def test1Canonicalization(self):
mol = Chem.MolFromSmiles("C")
conf = Chem.Conformer(1)
conf.SetAtomPosition(0, (4.0, 5.0, 6.0))
mol.AddConformer(conf, 1)
conf = mol.GetConformer()
pt = rdmt.ComputeCentroid(conf)
self.failUnless(ptEq(pt, geom.Point3D(4.0, 5.0, 6.0)))
fileN = os.path.join(RDConfig.RDBaseDir, 'Code', 'GraphMol',
'MolTransforms', 'test_data', '1oir.mol')
m = Chem.MolFromMolFile(fileN)
cpt = rdmt.ComputeCentroid(m.GetConformer())
trans = rdmt.ComputeCanonicalTransform(m.GetConformer(), cpt)
trans2 = rdmt.ComputeCanonicalTransform(m.GetConformer())
for i in range(4):
for j in range(4):
self.failUnless(feq(trans[i, j], trans2[i, j]))
rdmt.TransformConformer(m.GetConformer(), trans2)
m2 = Chem.MolFromMolFile(fileN)
rdmt.CanonicalizeConformer(m2.GetConformer())
nats = m.GetNumAtoms()
cnf1 = m.GetConformer()
cnf2 = m2.GetConformer()
for i in range(nats):
p1 = list(cnf1.GetAtomPosition(i))
p2 = list(cnf2.GetAtomPosition(i))
self.failUnless(feq(p1[0], p2[0]))
self.failUnless(feq(p1[1], p2[1]))
self.failUnless(feq(p1[2], p2[2]))
m3 = Chem.MolFromMolFile(fileN)
rdmt.CanonicalizeMol(m3)
cnf1 = m.GetConformer()
cnf2 = m3.GetConformer()
for i in range(nats):
p1 = list(cnf1.GetAtomPosition(i))
p2 = list(cnf2.GetAtomPosition(i))
self.failUnless(feq(p1[0], p2[0]))
self.failUnless(feq(p1[1], p2[1]))
self.failUnless(feq(p1[2], p2[2]))
def test1Shape(self):
fileN = os.path.join(RDConfig.RDBaseDir, 'Code', 'GraphMol',
'ShapeHelpers', 'test_data', '1oir.mol')
m = Chem.MolFromMolFile(fileN)
rdmt.CanonicalizeMol(m)
dims1, offset1 = rdshp.ComputeConfDimsAndOffset(m.GetConformer())
grd = geom.UniformGrid3D(30.0, 16.0, 10.0)
rdshp.EncodeShape(m, grd, 0)
ovect = grd.GetOccupancyVect()
self.failUnless(ovect.GetTotalVal() == 9250)
m = Chem.MolFromMolFile(fileN)
trans = rdmt.ComputeCanonicalTransform(m.GetConformer())
dims, offset = rdshp.ComputeConfDimsAndOffset(m.GetConformer(),
trans=trans)
dims -= dims1
offset -= offset1
self.failUnless(feq(dims.Length(), 0.0))
self.failUnless(feq(offset.Length(), 0.0))
grd1 = geom.UniformGrid3D(30.0, 16.0, 10.0)
rdshp.EncodeShape(m, grd1, 0, trans)
ovect = grd1.GetOccupancyVect()
self.failUnless(ovect.GetTotalVal() == 9250)
grd2 = geom.UniformGrid3D(30.0, 16.0, 10.0)
rdshp.EncodeShape(m, grd2, 0)
fileN2 = os.path.join(RDConfig.RDBaseDir, 'Code', 'GraphMol',
'ShapeHelpers', 'test_data', '1oir_conf.mol')
m2 = Chem.MolFromMolFile(fileN2)
rmsd = rdMolAlign.AlignMol(m, m2)
self.failUnless(feq(rdshp.ShapeTanimotoDist(m, m2), 0.2813))
dist = rdshp.ShapeTanimotoDist(mol1=m,
mol2=m2,
confId1=0,
confId2=0,
gridSpacing=0.25,
stepSize=0.125)
self.failUnless(feq(dist, 0.3021))
m = Chem.MolFromMolFile(fileN)
cpt = rdmt.ComputeCentroid(m.GetConformer())
dims, offset = rdshp.ComputeConfDimsAndOffset(m.GetConformer())
grd = geom.UniformGrid3D(dims.x, dims.y, dims.z, 0.5,
DataStructs.DiscreteValueType.TWOBITVALUE,
offset)
dims -= geom.Point3D(13.927, 16.97, 9.775)
offset -= geom.Point3D(-4.353, 16.829, 2.782)
self.failUnless(feq(dims.Length(), 0.0))
self.failUnless(feq(offset.Length(), 0.0))
rdshp.EncodeShape(m, grd, 0)
ovect = grd.GetOccupancyVect()
self.failUnless(ovect.GetTotalVal() == 9275)
geom.WriteGridToFile(grd, '1oir_shape.grd')
m = Chem.MolFromMolFile(fileN)
lc, uc = rdshp.ComputeConfBox(m.GetConformer())
rdmt.CanonicalizeMol(m)
lc1, uc1 = rdshp.ComputeConfBox(m.GetConformer())
lc2, uc2 = rdshp.ComputeUnionBox((lc, uc), (lc1, uc1))
lc -= geom.Point3D(-4.353, 16.829, 2.782)
uc -= geom.Point3D(9.574, 33.799, 12.557)
self.failUnless(feq(lc.Length(), 0.0))
self.failUnless(feq(uc.Length(), 0.0))
lc1 -= geom.Point3D(-10.7519, -6.0778, -3.0123)
uc1 -= geom.Point3D(8.7163, 5.3279, 3.1621)
self.failUnless(feq(lc1.Length(), 0.0))
self.failUnless(feq(uc1.Length(), 0.0))
lc2 -= geom.Point3D(-10.7519, -6.0778, -3.01226)
uc2 -= geom.Point3D(9.574, 33.799, 12.557)
self.failUnless(feq(lc2.Length(), 0.0))
self.failUnless(feq(uc2.Length(), 0.0))
