Exemplo n.º 1
0
def _get_charge_delta_label(reactant_mol, product_mol):
    num_atom = reactant_mol.GetNumAtoms()

    reactant_c_count = np.zeros(num_atom, dtype=np.int)
    product_c_count = np.zeros_like(reactant_c_count)

    for atom in reactant_mol.GetAtoms():
        reactant_c_count[idxfunc(atom)] = atom.GetFormalCharge()

    for atom in product_mol.GetAtoms():
        product_c_count[idxfunc(atom)] = atom.GetFormalCharge()

    return (product_c_count - reactant_c_count) * -2
Exemplo n.º 2
0
def _get_hydrogen_delta_label(reactant_mol, product_mol):
    num_atom = reactant_mol.GetNumAtoms()

    reactant_h_count = np.zeros(num_atom, dtype=np.int)
    product_h_count = np.zeros_like(reactant_h_count)

    for atom in reactant_mol.GetAtoms():
        reactant_h_count[idxfunc(atom)] = atom.GetTotalNumHs()

    for atom in product_mol.GetAtoms():
        product_h_count[idxfunc(atom)] = atom.GetTotalNumHs()

    return (product_h_count - reactant_h_count) * 2
Exemplo n.º 3
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 def count_reactant_atom(mol_str):
     count = 0
     mol = Chem.MolFromSmiles(mol_str)
     for atom in mol.GetAtoms():
         if idxfunc(atom) in reactant_idx:
             count += 1
     return count
Exemplo n.º 4
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def get_delta_labels(reactant_mol, product_mol):
    product_atom_idx = {idxfunc(atom) for atom in product_mol.GetAtoms()}
    reactant_atom_idx = get_reactant_atom_idx(get_reactant_mols(reactant_mol),
                                              product_mol)

    edge_deltas = _get_edge_delta_label(reactant_mol, product_mol)
    h_deltas = _get_hydrogen_delta_label(reactant_mol, product_mol)
    c_deltas = _get_charge_delta_label(reactant_mol, product_mol)

    num_atom = reactant_mol.GetNumAtoms()
    octet_sum = np.zeros(num_atom, dtype=np.int)
    for idx in range(num_atom):

        for idx_other in range(num_atom):
            if idx not in product_atom_idx and idx_other not in product_atom_idx:
                edge_deltas[idx, idx_other] = edge_deltas[idx_other, idx] = 0

        if idx not in product_atom_idx and idx in reactant_atom_idx:
            # assume h on break
            h_deltas[idx] = -np.sum(edge_deltas[idx])
            c_deltas[idx] = 0
        elif idx not in product_atom_idx:
            h_deltas[idx] = 0
            c_deltas[idx] = 0

        octet_sum[idx] = np.sum(
            edge_deltas[idx]) + h_deltas[idx] + c_deltas[idx]

    return {
        EDGE_DELTA_KEY: edge_deltas,
        H_DELTA_KEY: h_deltas,
        C_DELTA_KEY: c_deltas,
        OCTET_SUM_KEY: octet_sum
    }
Exemplo n.º 5
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    def __init__(self, delta_pred,
                 num_candidates=10,
                 calibration=(EDGE_CALIBRATION_KEY),
                 soften=True,
                 octet_rule=True,
                 verbose=False):
        self.reaction_str = delta_pred[OUTPUT_REACTION_STR_KEY]
        self.edge_delta_pred = delta_pred[OUTPUT_EDGE_DELTA_KEY]
        self.c_delta_pred = delta_pred[OUTPUT_C_DELTA_KEY]
        self.h_delta_pred = delta_pred[OUTPUT_H_DELTA_KEY]
        if soften:
            self.edge_delta_pred = soften_matrix(self.edge_delta_pred)
            self.c_delta_pred = soften_matrix(self.c_delta_pred)
            self.h_delta_pred = soften_matrix(self.h_delta_pred)
        self.num_candidates = num_candidates
        self.edge_coefficient = 5.0
        self.h_coefficient = 1.0
        self.c_coefficient = 1.0
        self.octet_rule = octet_rule
        self.edge_calibration_fn = no_calibration
        self.h_calibration_fn = no_calibration
        if EDGE_CALIBRATION_KEY in calibration:
            self.edge_calibration_fn = smooth_calibrate
        if H_CALIBRATION_KEY in calibration:
            self.h_calibration_fn = smooth_calibrate
        self.verbose = verbose

        self.reactant_mol, self.product_mol = get_reactant_product_molecule(self.reaction_str)
        Chem.SanitizeMol(self.reactant_mol)
        Chem.Kekulize(self.reactant_mol, clearAromaticFlags=True)

        self.n_atom = self.reactant_mol.GetNumAtoms()

        self.reactant_atom_map = {idxfunc(atom): atom for atom in self.reactant_mol.GetAtoms()}
        self.reactant_bond_map = {bond_idx_tuple(bond): bond for bond in self.reactant_mol.GetBonds()}

        self.reactant_atom_idx = get_reactant_atom_idx(get_reactant_mols(self.reactant_mol), self.product_mol)

        self.idx_to_delta_vars = {}
        self.reaction_center_delta_vars = []
        self.model_objective = []

        self.model = Model('Gurobi Sampler for Octet Sampling')
        if not self.verbose:
            self.model.setParam(GRB.Param.OutputFlag, 0)

        self._set_variables()

        self._set_constraints()

        self._set_model_objective()

        self._set_model_param()

        self._optimize_model()
Exemplo n.º 6
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def _get_edge_delta_label(reactant_mol, product_mol):
    num_atom = reactant_mol.GetNumAtoms()

    reactant_edge_charge = np.zeros((num_atom, num_atom), dtype=np.int)
    product_edge_charge = np.zeros_like(reactant_edge_charge)

    for bond in reactant_mol.GetBonds():
        begin_atom_idx = idxfunc(bond.GetBeginAtom())
        end_atom_idx = idxfunc(bond.GetEndAtom())
        bond_charge = BOND_TYPE_TO_CHARGE[bond.GetBondType()]
        reactant_edge_charge[begin_atom_idx, end_atom_idx] = bond_charge
        reactant_edge_charge[end_atom_idx, begin_atom_idx] = bond_charge

    for bond in product_mol.GetBonds():
        begin_atom_idx = idxfunc(bond.GetBeginAtom())
        end_atom_idx = idxfunc(bond.GetEndAtom())
        bond_charge = BOND_TYPE_TO_CHARGE[bond.GetBondType()]
        product_edge_charge[begin_atom_idx, end_atom_idx] = bond_charge
        product_edge_charge[end_atom_idx, begin_atom_idx] = bond_charge

    return product_edge_charge - reactant_edge_charge
Exemplo n.º 7
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    def _build_solution_mol(self, solution_dict):

        solution_mol = Chem.rdchem.EditableMol(self.reactant_mol)

        # Modify Edge.
        for bond_idx, delta in sorted(solution_dict[EDGE_DELTA_VAR_NAME_HEADER].items(),
                                      key=operator.itemgetter(1),
                                      reverse=False):
            if abs(delta) > 0:
                idx1, idx2 = bond_idx
                atom_idx1 = self._idx_to_atom_idx(idx1)
                atom_idx2 = self._idx_to_atom_idx(idx2)
                old_bond = self.reactant_mol.GetBondBetweenAtoms(atom_idx1, atom_idx2)

                old_charge = 0
                if old_bond is not None:
                    old_charge += BOND_TYPE_TO_CHARGE[old_bond.GetBondType()]
                    solution_mol.RemoveBond(atom_idx1, atom_idx2)

                new_charge = old_charge + delta
                if new_charge > 0:
                    solution_mol.AddBond(atom_idx1, atom_idx2, CHARGE_TO_BOND_TYPE[new_charge])
                elif new_charge < 0:
                    raise ValueError('New charge cannot be negative: {}'.format(new_charge))

        # Get the modified solution mol.
        solution_mol = solution_mol.GetMol()
        solution_mol_atom_map = {idxfunc(atom): atom for atom in solution_mol.GetAtoms()}

        # Modify H.
        for idx, delta in solution_dict[H_DELTA_VAR_NAME_HEADER].items():
            if abs(delta) > 0:
                atom = solution_mol_atom_map[idx]
                old_h = int(atom.GetTotalNumHs())
                atom.SetNoImplicit(True)
                new_h = int(old_h + (delta / 2))
                atom.SetNumExplicitHs(new_h)

        # Modify Charge.
        for idx, delta in solution_dict[C_DELTA_VAR_NAME_HEADER].items():
            if abs(delta) > 0:
                atom = solution_mol_atom_map[idx]
                new_c = int(atom.GetFormalCharge() - (delta / 2))
                atom.SetFormalCharge(new_c)

        try:
            solution_mol = Chem.Mol(solution_mol)
            Chem.SanitizeMol(solution_mol)
            Chem.Kekulize(solution_mol, clearAromaticFlags=False)
            Chem.SanitizeMol(solution_mol)
            return solution_mol
        except ValueError as ve:
            return None
Exemplo n.º 8
0
def get_mol_atom_features(reactant_mol, num_atom=None, reactant_atom_idx=None):
    if num_atom is None:
        num_atom = reactant_mol.GetNumAtoms()
    atom_features = np.zeros((num_atom, ATOM_FEATURE_DIM), dtype=np.float)

    for atom in reactant_mol.GetAtoms():
        idx = idxfunc(atom)
        atom_feature = np.append(_get_atomic_features(atom.GetAtomicNum()), _get_atom_features(atom))
        atom_features[idx, :ATOM_FEATURE_DIM - 1] = atom_feature
        if reactant_atom_idx is not None and idx in reactant_atom_idx:
            atom_features[idx, -1] = 1

    return {ATOM_FEATURES_KEY: atom_features}
Exemplo n.º 9
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def bond_idx_tuple(bond):
    return tuple(
        sorted([idxfunc(bond.GetBeginAtom()),
                idxfunc(bond.GetEndAtom())]))
Exemplo n.º 10
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def get_mol_bond_features(reactant_mol,
                          num_atom=None,
                          reactant_atom_idx=None,
                          reactant_component_map=None):
    if num_atom is None:
        num_atom = reactant_mol.GetNumAtoms()

    bond_features = np.zeros((num_atom, num_atom, BOND_FEATURE_DIM),
                             dtype=np.float)
    neighbor_atom = np.zeros((num_atom, MAX_NEIGHBOR_NUM), dtype=np.int)
    neighbor_bond = np.zeros((num_atom, MAX_NEIGHBOR_NUM, 2), dtype=np.int)
    neighbor_mask = np.zeros_like(neighbor_atom)
    neighbor_num = np.zeros(num_atom, dtype=np.int)

    for bond in reactant_mol.GetBonds():
        begin_atom_idx = idxfunc(bond.GetBeginAtom())
        end_atom_idx = idxfunc(bond.GetEndAtom())

        neighbor_atom[begin_atom_idx,
                      neighbor_num[begin_atom_idx]] = end_atom_idx
        neighbor_atom[end_atom_idx,
                      neighbor_num[end_atom_idx]] = begin_atom_idx
        neighbor_bond[begin_atom_idx, neighbor_num[begin_atom_idx]] = [
            begin_atom_idx, end_atom_idx
        ]
        neighbor_bond[end_atom_idx, neighbor_num[end_atom_idx]] = [
            end_atom_idx, begin_atom_idx
        ]
        neighbor_mask[begin_atom_idx, neighbor_num[begin_atom_idx]] = 1
        neighbor_mask[end_atom_idx, neighbor_num[end_atom_idx]] = 1
        neighbor_num[begin_atom_idx] += 1
        neighbor_num[end_atom_idx] += 1

        bond_feature = _get_bond_features(bond)

        if reactant_atom_idx is not None and (
                begin_atom_idx in reactant_atom_idx
                or end_atom_idx in reactant_atom_idx):
            bond_feature = np.append(bond_feature, 1)
        else:
            bond_feature = np.append(bond_feature, 0)

        # bond exists
        bond_feature = np.append(bond_feature, 1)

        bond_features[begin_atom_idx,
                      end_atom_idx, :BOND_FEATURE_DIM - 2] = bond_feature
        bond_features[end_atom_idx,
                      begin_atom_idx, :BOND_FEATURE_DIM - 2] = bond_feature

    for i in range(num_atom):
        for j in range(num_atom):
            if reactant_component_map is not None and reactant_component_map[COMPONENT_MAP_KEY][i] == \
                    reactant_component_map[COMPONENT_MAP_KEY][j]:
                bond_features[i, j, -2] = bond_features[j, i, -2] = 1
            else:
                bond_features[i, j, -2] = bond_features[j, i, -2] = 0

            if reactant_component_map is not None and reactant_component_map[
                    COMPONENT_NUM_KEY] > 1:
                bond_features[i, j, -1] = bond_features[j, i, -1] = 1
            else:
                bond_features[i, j, -1] = bond_features[j, i, -1] = 0

    return {
        BOND_FEATURES_KEY: bond_features,
        NEIGHBOR_ATOM_KEY: neighbor_atom,
        NEIGHBOR_BOND_KEY: neighbor_bond,
        NEIGHBOR_MASK_KEY: neighbor_mask
    }