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FiveConf.py
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FiveConf.py
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# -*- coding: utf-8 -*-
"""
Created on Wed Dec 17 15:20:18 2014
@author: ke291
Gets called by PyDP4.py if automatic 5-membered cycle corner-flipping is used.
"""
import numpy as np
from math import sqrt, pi, cos, sin, acos
import scipy.optimize as sciopt
try:
from openbabel.openbabel import OBConversion, OBMol, OBAtomAtomIter, OBMolAtomIter
except ImportError:
from openbabel import *
def main(f, settings):
"""
Find the axis atoms
Find all the atoms to be rotated
Rotate it and the substituents to the other side of the plane
"""
obconversion = OBConversion()
obconversion.SetInFormat("sdf")
obmol = OBMol()
obconversion.ReadFile(obmol, f)
obmol.ConnectTheDots()
#Find the atoms composing furan ring
Rings = obmol.GetSSSR()
furan = []
for ring in Rings:
if len(settings.RingAtoms) == 5:
if all(x in ring._path for x in settings.RingAtoms):
furan = ring
break
else:
if ring.Size() == 5 and not ring.IsAromatic():
furan = ring
break
if furan == []:
"No five membered rings to rotate. Quitting..."
quit()
#Find the plane of the 5-membered ring and the outlying atom
norm, d, outAtom = FindFuranPlane(obmol, furan)
#Find the atoms connected to the outlying atom and sort them
#as either part of the ring(axis atoms) or as atoms to be rotated
AxisAtoms = []
RotAtoms = []
for NbrAtom in OBAtomAtomIter(outAtom):
#if NbrAtom.IsInRingSize(5):
if furan.IsInRing(NbrAtom.GetIdx()):
AxisAtoms.append(NbrAtom)
else:
RotAtoms.append(NbrAtom)
FindSubstAtoms(NbrAtom, outAtom, RotAtoms)
#Simple switch to help detect if the atoms are rotated the right way
WasAbove90 = False
angle = FindRotAngle(AxisAtoms[0], AxisAtoms[1], outAtom, norm)
if angle > 0.5*pi:
WasAbove90 = True
rotangle = 2*(angle-0.5*pi)
else:
WasAbove90 = False
rotangle = 2*(0.5*pi-angle)
OldAtomCoords = outAtom.GetVector()
print("Atom " + str(outAtom.GetAtomicNum()) + " will be rotated by " +\
str(rotangle*57.3) + ' degrees')
RotateAtom(outAtom, AxisAtoms[0], AxisAtoms[1], rotangle)
angle2 = FindRotAngle(AxisAtoms[0], AxisAtoms[1], outAtom, norm)
#if the atom is on the same side of the plane as it was,
# it has been rotated in the wrong direction
if ((angle2 > 0.5*pi) and WasAbove90) or ((angle2 < 0.5*pi) and not WasAbove90):
#Flip the sign of the rotation angle, restore the coords
#and rotate the atom in the opposite direction
print("Atom was rotated the wrong way, switching the direction")
rotangle = -rotangle
outAtom.SetVector(OldAtomCoords)
RotateAtom(outAtom, AxisAtoms[0], AxisAtoms[1], rotangle)
RotatedAtoms = [] # Index to make sure that atoms are not rotated twice
for atom in RotAtoms:
if atom not in RotatedAtoms:
RotateAtom(atom, AxisAtoms[0], AxisAtoms[1], rotangle)
RotatedAtoms.append(atom)
else:
print("Atom already rotated, skipping")
obconversion.SetOutFormat("sdf")
obconversion.WriteFile(obmol, f[:-4] + 'rot.sdf')
#Recursively finds all the atoms connected to the input
def FindSubstAtoms(atom, outAtom, al):
indexes = [a.GetIdx() for a in al]
for NbrAtom in OBAtomAtomIter(atom):
if (NbrAtom.GetIdx() not in indexes) and\
(NbrAtom.GetIdx() != outAtom.GetIdx()):
al.append(NbrAtom)
FindSubstAtoms(NbrAtom, outAtom, al)
#Rotate atom around and axis by an angle
def RotateAtom(atom, AxisAtom1, AxisAtom2, angle):
[u, v, w] = GetUnitVector(AxisAtom1, AxisAtom2)
[x, y, z] = [atom.x(), atom.y(), atom.z()]
[a, b, c] = [(AxisAtom1.x()+AxisAtom1.x())/2, (AxisAtom1.y()+AxisAtom1.y())/2,\
(AxisAtom1.z()+AxisAtom1.z())/2]
X = (a*(v**2 + w**2) - u*(b*v+c*w-u*x-v*y-w*z))*(1-cos(angle))+x*cos(angle)\
+(-1*c*v+b*w-w*y+v*z)*sin(angle)
Y = (b*(u**2 + w**2) - v*(a*u+c*w-u*x-v*y-w*z))*(1-cos(angle))+y*cos(angle)\
+(c*u-a*w+w*x-u*z)*sin(angle) #was _+_u*z)*sin(angle)
Z = (c*(u**2 + v**2) - w*(a*u+b*v-u*x-v*y-w*z))*(1-cos(angle))+z*cos(angle)\
+(-1*b*u+a*v-v*x+u*y)*sin(angle)
atom.SetVector(X, Y, Z)
def GetUnitVector(Atom1, Atom2):
vector = []
vector.append(Atom2.x() - Atom1.x())
vector.append(Atom2.y() - Atom1.y())
vector.append(Atom2.z() - Atom1.z())
length = np.linalg.norm(vector)
return [x/length for x in vector]
#Finds the angle by which atoms need to be rotated by taking the angle
#the atom is out of the plane (the 2 neighbor atoms being the axis)
#and doubling it
def FindRotAngle(AxisAtom1, AxisAtom2, OutAtom, Normal):
start = []
start.append((AxisAtom1.x() + AxisAtom2.x())/2)
start.append((AxisAtom1.y() + AxisAtom2.y())/2)
start.append((AxisAtom1.z() + AxisAtom2.z())/2)
vector = []
vector.append(OutAtom.x() - start[0])
vector.append(OutAtom.y() - start[1])
vector.append(OutAtom.z() - start[2])
#Angle between plane normal and OOP atom
vangle = angle(vector, Normal)
#print "Measured angle: " + str(vangle*57.3)
return vangle
def crossproduct(v1, v2):
product = [0, 0, 0]
product[0] = v1[1]*v2[2]-v1[2]*v2[1]
product[1] = v1[2]*v2[0]-v1[0]*v2[2]
product[2] = v1[0]*v2[1]-v1[1]*v2[0]
return product
def dotproduct(v1, v2):
return sum((a*b) for a, b in zip(v1, v2))
def length(v):
return sqrt(dotproduct(v, v))
def angle(v1, v2):
return acos(dotproduct(v1, v2) / (length(v1) * length(v2)))
"""Finds planes for every 3 atoms, calculates distances to the plane
for the other 2 atoms andchoose the plane with the smallest smallest distance
"""
def FindFuranPlane(mol, furan):
atomIds = furan._path
atoms = []
for i in atomIds:
atoms.append(mol.GetAtom(i))
MinError = 100.0
for atom in atoms:
pats = [a for a in atoms if a != atom]
norm, d, error = LstSqPlane(pats[0], pats[1], pats[2], pats[3])
if error < MinError:
MinError = error
MaxNorm = norm
MaxD = d
OutAtom = atom
return MaxNorm, MaxD, OutAtom
#Given 3 atoms, finds a plane defined by a normal vector and d
def FindPlane(atom1, atom2, atom3):
vector1 = [atom2.x() - atom1.x(), atom2.y() - atom1.y(),
atom2.z() - atom1.z()]
vector2 = [atom3.x() - atom1.x(), atom3.y() - atom1.y(),
atom3.z() - atom1.z()]
cross_product = [vector1[1] * vector2[2] - vector1[2] * vector2[1],
-1 * vector1[0] * vector2[2] + vector1[2] * vector2[0],
vector1[0] * vector2[1] - vector1[1] * vector2[0]]
d = cross_product[0] * atom1.x() - cross_product[1] * atom1.y() + \
cross_product[2] * atom1.z()
return cross_product, d
def LstSqPlane(atom1, atom2, atom3, atom4):
# Inital guess of the plane
[a0, b0, c0], d0 = FindPlane(atom1, atom2, atom3)
f = lambda a: PlaneError([atom1, atom2, atom3, atom4], a[0], a[1], a[2], a[3])
res = sciopt.minimize(f, (a0, b0, c0, d0), method='nelder-mead')
plane = list(res.x)
return plane[:3], plane[3], f(plane)
def PlaneError(atoms, a, b, c, d):
dists = []
for atom in atoms:
dists.append(abs(PointPlaneDist([a, b, c], d, atom)))
return sum(dists)/len(dists)
#Calculates distance from an atom to a plane
def PointPlaneDist(norm, d, atom):
point = []
point.append(atom.x())
point.append(atom.y())
point.append(atom.z())
a = norm[0]*point[0] + norm[1]*point[1] + norm[2]*point[2] + d
b = sqrt(norm[0]**2 + norm[1]**2 + norm[2]**2)
return a/b