtomicNumber.Equals(AtomicNumbers.O)) &&
!nextAtom.IsVisited)
{
//Debug.WriteLine("BDS> AtomNr:"+container.Atoms.IndexOf(nextAtom)+" maxBondOrder:"+container.GetMaximumBondOrder(nextAtom)+" Aromatic:"+nextAtom.IsAromatic+" FormalCharge:"+nextAtom.FormalCharge+" Charge:"+nextAtom.Charge+" Flag:"+nextAtom.IsVisited);
path.Add(nextAtom);
//Debug.WriteLine("BreadthFirstSearch is meeting new atom " + (nextAtomNr + 1));
nextAtom.IsVisited = true;
if (container.GetConnectedBonds(nextAtom).Count() > 1)
{
newSphere.Add(nextAtom);
}
}
else
{
nextAtom.IsVisited = true;
}
}
}
if (newSphere.Count > 0)
{
BreadthFirstSearch(container, newSphere, path);
}
}
/// <summary>
/// Method which stores and assigns the factors a,b,c and CHI+.
/// </summary>
/// <param name="ac">AtomContainer</param>
/// <returns>Array of doubles [a1,b1,c1,denom1,chi1,q1...an,bn,cn...] 1:Atom 1-n in AtomContainer</returns>
public double[] AssignGasteigerSigmaMarsiliFactors(IAtomContainer ac)
{
//a,b,c,denom,chi,q
var gasteigerFactors = new double[(ac.Atoms.Count * (StepSize + 1))];
var factors = new double[] { 0.0, 0.0, 0.0 };
for (int i = 0; i < ac.Atoms.Count; i++)
{
factors[0] = 0.0;
factors[1] = 0.0;
factors[2] = 0.0;
var atom = ac.Atoms[i];
var symbol = atom.Symbol;
var maxBondOrder = ac.GetMaximumBondOrder(atom);
var charge = atom.FormalCharge;
switch (atom.AtomicNumber)
{
case AtomicNumbers.H:
factors[0] = 7.17;
factors[1] = 6.24;
factors[2] = -0.56;
break;
case AtomicNumbers.C:
if (maxBondOrder == BondOrder.Double ||
(maxBondOrder == BondOrder.Single && (charge == -1 || charge == +1)))
{
factors[0] = 8.79; /* 8.79 *//* 8.81 */
factors[1] = 9.32; /* 9.32 *//* 9.34 */
factors[2] = 1.51; /* 1.51 *//* 1.52 */
}
else if (maxBondOrder == BondOrder.Single && charge == 0)
{
factors[0] = 7.98;
factors[1] = 9.18;
factors[2] = 1.88;
}
else if (maxBondOrder == BondOrder.Triple ||
maxBondOrder == BondOrder.Quadruple)
{
factors[0] = 10.39; /* 10.39 */
factors[1] = 9.45; /* 9.45 */
factors[2] = 0.73;
}
break;
case AtomicNumbers.N:
if ((maxBondOrder == BondOrder.Single) &&
(charge != -1))
{
factors[0] = 11.54;
factors[1] = 10.82;
factors[2] = 1.36;
}
else if ((maxBondOrder == BondOrder.Double) ||
(maxBondOrder == BondOrder.Single))
{
factors[0] = 12.87;
factors[1] = 11.15;
factors[2] = 0.85;
}
else if (maxBondOrder == BondOrder.Triple ||
maxBondOrder == BondOrder.Quadruple)
{
factors[0] = 17.68; /* 15.68 */
factors[1] = 12.70; /* 11.70 */
factors[2] = -0.27; /*-0.27*/
}
break;
case AtomicNumbers.O:
if ((maxBondOrder == BondOrder.Single) &&
(charge != -1))
{
factors[0] = 14.18;
factors[1] = 12.92;
factors[2] = 1.39;
}
else if ((maxBondOrder == BondOrder.Double) ||
(maxBondOrder == BondOrder.Single))
{
factors[0] = 17.07; /* paramaters aren'T correct parametrized. */
factors[1] = 13.79;
factors[2] = 0.47; /* 0.47 */
}
break;
case AtomicNumbers.Si: // <--not correct
factors[0] = 8.10; // <--not correct
factors[1] = 7.92; // <--not correct
factors[2] = 1.78; // <--not correct
break;
case AtomicNumbers.P:
factors[0] = 8.90;
factors[1] = 8.32;
factors[2] = 1.58;
break;
case AtomicNumbers.S:
factors[0] = 10.14; /* 10.14 */
factors[1] = 9.13; /* 9.13 */
factors[2] = 1.38; /* 1.38 */
break;
case AtomicNumbers.F:
factors[0] = 14.66;
factors[1] = 13.85;
factors[2] = 2.31;
break;
case AtomicNumbers.Cl:
factors[0] = 12.31; /* 11.0 *//* 12.31 */
factors[1] = 10.84; /* 9.69 *//* 10.84 */
factors[2] = 1.512; /* 1.35 *//* 1.512 */
break;
case AtomicNumbers.Br:
factors[0] = 11.44; /* 10.08 *//* 11.2 */
factors[1] = 9.63; /* 8.47 *//* 9.4 */
factors[2] = 1.31; /* 1.16 *//* 1.29 */
break;
case AtomicNumbers.I:
factors[0] = 9.88; /* 9.90 */
factors[1] = 7.95; /* 7.96 */
factors[2] = 0.945; /* 0.96 */
break;
default:
throw new CDKException($"Partial charge not-supported for element: '{symbol}'.");
}
gasteigerFactors[StepSize * i + i] = factors[0];
gasteigerFactors[StepSize * i + i + 1] = factors[1];
gasteigerFactors[StepSize * i + i + 2] = factors[2];
gasteigerFactors[StepSize * i + i + 5] = atom.Charge.Value;
if (factors[0] == 0 && factors[1] == 0 && factors[2] == 0)
{
gasteigerFactors[StepSize * i + i + 3] = 1;
}
else
{
gasteigerFactors[StepSize * i + i + 3] = factors[0] + factors[1] + factors[2];
}
}
return(gasteigerFactors);
}
/// <summary>
/// The method calculates the number of rotatable bonds of an atom container.
/// If the boolean parameter is set to <see langword="true"/>, terminal bonds are included.
/// </summary>
/// <returns>number of rotatable bonds</returns>
/// <param name="includeTerminals"><see langword="true"/> if terminal bonds are included</param>
/// <param name="excludeAmides"><see langword="true"/> if amide C-N bonds should be excluded</param>
public Result Calculate(IAtomContainer container, bool includeTerminals = false, bool excludeAmides = false)
{
container = (IAtomContainer)container.Clone();
IRingSet ringSet;
try
{
ringSet = new SpanningTree(container).GetBasicRings();
}
catch (NoSuchAtomException)
{
return(new Result(0));
}
foreach (var bond in container.Bonds)
{
if (ringSet.GetRings(bond).Count() > 0)
{
bond.IsInRing = true;
}
}
int rotatableBondsCount = 0;
foreach (var bond in container.Bonds)
{
var atom0 = bond.Atoms[0];
var atom1 = bond.Atoms[1];
if (atom0.AtomicNumber.Equals(AtomicNumbers.H) || atom1.AtomicNumber.Equals(AtomicNumbers.H))
{
continue;
}
if (bond.Order == BondOrder.Single)
{
if (BondManipulator.IsLowerOrder(container.GetMaximumBondOrder(atom0), BondOrder.Triple) &&
BondManipulator.IsLowerOrder(container.GetMaximumBondOrder(atom1), BondOrder.Triple))
{
if (!bond.IsInRing)
{
if (excludeAmides && (IsAmide(atom0, atom1, container) || IsAmide(atom1, atom0, container)))
{
continue;
}
// if there are explicit H's we should ignore those bonds
var degree0 = container.GetConnectedBonds(atom0).Count() - GetConnectedHCount(container, atom0);
var degree1 = container.GetConnectedBonds(atom1).Count() - GetConnectedHCount(container, atom1);
if ((degree0 == 1) || (degree1 == 1))
{
if (includeTerminals)
{
rotatableBondsCount += 1;
}
}
else
{
rotatableBondsCount += 1;
}
}
}
}
}
return(new Result(rotatableBondsCount));
}
/// <summary>
/// Gets the atomicSoftnessCore attribute of the InductivePartialCharges object.
/// </summary>
/// <remarks>
/// this method returns the result of the core of the equation of atomic softness
/// that can be used for qsar descriptors and during the iterative calculation
/// of effective electronegativity
/// </remarks>
/// <param name="ac">AtomContainer</param>
/// <param name="atomPosition">position of target atom</param>
/// <returns>The atomicSoftnessCore value</returns>
/// <exception cref="CDKException"></exception>
public double GetAtomicSoftnessCore(IAtomContainer ac, int atomPosition)
{
IAtom target = null;
double core = 0;
double radiusTarget = 0;
target = ac.Atoms[atomPosition];
double partial = 0;
double radius = 0;
IAtomType type = null;
try
{
type = factory.GetAtomType(ac.Atoms[atomPosition].Symbol);
var n = ac.Atoms[atomPosition].AtomicNumber;
if (GetCovalentRadius(n, ac.GetMaximumBondOrder(target)) > 0)
{
radiusTarget = GetCovalentRadius(n, ac.GetMaximumBondOrder(target));
}
else
{
radiusTarget = type.CovalentRadius.Value;
}
}
catch (Exception ex1)
{
Debug.WriteLine(ex1);
throw new CDKException("Problems with AtomTypeFactory due to " + ex1.Message, ex1);
}
foreach (var atom in ac.Atoms)
{
if (!target.Equals(atom))
{
partial = 0;
try
{
type = factory.GetAtomType(atom.Symbol);
}
catch (Exception ex1)
{
Debug.WriteLine(ex1);
throw new CDKException($"Problems with AtomTypeFactory due to {ex1.Message}", ex1);
}
if (GetCovalentRadius(atom.AtomicNumber, ac.GetMaximumBondOrder(atom)) > 0)
{
radius = GetCovalentRadius(atom.AtomicNumber, ac.GetMaximumBondOrder(atom));
}
else
{
radius = type.CovalentRadius.Value;
}
partial += radius * radius;
partial += (radiusTarget * radiusTarget);
partial = partial / (CalculateSquaredDistanceBetweenTwoAtoms(target, atom));
core += partial;
}
}
core = 2 * core;
core = 0.172 * core;
return(core);
}
public int CalculateNumberOfImplicitHydrogens(IAtom atom, IAtomContainer container)
{
return(this.CalculateNumberOfImplicitHydrogens(atom, container.GetBondOrderSum(atom), container.GetMaximumBondOrder(atom), container.GetConnectedBonds(atom).Count()));
}
// this method returns the partial charge increment for a given atom
/// <summary>
/// Gets the atomicChargeIncrement attribute of the InductivePartialCharges object.
/// </summary>
/// <param name="ac">AtomContainer</param>
/// <param name="atomPosition">position of target atom</param>
/// <param name="ElEn">electronegativity of target atom</param>
/// <param name="step">step in iteration</param>
/// <returns>The atomic charge increment for the target atom</returns>
/// <exception cref="CDKException"></exception>
private double GetAtomicChargeIncrement(IAtomContainer ac, int atomPosition, double[] ElEn, int step)
{
IAtom[] allAtoms = null;
IAtom target = null;
double incrementedCharge = 0;
double radiusTarget = 0;
target = ac.Atoms[atomPosition];
allAtoms = ac.Atoms.ToArray();
double tmp = 0;
double radius = 0;
IAtomType type = null;
try
{
type = factory.GetAtomType(target.Symbol);
if (GetCovalentRadius(target.AtomicNumber, ac.GetMaximumBondOrder(target)) > 0)
{
radiusTarget = GetCovalentRadius(target.AtomicNumber, ac.GetMaximumBondOrder(target));
}
else
{
radiusTarget = type.CovalentRadius.Value;
}
}
catch (Exception ex1)
{
Debug.WriteLine(ex1);
throw new CDKException($"Problems with AtomTypeFactory due to {ex1.Message}", ex1);
}
for (int a = 0; a < allAtoms.Length; a++)
{
if (!target.Equals(allAtoms[a]))
{
tmp = 0;
var atom = allAtoms[a];
try
{
type = factory.GetAtomType(atom.Symbol);
}
catch (Exception ex1)
{
Debug.WriteLine(ex1);
throw new CDKException("Problems with AtomTypeFactory due to " + ex1.Message, ex1);
}
if (GetCovalentRadius(atom.AtomicNumber, ac.GetMaximumBondOrder(allAtoms[a])) > 0)
{
radius = GetCovalentRadius(atom.AtomicNumber, ac.GetMaximumBondOrder(allAtoms[a]));
}
else
{
radius = type.CovalentRadius.Value;
}
tmp = (ElEn[a + ((step - 1) * allAtoms.Length)] - ElEn[atomPosition + ((step - 1) * allAtoms.Length)]);
tmp = tmp * ((radius * radius) + (radiusTarget * radiusTarget));
tmp = tmp / (CalculateSquaredDistanceBetweenTwoAtoms(target, allAtoms[a]));
incrementedCharge += tmp;
}
}
incrementedCharge = 0.172 * incrementedCharge;
return(incrementedCharge);
}
/// <summary>
/// Sets a branch atom to a ring or aliphatic chain.
/// </summary>
/// <param name="unplacedAtom">The new branchAtom</param>
/// <param name="atomA">placed atom to which the unplaced atom is connected</param>
/// <param name="atomNeighbours">placed atomNeighbours of atomA</param>
private static void SetBranchAtom(IAtomContainer molecule, IAtom unplacedAtom, IAtom atomA, IAtomContainer atomNeighbours,
AtomPlacer3D ap3d, AtomTetrahedralLigandPlacer3D atlp3d)
{
//Debug.WriteLine("****** SET Branch Atom ****** >"+molecule.Atoms.IndexOf(unplacedAtom));
IAtomContainer noCoords = molecule.Builder.NewAtomContainer();
noCoords.Atoms.Add(unplacedAtom);
Vector3 centerPlacedMolecule = ap3d.GeometricCenterAllPlacedAtoms(molecule);
IAtom atomB = atomNeighbours.Atoms[0];
string atypeNameA = atomA.AtomTypeName;
string atypeNameB = atomB.AtomTypeName;
string atypeNameUnplaced = unplacedAtom.AtomTypeName;
double length = ap3d.GetBondLengthValue(atypeNameA, atypeNameUnplaced);
double angle = (ap3d.GetAngleValue(atypeNameB, atypeNameA, atypeNameUnplaced)) * Math.PI / 180;
// Console.Out.WriteLine("A:"+atomA.Symbol+" "+atomA.AtomTypeName+
// " B:"+atomB.Symbol+" "+atomB.AtomTypeName
// +" unplaced Atom:"
// +unplacedAtom.AtomTypeName+" BL:"+length+" Angle:"+angle
// +" FormalNeighbour:"
// +atomA.FormalNeighbourCount+" HYB:"+atomA.getFlag
// (CDKConstants.HYBRIDIZATION_SP2)
// +" #Neigbhours:"+atomNeighbours.Atoms.Count);
IAtom atomC = ap3d.GetPlacedHeavyAtom(molecule, atomB, atomA);
Vector3[] branchPoints = atlp3d.Get3DCoordinatesForLigands(atomA, noCoords, atomNeighbours, atomC,
(atomA.FormalNeighbourCount.Value - atomNeighbours.Atoms.Count), length, angle);
double distance = 0;
int farthestPoint = 0;
for (int i = 0; i < branchPoints.Length; i++)
{
if (Math.Abs(Vector3.Distance(branchPoints[i], centerPlacedMolecule)) > Math.Abs(distance))
{
distance = Vector3.Distance(branchPoints[i], centerPlacedMolecule);
farthestPoint = i;
}
}
int stereo = -1;
IBond unplacedBond = molecule.GetBond(atomA, unplacedAtom);
if (atomA.StereoParity != 0 ||
(unplacedBond.Stereo == BondStereo.Up || unplacedBond.Stereo == BondStereo.Down) &&
molecule.GetMaximumBondOrder(atomA) == BondOrder.Single)
{
if (atomNeighbours.Atoms.Count > 1)
{
stereo = AtomTetrahedralLigandPlacer3D.MakeStereocenter(atomA.Point3D.Value, molecule.GetBond(atomA, unplacedAtom),
(atomNeighbours.Atoms[0]).Point3D.Value, (atomNeighbours.Atoms[1]).Point3D.Value,
branchPoints);
}
}
if (stereo != -1)
{
farthestPoint = stereo;
}
unplacedAtom.Point3D = branchPoints[farthestPoint];
unplacedAtom.IsPlaced = true;
}
/// <summary>
/// Method which assigns the polarizabilitiyFactors.
/// </summary>
/// <param name="atomContainer">AtomContainer</param>
/// <param name="atom">Atom</param>
/// <returns>double polarizabilitiyFactor</returns>
private static double GetKJPolarizabilityFactor(IAtomContainer atomContainer, IAtom atom)
{
double polarizabilitiyFactor = 0;
switch (atom.AtomicNumber)
{
case AtomicNumbers.H:
polarizabilitiyFactor = 0.387;
break;
case AtomicNumbers.C:
if (atom.IsAromatic)
{
polarizabilitiyFactor = 1.230;
}
else if (atomContainer.GetMaximumBondOrder(atom) == BondOrder.Single)
{
polarizabilitiyFactor = 1.064; /* 1.064 */
}
else if (atomContainer.GetMaximumBondOrder(atom) == BondOrder.Double)
{
if (GetNumberOfHydrogen(atomContainer, atom) == 0)
{
polarizabilitiyFactor = 1.382;
}
else
{
polarizabilitiyFactor = 1.37;
}
}
else if (atomContainer.GetMaximumBondOrder(atom) == BondOrder.Triple ||
atomContainer.GetMaximumBondOrder(atom) == BondOrder.Quadruple)
{
polarizabilitiyFactor = 1.279;
}
break;
case AtomicNumbers.N:
if (atom.Charge != null && atom.Charge < 0)
{
polarizabilitiyFactor = 1.090;
}
else if (atomContainer.GetMaximumBondOrder(atom) == BondOrder.Single)
{
polarizabilitiyFactor = 1.094;
}
else if (atomContainer.GetMaximumBondOrder(atom) == BondOrder.Double)
{
polarizabilitiyFactor = 1.030;
}
else
{
polarizabilitiyFactor = 0.852;
}
break;
case AtomicNumbers.O:
if (atom.Charge != null && atom.Charge == -1)
{
polarizabilitiyFactor = 1.791;
}
else if (atom.Charge != null && atom.Charge == 1)
{
polarizabilitiyFactor = 0.422;
}
else if (atomContainer.GetMaximumBondOrder(atom) == BondOrder.Single)
{
polarizabilitiyFactor = 0.664;
}
else if (atomContainer.GetMaximumBondOrder(atom) == BondOrder.Double)
{
polarizabilitiyFactor = 0.460;
}
break;
case AtomicNumbers.P:
if (atomContainer.GetConnectedBonds(atom).Count() == 4 &&
atomContainer.GetMaximumBondOrder(atom) == BondOrder.Double)
{
polarizabilitiyFactor = 0;
}
break;
case AtomicNumbers.S:
if (atom.IsAromatic)
{
polarizabilitiyFactor = 3.38;
}
else if (atomContainer.GetMaximumBondOrder(atom) == BondOrder.Single)
{
polarizabilitiyFactor = 3.20; /* 3.19 */
}
else if (atomContainer.GetMaximumBondOrder(atom) == BondOrder.Double)
{
if (GetNumberOfHydrogen(atomContainer, atom) == 0)
{
polarizabilitiyFactor = 3.51;
}
else
{
polarizabilitiyFactor = 3.50;
}
}
else
{
polarizabilitiyFactor = 3.42;
}
break;
case AtomicNumbers.F:
polarizabilitiyFactor = 0.296;
break;
case AtomicNumbers.Cl:
polarizabilitiyFactor = 2.343;
break;
case AtomicNumbers.Br:
polarizabilitiyFactor = 3.5;
break;
case AtomicNumbers.I:
polarizabilitiyFactor = 5.79;
break;
}
return(polarizabilitiyFactor);
}
/// <summary>
/// Gets the paulingElectronegativities attribute of the
/// InductivePartialCharges object.
/// </summary>
/// <param name="ac">AtomContainer</param>
/// <param name="modified">if true, some values are modified by following the reference</param>
/// <returns>The pauling electronegativities</returns>
public double[] GetPaulingElectronegativities(IAtomContainer ac, bool modified)
{
var paulingElectronegativities = new double[ac.Atoms.Count];
string symbol = null;
int atomicNumber = 0;
try
{
ifac = CDK.IsotopeFactory;
for (int i = 0; i < ac.Atoms.Count; i++)
{
var atom = ac.Atoms[i];
symbol = ac.Atoms[i].Symbol;
var element = ifac.GetElement(symbol);
atomicNumber = element.AtomicNumber;
if (modified)
{
switch (atom.AtomicNumber)
{
case AtomicNumbers.Cl:
paulingElectronegativities[i] = 3.28;
break;
case AtomicNumbers.Br:
paulingElectronegativities[i] = 3.13;
break;
case AtomicNumbers.I:
paulingElectronegativities[i] = 2.93;
break;
case AtomicNumbers.H:
paulingElectronegativities[i] = 2.10;
break;
case AtomicNumbers.C:
if (ac.GetMaximumBondOrder(atom) == BondOrder.Single)
{
// Csp3
paulingElectronegativities[i] = 2.20;
}
else if (ac.GetMaximumBondOrder(atom) == BondOrder.Double)
{
paulingElectronegativities[i] = 2.31;
}
else
{
paulingElectronegativities[i] = 3.15;
}
break;
case AtomicNumbers.O:
if (ac.GetMaximumBondOrder(atom) == BondOrder.Single)
{
// Osp3
paulingElectronegativities[i] = 3.20;
}
else if (ac.GetMaximumBondOrder(atom) != BondOrder.Single)
{
paulingElectronegativities[i] = 4.34;
}
break;
case AtomicNumbers.Si:
paulingElectronegativities[i] = 1.99;
break;
case AtomicNumbers.S:
paulingElectronegativities[i] = 2.74;
break;
case AtomicNumbers.N:
paulingElectronegativities[i] = 2.59;
break;
default:
paulingElectronegativities[i] = pauling[atomicNumber];
break;
}
}
else
{
paulingElectronegativities[i] = pauling[atomicNumber];
}
}
return(paulingElectronegativities);
}
catch (Exception ex1)
{
Debug.WriteLine(ex1);
throw new CDKException($"Problems with IsotopeFactory due to {ex1.Message}", ex1);
}
}
/// <summary>
/// Method which stores and assigns the factors a,b,c and CHI+.
/// </summary>
/// <param name="setAc"></param>
/// <returns>Array of doubles [a1,b1,c1,denom1,chi1,q1...an,bn,cn...] 1:Atom 1-n in AtomContainer</returns>
public double[][] AssignrPiMarsilliFactors(IChemObjectSet <IAtomContainer> setAc)
{
//a,b,c,denom,chi,q
double[][] gasteigerFactors = Arrays.CreateJagged <double>(setAc.Count, (setAc[0].Atoms.Count * (StepSize + 1)));
double[] factors = new double[] { 0.0, 0.0, 0.0 };
for (int k = 1; k < setAc.Count; k++)
{
IAtomContainer ac = setAc[k];
for (int i = 0; i < ac.Atoms.Count; i++)
{
factors[0] = 0.0;
factors[1] = 0.0;
factors[2] = 0.0;
switch (ac.Atoms[i].AtomicNumber)
{
case AtomicNumbers.H:
factors[0] = 0.0;
factors[1] = 0.0;
factors[2] = 0.0;
break;
case AtomicNumbers.C:
factors[0] = 5.98; /* 5.98-5.60 */
factors[1] = 7.93; /* 7.93-8.93 */
factors[2] = 1.94;
break;
case AtomicNumbers.O:
if (ac.GetMaximumBondOrder(ac.Atoms[i]) != BondOrder.Single)
{
factors[0] = 11.2; /* 11.2-10.0 */
factors[1] = 13.24; /* 13.24-13.86 */
factors[2] = 9.68;
}
else
{
factors[0] = 7.91;
factors[1] = 14.76;
factors[2] = 6.85;
}
break;
case AtomicNumbers.N:
if (ac.GetMaximumBondOrder(ac.Atoms[i]) != BondOrder.Single)
{
factors[0] = 8.95; /* 7.95 */
factors[1] = 9.73; /* 9.73 */
factors[2] = 2.67; /* 2.67 */
}
else
{
factors[0] = 4.54;
factors[1] = 11.86;
factors[2] = 7.32;
}
break;
case AtomicNumbers.P:
{ // <--No correct
if (ac.GetMaximumBondOrder(ac.Atoms[i]) != BondOrder.Single)
{
factors[0] = 10.73; // <--No correct
factors[1] = 11.16; // <--No correct
factors[2] = 6.81; // <--No correct
}
else
{
factors[0] = 9.60; // <--No correct
factors[1] = 13.32; // <--No correct
factors[2] = 2.72; // <--No correct
}
}
break;
case AtomicNumbers.S:
if (ac.GetMaximumBondOrder(ac.Atoms[i]) != BondOrder.Single)
{
factors[0] = 7.73;
factors[1] = 8.16;
factors[2] = 1.81;
}
else
{
factors[0] = 6.60;
factors[1] = 10.32;
factors[2] = 3.72;
}
break;
case AtomicNumbers.F:
factors[0] = 7.14 /* 7.34 */;
factors[1] = 13.86;
factors[2] = 5.68;
break;
case AtomicNumbers.Cl:
factors[0] = 6.51; /* 6.50 */
factors[1] = 11.02;
factors[2] = 4.52;
break;
case AtomicNumbers.Br:
factors[0] = 5.20;
factors[1] = 9.68;
factors[2] = 4.48;
break;
case AtomicNumbers.I:
factors[0] = 4.95;
factors[1] = 8.81;
factors[2] = 3.86;
break;
}
gasteigerFactors[k][StepSize * i + i] = factors[0];
gasteigerFactors[k][StepSize * i + i + 1] = factors[1];
gasteigerFactors[k][StepSize * i + i + 2] = factors[2];
gasteigerFactors[k][StepSize * i + i + 5] = ac.Atoms[i].Charge.Value;
if (factors[0] == 0 && factors[1] == 0 && factors[2] == 0)
{
gasteigerFactors[k][StepSize * i + i + 3] = 1;
}
else
{
gasteigerFactors[k][StepSize * i + i + 3] = factors[0] + factors[1] + factors[2];
}
}
}
return(gasteigerFactors);
}
/// <summary>
/// Method assigns atom types to atoms (calculates sssr and aromaticity)
/// </summary>
/// <returns>sssrf set</returns>
/// <exception cref="CDKException"> Problems detecting aromaticity or making hose codes.</exception>
public IRingSet AssignAtomTyps(IAtomContainer molecule)
{
IAtom atom = null;
string hoseCode = "";
HOSECodeGenerator hcg = new HOSECodeGenerator();
int NumberOfRingAtoms = 0;
IRingSet ringSetMolecule = Cycles.FindSSSR(molecule).ToRingSet();
bool isInHeteroRing = false;
try
{
AtomContainerManipulator.PercieveAtomTypesAndConfigureAtoms(molecule);
Aromaticity.CDKLegacy.Apply(molecule);
}
catch (Exception cdk1)
{
throw new CDKException("AROMATICITYError: Cannot determine aromaticity due to: " + cdk1.Message, cdk1);
}
for (int i = 0; i < molecule.Atoms.Count; i++)
{
atom = molecule.Atoms[i];
if (ringSetMolecule.Contains(atom))
{
NumberOfRingAtoms = NumberOfRingAtoms + 1;
atom.IsInRing = true;
atom.IsAliphatic = false;
var ringSetA = ringSetMolecule.GetRings(atom).ToList();
RingSetManipulator.Sort(ringSetA);
IRing sring = (IRing)ringSetA[ringSetA.Count - 1];
atom.SetProperty("RING_SIZE", sring.RingSize);
foreach (var ring in ringSetA)
{
if (IsHeteroRingSystem(ring))
{
break;
}
}
}
else
{
atom.IsAliphatic = true;
atom.IsInRing = false;
isInHeteroRing = false;
}
atom.SetProperty("MAX_BOND_ORDER", molecule.GetMaximumBondOrder(atom).Numeric());
try
{
hoseCode = hcg.GetHOSECode(molecule, atom, 3);
//Debug.WriteLine("HOSECODE GENERATION: ATOM "+i+" HoseCode: "+hoseCode+" ");
}
catch (CDKException ex1)
{
Console.Out.WriteLine("Could not build HOSECode from atom " + i + " due to " + ex1.ToString());
throw new CDKException("Could not build HOSECode from atom " + i + " due to " + ex1.ToString(), ex1);
}
try
{
ConfigureAtom(atom, hoseCode, isInHeteroRing);
}
catch (CDKException ex2)
{
Console.Out.WriteLine("Could not final configure atom " + i + " due to " + ex2.ToString());
throw new CDKException("Could not final configure atom due to problems with force field", ex2);
}
}
// IBond[] bond = molecule.Bonds;
string bondType;
foreach (var bond in molecule.Bonds)
{
//Debug.WriteLine("bond[" + i + "] properties : " + molecule.Bonds[i].GetProperties());
bondType = "0";
if (bond.Order == BondOrder.Single)
{
if ((bond.Begin.AtomTypeName.Equals("Csp2", StringComparison.Ordinal)) &&
((bond.End.AtomTypeName.Equals("Csp2", StringComparison.Ordinal)) ||
(bond.End.AtomTypeName.Equals("C=", StringComparison.Ordinal))))
{
bondType = "1";
}
if ((bond.Begin.AtomTypeName.Equals("C=", StringComparison.Ordinal)) &&
((bond.End.AtomTypeName.Equals("Csp2", StringComparison.Ordinal)) ||
(bond.End.AtomTypeName.Equals("C=", StringComparison.Ordinal))))
{
bondType = "1";
}
if ((bond.Begin.AtomTypeName.Equals("Csp", StringComparison.Ordinal)) &&
(bond.End.AtomTypeName.Equals("Csp", StringComparison.Ordinal)))
{
bondType = "1";
}
}
// molecule.Bonds[i].SetProperty("MMFF94 bond type", bondType);
bond.SetProperty("MMFF94 bond type", bondType);
//Debug.WriteLine("bond[" + i + "] properties : " + molecule.Bonds[i].GetProperties());
}
return(ringSetMolecule);
}
internal IReactionSet Initiate(IChemObjectSet <IAtomContainer> reactants, IChemObjectSet <IAtomContainer> agents, int length, bool checkPrev, AtomCheck atomCheck)
{
CheckInitiateParams(reactants, agents);
IReactionSet setOfReactions = reactants.Builder.NewReactionSet();
IAtomContainer reactant = reactants[0];
AtomContainerManipulator.PercieveAtomTypesAndConfigureAtoms(reactant);
Aromaticity.CDKLegacy.Apply(reactant);
AllRingsFinder arf = new AllRingsFinder();
IRingSet ringSet = arf.FindAllRings(reactant);
for (int ir = 0; ir < ringSet.Count; ir++)
{
IRing ring = (IRing)ringSet[ir];
for (int jr = 0; jr < ring.Atoms.Count; jr++)
{
IAtom aring = ring.Atoms[jr];
aring.IsInRing = true;
}
}
// if the parameter hasActiveCenter is not fixed yet, set the active centers
IParameterReaction ipr = base.GetParameterClass(typeof(SetReactionCenter));
if (ipr != null && !ipr.IsSetParameter)
{
SetActiveCenters(reactant, length, checkPrev, atomCheck);
}
HOSECodeGenerator hcg = new HOSECodeGenerator();
foreach (var atomi in reactant.Atoms)
{
if (atomi.IsReactiveCenter && reactant.GetConnectedSingleElectrons(atomi).Count() == 1)
{
IEnumerable <IAtom> atom1s = null;
if (checkPrev)
{
hcg.GetSpheres(reactant, atomi, length - 1, true);
atom1s = hcg.GetNodesInSphere(length - 1);
}
hcg.GetSpheres(reactant, atomi, length, true);
foreach (var atoml in hcg.GetNodesInSphere(length))
{
if (atoml != null &&
atoml.IsReactiveCenter &&
!atoml.IsInRing &&
(atoml.FormalCharge ?? 0) == 0 &&
!atoml.AtomicNumber.Equals(AtomicNumbers.H) &&
reactant.GetMaximumBondOrder(atoml) == BondOrder.Single)
{
foreach (var atomR in reactant.GetConnectedAtoms(atoml))
{
if (atom1s != null && atom1s.Contains(atomR))
{
continue;
}
if (reactant.GetBond(atomR, atoml).IsReactiveCenter &&
atomR.IsReactiveCenter &&
atomCheck(atomR))
{
var atomList = new List <IAtom>
{
atomR,
atomi,
atoml
};
var bondList = new List <IBond>
{
reactant.GetBond(atomR, atoml)
};
var moleculeSet = reactant.Builder.NewChemObjectSet <IAtomContainer>();
moleculeSet.Add(reactant);
var reaction = Mechanism.Initiate(moleculeSet, atomList, bondList);
if (reaction == null)
{
continue;
}
else
{
setOfReactions.Add(reaction);
}
}
}
}
}
}
}
return(setOfReactions);
}
/// <summary>
/// Check an Atom whether it may be conjugated or not.
/// </summary>
/// <param name="ac">The AtomContainer containing currentAtom</param>
/// <param name="currentAtom">The Atom to check</param>
/// <returns>-1 if isolated, 0 if conjugated, 1 if cumulative db</returns>
private static int CheckAtom(IAtomContainer ac, IAtom currentAtom)
{
int check = -1;
var atoms = ac.GetConnectedAtoms(currentAtom).ToReadOnlyList();
var bonds = ac.GetConnectedBonds(currentAtom).ToReadOnlyList();
if (currentAtom.IsAromatic)
{
check = 0;
}
else if (currentAtom.FormalCharge == 1)
/* && currentAtom.Symbol.Equals("C") */
{
check = 0;
}
else if (currentAtom.FormalCharge == -1)
{
//// NEGATIVE CHARGES WITH A NEIGHBOOR PI BOND ////
int counterOfPi = 0;
foreach (var atom in atoms)
{
if (ac.GetMaximumBondOrder(atom) != BondOrder.Single)
{
counterOfPi++;
}
}
if (counterOfPi > 0)
{
check = 0;
}
}
else
{
int se = ac.GetConnectedSingleElectrons(currentAtom).Count();
if (se == 1)
{
check = 0; //// DETECTION of radicals
}
else if (ac.GetConnectedLonePairs(currentAtom).Any()
/* && (currentAtom.Symbol.Equals("N") */)
{
check = 0; //// DETECTION of lone pair
}
else
{
int highOrderBondCount = 0;
for (int j = 0; j < atoms.Count; j++)
{
var bond = bonds[j];
if (bond == null || bond.Order != BondOrder.Single)
{
highOrderBondCount++;
}
else
{
}
}
if (highOrderBondCount == 1)
{
check = 0;
}
else if (highOrderBondCount > 1)
{
check = 1;
}
}
}
return(check);
}
