from __future__ import division
import networkx as nx
from ._base import Descriptor
from .RingCount import Rings
__all__ = ('Framework',)
class FrameworkCache(Descriptor):
__slots__ = ()
def parameters(self):
return ()
def dependencies(self):
return {'Rs': Rings()}
def calculate(self, Rs):
G = nx.Graph()
Rd = {i: ('R', Ri) for Ri, R in enumerate(Rs) for i in R}
R = list(set(Rd.values()))
NR = len(R)
for bond in self.mol.GetBonds():
a = bond.GetBeginAtomIdx()
b = bond.GetEndAtomIdx()
a = Rd.get(a, ('A', a))
b = Rd.get(b, ('A', b))
G.add_edge(a, b)
linkers = set()
for Ri, Rj in ((i, j) for i in range(NR) for j in range(i + 1, NR)):
Ra, Rb = R[Ri], R[Rj]
try:
linkers.update(i for t, i in nx.shortest_path(G, Ra, Rb) if t == 'A')
except nx.NetworkXNoPath:
pass
return linkers, Rs
[docs]class Framework(Descriptor):
r"""molecular framework ratio descriptor.
.. math::
f_{\rm MF} = \frac{N_{\rm MF}}{N}
where
:math:`N_{\rm MF}` is number of atoms in molecular framework,
:math:`N` is number of all atoms.
References
* :cite:`10.1021/jm9602928`
"""
__slots__ = ()
@classmethod
def preset(cls):
yield cls()
def __str__(self):
return 'fMF'
[docs] def parameters(self):
return ()
def dependencies(self):
return {'F': FrameworkCache()}
def calculate(self, F):
linkers, rings = F
Nmf = len(linkers) + len({i for ring in rings for i in ring})
N = self.mol.GetNumAtoms()
return Nmf / N
rtype = float