Exemplo n.º 1
0
def convert_dict_to_mols(tot_dict):
    """
    :param tot_dict:
    :return:
    """
    mol_list = []
    for smiles in tot_dict:
        # Now generate the molecules for that
        mol = RWMol()
        atoms = tot_dict[smiles]
        print(atoms)
        for atom in atoms:
            atom = Atom(6)
            mol.AddAtom(atom)
        # for i in range(len(atoms)-1):
        #     mol.AddBond(i,i+1)
        mol = mol.GetMol()
        AllChem.EmbedMolecule(mol)
        conf = mol.GetConformer()
        for i, atom in enumerate(atoms):
            point_3d = Point3D(atom[0], atom[1], atom[2])
            conf.SetAtomPosition(i, point_3d)
        mol = conf.GetOwningMol()
        mol.SetProp("_Name", smiles)
        mol_list.append(mol)
    return mol_list
Exemplo n.º 2
0
 def _place_between(self, mol: Chem.RWMol, a: int, b: int, aromatic=True):
     oribond = mol.GetBondBetweenAtoms(a, b)
     if oribond is None:
         print('FAIL')
         return None  # fail
     elif aromatic:
         bt = Chem.BondType.AROMATIC
     else:
         bt = oribond.GetBondType()
     idx = mol.AddAtom(Chem.Atom(6))
     neoatom = mol.GetAtomWithIdx(idx)
     atom_a = mol.GetAtomWithIdx(a)
     atom_b = mol.GetAtomWithIdx(b)
     if aromatic:
         neoatom.SetIsAromatic(True)
         atom_a.SetIsAromatic(True)
         atom_b.SetIsAromatic(True)
     # prevent constraints
     neoatom.SetBoolProp('_Novel', True)
     atom_a.SetBoolProp('_Novel', True)
     atom_b.SetBoolProp('_Novel', True)
     # fix position
     conf = mol.GetConformer()
     pos_A = conf.GetAtomPosition(a)
     pos_B = conf.GetAtomPosition(b)
     x = pos_A.x / 2 + pos_B.x / 2
     y = pos_A.y / 2 + pos_B.y / 2
     z = pos_A.z / 2 + pos_B.z / 2
     conf.SetAtomPosition(idx, Point3D(x, y, z))
     # fix bonds
     mol.RemoveBond(a, b)
     mol.AddBond(a, idx, bt)
     mol.AddBond(b, idx, bt)
Exemplo n.º 3
0
    def _join_atoms(self,
                    combo: Chem.RWMol,
                    anchor_A: int,
                    anchor_B: int,
                    distance: float,
                    linking: bool = True):
        """
        extrapolate positions between. by adding linkers if needed.
        """
        conf = combo.GetConformer()
        pos_A = conf.GetAtomPosition(anchor_A)
        pos_B = conf.GetAtomPosition(anchor_B)
        n_new = int(round(distance / 1.22) - 1)
        xs = np.linspace(pos_A.x, pos_B.x, n_new + 2)[1:-1]
        ys = np.linspace(pos_A.y, pos_B.y, n_new + 2)[1:-1]
        zs = np.linspace(pos_A.z, pos_B.z, n_new + 2)[1:-1]

        # correcting for ring marker atoms
        def is_ring_atom(anchor: int) -> bool:
            atom = combo.GetAtomWithIdx(anchor)
            if atom.HasProp('_ori_i') and atom.GetIntProp('_ori_i') == -1:
                return True
            else:
                return False

        if is_ring_atom(anchor_A):
            distance -= 1.35 + 0.2  # Arbitrary + 0.2 to compensate for the ring not reaching (out of plane).
            n_new -= 1
            xs = xs[1:]
            ys = ys[1:]
            zs = zs[1:]

        if is_ring_atom(anchor_B):
            distance -= 1.35 + 0.2  # Arbitrary + 0.2 to compensate for the ring not reaching  (out of plane).
            n_new -= 1
            xs = xs[:-1]
            ys = ys[:-1]
            zs = zs[:-1]

        # notify that things could be leary.
        if distance < 0:
            self.journal.debug(
                f'Two ring atoms detected to be close. Joining for now.' +
                ' They will be bonded/fused/spiro afterwards')
        # check if valid.
        if distance > self.joining_cutoff:
            msg = f'Atoms {anchor_A}+{anchor_B} are {distance} Å away. Cutoff is {self.joining_cutoff}.'
            self.journal.warning(msg)
            raise ConnectionError(msg)
        # place new atoms
        self.journal.debug(
            f'Molecules will be joined via atoms {anchor_A}+{anchor_B} ({distance} Å) via the addition of {n_new} atoms.'
        )
        previous = anchor_A
        if linking is False and n_new > 0:
            self.journal.warning(
                f'Was going to bond {anchor_A} and {anchor_B} but reconsidered.'
            )
        elif linking is True and n_new <= 0:
            combo.AddBond(previous, anchor_B, Chem.BondType.SINGLE)
            new_bond = combo.GetBondBetweenAtoms(previous, anchor_B)
            BondProvenance.set_bond(new_bond, 'main_novel')
        elif linking is False and n_new <= 0:
            combo.AddBond(previous, anchor_B, Chem.BondType.SINGLE)
            new_bond = combo.GetBondBetweenAtoms(previous, anchor_B)
            BondProvenance.set_bond(new_bond, 'other_novel')
        elif linking is True and n_new > 0:
            for i in range(n_new):
                # make oxygen the first and last bridging atom.
                if i == 0 and combo.GetAtomWithIdx(
                        anchor_A).GetSymbol() == 'C':
                    new_atomic = 8
                elif i > 2 and i == n_new - 1 and combo.GetAtomWithIdx(
                        anchor_B).GetSymbol() == 'C':
                    new_atomic = 8
                else:
                    new_atomic = 6
                idx = combo.AddAtom(Chem.Atom(new_atomic))
                new = combo.GetAtomWithIdx(idx)
                new.SetBoolProp('_Novel', True)
                new.SetIntProp('_ori_i', 999)
                conf.SetAtomPosition(
                    idx, Point3D(float(xs[i]), float(ys[i]), float(zs[i])))
                combo.AddBond(idx, previous, Chem.BondType.SINGLE)
                new_bond = combo.GetBondBetweenAtoms(idx, previous)
                BondProvenance.set_bond(new_bond, 'linker')
                previous = idx
            combo.AddBond(previous, anchor_B, Chem.BondType.SINGLE)
            new_bond = combo.GetBondBetweenAtoms(previous, anchor_B)
            BondProvenance.set_bond(new_bond, 'linker')
        else:
            raise ValueError('Impossible')
        return combo.GetMol()