def testBLJ_isomer(self):
        """
        test with BLJ potential.  We have two classes of permutable atoms  
        
        test case where X2 is an isomer of X1.
        """
        import pele.utils.rotations as rot
        X1i = np.copy(self.X1)
        X1 = np.copy(self.X1)        
        X2 = np.copy(X1)
        
        #rotate X2 randomly
        aa = rot.random_aa()
        rot_mx = rot.aa2mx( aa )
        for j in range(self.natoms):
            i = 3*j
            X2[i:i+3] = np.dot( rot_mx, X1[i:i+3] )
        
        #permute X2
        import random, copy
        from pele.mindist.permutational_alignment import permuteArray
        for atomlist in self.permlist:
            perm = copy.copy(atomlist)
            random.shuffle( perm )
            X2 = permuteArray( X2, perm)

        X2i = np.copy(X2)
        
        #distreturned, X1, X2 = self.runtest(X1, X2)
        distreturned, X1, X2 = self.runtest(X1, X2, MinPermDistCluster(measure=MeasureAtomicCluster(permlist=self.permlist)))

        
        #it's an isomer, so the distance should be zero
        self.assertTrue( abs(distreturned) < 1e-14, "didn't find isomer: dist = %g" % distreturned)
Пример #2
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    def testBLJ_isomer(self):
        """
        test with BLJ potential.  We have two classes of permutable atoms  
        
        test case where X2 is an isomer of X1.
        """
        import pele.utils.rotations as rot
        X1i = np.copy(self.X1)
        X1 = np.copy(self.X1)        
        X2 = np.copy(X1)
        
        #rotate X2 randomly
        aa = rot.random_aa()
        rot_mx = rot.aa2mx( aa )
        for j in range(self.natoms):
            i = 3*j
            X2[i:i+3] = np.dot( rot_mx, X1[i:i+3] )
        
        #permute X2
        import random, copy
        from pele.mindist.permutational_alignment import permuteArray
        for atomlist in self.permlist:
            perm = copy.copy(atomlist)
            random.shuffle( perm )
            X2 = permuteArray( X2, perm)

        X2i = np.copy(X2)
        
        #distreturned, X1, X2 = self.runtest(X1, X2)
        distreturned, X1, X2 = self.runtest(X1, X2, MinPermDistCluster(measure=MeasureAtomicCluster(permlist=self.permlist)))

        
        #it's an isomer, so the distance should be zero
        self.assertTrue( abs(distreturned) < 1e-14, "didn't find isomer: dist = %g" % distreturned)
Пример #3
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def test_LJ(natoms = 12, **kwargs):
    from pele.potentials.lj import LJ
    from pele.optimize import mylbfgs
    import pele.utils.rotations as rot
    from pele.mindist.permutational_alignment import permuteArray
    import random
    
    quench = mylbfgs
    lj = LJ()
    X1 = np.random.uniform(-1,1,[natoms*3])*(float(natoms))**(1./3)
    #quench X1
    ret = quench( X1, lj)
    X1 = ret.coords
    X2 = np.random.uniform(-1,1,[natoms*3])*(float(natoms))**(1./3)
    #make X2 a rotation of X1
    print "testing with", natoms, "atoms, with X2 a rotated and permuted isomer of X1"
    aa = rot.random_aa()
    rot_mx = rot.aa2mx( aa )
    for j in range(natoms):
        i = 3*j
        X2[i:i+3] = np.dot( rot_mx, X1[i:i+3] )
    perm = range(natoms)
    random.shuffle( perm )
    print perm
    X2 = permuteArray( X2, perm)

    #X1 = np.array( [ 0., 0., 0., 1., 0., 0., 0., 0., 1.,] )
    #X2 = np.array( [ 0., 0., 0., 1., 0., 0., 0., 1., 0.,] )
    import copy
    X1i = copy.copy(X1)
    X2i = copy.copy(X2)
 
    print "******************************"
    print "testing normal LJ  ISOMER"
    print "******************************"
    test(X1, X2, lj, **kwargs)
    
    print "******************************"
    print "testing normal LJ  non isomer"
    print "******************************"
    X2 = np.random.uniform(-1,1,[natoms*3])*(float(natoms))**(1./3)
    ret = quench( X2, lj)
    X2 = ret.coords
    
    Y = X1.reshape([-1,3])
    Y+=np.random.random(3)
    X1[:] = Y.flatten()
 
    test(X1, X2, lj, **kwargs)
    

    distinit = np.linalg.norm(X1-X2)
    print "distinit", distinit
Пример #4
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def test_LJ(natoms=12, **kwargs):  # pragma: no cover
    from pele.potentials.lj import LJ
    from pele.optimize import mylbfgs
    import pele.utils.rotations as rot
    from pele.mindist.permutational_alignment import permuteArray
    import random

    quench = mylbfgs
    lj = LJ()
    X1 = np.random.uniform(-1, 1, [natoms * 3]) * (float(natoms))**(1. / 3)
    # quench X1
    ret = quench(X1, lj)
    X1 = ret.coords
    X2 = np.random.uniform(-1, 1, [natoms * 3]) * (float(natoms))**(1. / 3)
    # make X2 a rotation of X1
    print("testing with", natoms,
          "atoms, with X2 a rotated and permuted isomer of X1")
    aa = rot.random_aa()
    rot_mx = rot.aa2mx(aa)
    for j in range(natoms):
        i = 3 * j
        X2[i:i + 3] = np.dot(rot_mx, X1[i:i + 3])
    perm = list(range(natoms))
    random.shuffle(perm)
    print(perm)
    X2 = permuteArray(X2, perm)

    import copy
    X1i = copy.copy(X1)
    X2i = copy.copy(X2)

    print("******************************")
    print("testing normal LJ  ISOMER")
    print("******************************")
    test(X1, X2, lj, **kwargs)

    print("******************************")
    print("testing normal LJ  non isomer")
    print("******************************")
    X2 = np.random.uniform(-1, 1, [natoms * 3]) * (float(natoms))**(1. / 3)
    ret = quench(X2, lj)
    X2 = ret.coords

    Y = X1.reshape([-1, 3])
    Y += np.random.random(3)
    X1[:] = Y.flatten()

    test(X1, X2, lj, **kwargs)

    distinit = np.linalg.norm(X1 - X2)
    print("distinit", distinit)
Пример #5
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def test_LJ(natoms = 12, **kwargs):
    from pele.potentials.lj import LJ
    import pele.defaults
    import pele.utils.rotations as rot
    from pele.mindist.permutational_alignment import permuteArray
    import random

    quench = pele.defaults.quenchRoutine
    lj = LJ()
    X1 = np.random.uniform(-1,1,[natoms*3])*(float(natoms))**(1./3)
    #quench X1
    ret = quench( X1, lj.getEnergyGradient)
    X1 = ret[0]
    X2 = np.random.uniform(-1,1,[natoms*3])*(float(natoms))**(1./3)
    #make X2 a rotation of X1
    print "testing with", natoms, "atoms, with X2 a rotated and permuted isomer of X1"
    aa = rot.random_aa()
    rot_mx = rot.aa2mx( aa )
    for j in range(natoms):
        i = 3*j
        X2[i:i+3] = np.dot( rot_mx, X1[i:i+3] )
    perm = range(natoms)
    random.shuffle( perm )
    print perm
    X2 = permuteArray( X2, perm)

    #X1 = np.array( [ 0., 0., 0., 1., 0., 0., 0., 0., 1.,] )
    #X2 = np.array( [ 0., 0., 0., 1., 0., 0., 0., 1., 0.,] )
    import copy
    X1i = copy.copy(X1)
    X2i = copy.copy(X2)
    
    print "******************************"
    print "testing normal LJ  ISOMER"
    print "******************************"
    test(X1, X2, lj, **kwargs)
    
    print "******************************"
    print "testing normal LJ  non isomer"
    print "******************************"
    X2 = np.random.uniform(-1,1,[natoms*3])*(float(natoms))**(1./3)
    ret = quench( X2, lj.getEnergyGradient)
    X2 = ret[0]
    test(X1, X2, lj, **kwargs)
    

    distinit = np.linalg.norm(X1-X2)
    print "distinit", distinit
Пример #6
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def test_binary_LJ(natoms = 12, **kwargs):
    import pele.defaults
    import pele.utils.rotations as rot
    quench = pele.defaults.quenchRoutine

    printlist = []
    
    ntypea = int(natoms*.8)
    from pele.potentials.ljpshift import LJpshift
    lj = LJpshift(natoms, ntypea)
    permlist = [range(ntypea), range(ntypea, natoms)]

    X1 = np.random.uniform(-1,1,[natoms*3])*(float(natoms))**(1./3)/2
    printlist.append( (X1.copy(), "very first"))
    #quench X1
    ret = quench( X1, lj.getEnergyGradient)
    X1 = ret[0]
    printlist.append((X1.copy(), "after quench"))

    X2 = np.random.uniform(-1,1,[natoms*3])*(float(natoms))**(1./3)
    #make X2 a rotation of X1
    print "testing with", natoms, "atoms,", ntypea, "type A atoms, with X2 a rotated and permuted isomer of X1"
    aa = rot.random_aa()
    rot_mx = rot.aa2mx( aa )
    for j in range(natoms):
        i = 3*j
        X2[i:i+3] = np.dot( rot_mx, X1[i:i+3] )
    printlist.append((X2.copy(), "x2 after rotation"))
    

    

    import random, copy
    from pele.mindist.permutational_alignment import permuteArray

    for atomlist in permlist:
        perm = copy.copy(atomlist)
        random.shuffle( perm )
        print perm
        X2 = permuteArray( X2, perm)
    printlist.append((X2.copy(), "x2 after permutation"))


    #X1 = np.array( [ 0., 0., 0., 1., 0., 0., 0., 0., 1.,] )
    #X2 = np.array( [ 0., 0., 0., 1., 0., 0., 0., 1., 0.,] )
    X1i = copy.copy(X1)
    X2i = copy.copy(X2)
    
    atomtypes = ["N" for i in range(ntypea)]
    for i in range(natoms-ntypea):
        atomtypes.append("O")
    
    print "******************************"
    print "testing binary LJ  ISOMER"
    print "******************************"
    test(X1, X2, lj, atomtypes=atomtypes, permlist = permlist, **kwargs)
    
    print "******************************"
    print "testing binary LJ  non isomer"
    print "******************************"
    X2 = np.random.uniform(-1,1,[natoms*3])*(float(natoms))**(1./3)
    ret = quench( X2, lj.getEnergyGradient)
    X2 = ret[0]
    test(X1, X2, lj, atomtypes=atomtypes, permlist=permlist, **kwargs)