def main():
    """
    This test shows various operators within Bond and BondContainer classes
    """

    print "************************************************************************************"
    print " This test shows various operators within Bond and BondContainer classes    "
    print "************************************************************************************ \n"

    print "Testing Bond and BondContainer"
    b1 = Bond( 1, 2, 1.233, "hooke")
    b2 = Bond( 3, 4, 0.5,   "hooke")
    b3 = Bond( )
    b4 = Bond( 3, 8, 0.5,   "stiff")

    bonds = BondContainer()
    bonds.put(b1)
    bonds.put(b2)
    bonds.put(b3)
    bonds.put(b4)
    del b1, b2, b3, b4
    print "\n Cleaning memory for initial objects \n" 

    print "Check for pre-existing bond"
    if bonds.hasBond([2,1]):
        print "bond 1--2 exists"
    else:
        print "bond 1--2 does NOT exists"

    print "Check for pre-existing bond"
    if bonds.hasBond([2,3]):
        print "bond 2--3 exists"
    else:
        print "bond 2--3 does NOT exist"


    print " "
    print "Bonds: ", bonds
    print " "

    print "Test iterator for bond container "
    for gid, bondObj in bonds:
        print "bondID = ", gid, "bond object ", bondObj.__dict__
    print " "

    searchID = 2
    print "Testing 'in' operator for searchID ", searchID, " in bonds"
    if searchID in bonds:
        print "ID ",searchID, " in bonds"
    else:
        print "nope"

    print "-----------------------------------------------------"
    print "bonds.getTypeInfoDict() ", bonds.getTypeInfoDict()
    print "-----------------------------------------------------"

    print " "
    print "Here's an issue... globalID's are assigned by ParticleContainer class "
    print "Setting Bond object with gid's of Particles needs to be done after PC class set "
    print "or there could be conflicts \n"
def main():
    """
    This test shows how reorder (compress) global IDs for a StructureContainer
    """
    p1 = Particle([0.2, 1.3, 33.0], "Si", 2.0, 1.23)
    p2 = Particle([5.0, 2.3, -22.1], "C", 1.0, 2.34)
    p3 = Particle([5.0, 2.3, -20.1], "C", 1.0, 2.34)

    b1 = Bond(1, 2, 1.233, "hooke")
    b2 = Bond(2, 3, 0.500, "hooke")

    atoms1 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)

    bonds1 = BondContainer()
    bonds1.put(b1)
    bonds1.put(b2)

    polymer1 = StructureContainer(atoms1, bonds1)  # Complete structure 1

    p1other = Particle([0.0, 2.3, -20.1], "C", 1.0, 2.34)
    p2other = Particle([50.0, 0.3, -0.1], "Ar", 2.0, 2.34)
    p3other = Particle([50.0, 0.3, -0.1], "Ar", 2.0, 2.34)

    b1other = Bond(1, 3, 1.233,
                   "hooke")  # Correct ptclIDs for second structure

    atoms2 = ParticleContainer()
    atoms2.put(p1other)
    atoms2.put(p2other)
    atoms2.put(p3other)

    del atoms2[2]  # remove 2nd particle so ID's are non-consecutive

    bonds2 = BondContainer()
    bonds2.put(b1other)

    polymer2 = StructureContainer(atoms2,
                                  bonds2)  # Complete structure 1 completely

    del p1, p2, p3, p1other, p2other, b1, b2, b1other, atoms1, atoms2, bonds1, bonds2
    print "\n Cleaning memory for initial objects \n"

    print "-------------------- Before adding --------------------"
    print "polymer1 = ", polymer1
    print "polymer2 = ", polymer2
    print " "

    print "-------------------- After adding --------------------"
    polymer2 += polymer1
    print "polymer2 = ", polymer2

    polymer2.compressPtclIDs()

    print "-------------------- After compressing --------------------"
    print "polymer2 = ", polymer2
def main():
    """
    This test shows how to add StructureContainer objects together
    A special test to double-check re-labeling ... add a big container to a 'small' one
    """
    print "***************************************************************************************"
    print " This test shows how to add StructureContainer objects together "
    print " A special test to double-check re-labeling ... add a big container to a 'small' one "
    print "*************************************************************************************** \n"

    p1 = Particle([1.1, 1.1, 1.1], "Si", 2.0, 1.23)
    p2 = Particle([2.2, 2.2, 2.2], "C", 1.0, 2.34)
    p3 = Particle([3.3, 3.3, 3.3], "C", 1.0, 2.34)

    b1 = Bond(1, 2, 1.111, "hooke")
    b2 = Bond(2, 3, 2.222, "hooke")

    atoms1 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)

    bonds1 = BondContainer()
    bonds1.put(b1)
    bonds1.put(b2)

    polymer1 = StructureContainer(atoms1,
                                  bonds1)  # Complete structure 1 completely

    p1other = Particle([1.11, 1.11, 1.11], "C", 1.0, 2.34)
    p2other = Particle([2.22, 2.22, 2.22], "Ar", 2.0, 2.34)

    b1other = Bond(1, 2, 1.1,
                   "hooke-2")  # Correct ptclIDs for second structure

    atoms2 = ParticleContainer()
    atoms2.put(p1other)
    atoms2.put(p2other)

    bonds2 = BondContainer()
    bonds2.put(b1other)

    polymer2 = StructureContainer(atoms2,
                                  bonds2)  # Complete structure 1 completely

    del p1, p2, p3, p1other, p2other, b1, b2, b1other, atoms1, atoms2, bonds1, bonds2
    print "\n Cleaning memory for initial objects \n"

    print "-------------------- Before adding --------------------"
    print "polymer1 = ", polymer1
    print "polymer2 = ", polymer2
    print " "

    print "-------------------- After adding --------------------"
    # polymer1 += polymer2
    polymer2 += polymer1
    print "polymer2 = ", polymer2
Пример #4
0
def runStrucAdd(numPtcls1, numPtcls2):
    """
    Creates structures with ptcls and bonds between consecutive IDs
    Adds and reports timing

    Args:
        numPtcls1 (int): # of ptcls in first  struc
        numPtcls2 (int): # of ptcls in second struc
    Returns:
           (initTime, addTime, compressTime)
    """

    atoms1 = ParticleContainer()
    bonds1 = BondContainer()
    atoms2 = ParticleContainer()
    bonds2 = BondContainer()

    start_time = time.time()
    for n in range(numPtcls1):
        pobj1 = Particle([1.1, 1.1, 1.1], "Si", 2.0, float(n + 1))
        atoms1.put(pobj1)

    for n in range(1, numPtcls1):
        bobj1 = Bond(n, n + 1, 1.233, "hooke-1")
        bonds1.put(bobj1)

    for n in range(numPtcls2):
        pobj2 = Particle([2.2, 2.2, 2.2], "C", 1.0, float(n + 1))
        atoms2.put(pobj2)

    for n in range(1, numPtcls2):
        bobj2 = Bond(n, n + 1, 1.233, "hooke-2")
        bonds2.put(bobj2)
    end_time = time.time()

    initTime = end_time - start_time

    polymer1 = StructureContainer(atoms1, bonds1)  # Complete structure 1
    polymer2 = StructureContainer(atoms2, bonds2)  # Complete structure 2
    del atoms1, atoms2
    print "\n Cleaning memory for initial objects \n"

    start_time = time.time()
    polymer1 += polymer2
    end_time = time.time()
    addTime = end_time - start_time

    start_time = time.time()
    polymer1.compressPtclIDs()
    end_time = time.time()
    compressTime = end_time - start_time

    return (numPtcls1, numPtcls2, initTime, addTime, compressTime)
Пример #5
0
def main():
    """
    This test shows how the setPtclPos method works to externally set all particle
    positions from a list
    """
    print "************************************************************************************"
    print " This test shows how the setPtclPos method works to externally set all particle "
    print " positions from a list"
    print "************************************************************************************ \n"

    p1 = Particle([0.2, 1.3, 33.0], "Si", 2.0, 1.23)
    p2 = Particle([5.0, 2.3, -22.1], "C", 1.0, 2.34)
    p3 = Particle([5.0, 2.3, -20.1], "C", 1.0, 2.34)
    p4 = Particle([0.0, 2.3, -20.1], "C", 1.0, 2.34)

    b1 = Bond(1, 2, 1.233, "hooke")
    b2 = Bond(2, 3, 0.500, "hooke")
    b3 = Bond(3, 4, 2.301, "hooke")
    b4 = Bond(1, 3, 0.828, "hooke")

    atoms1 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    atoms1.put(p4)

    bonds = BondContainer()
    bonds.put(b1)
    bonds.put(b2)
    bonds.put(b3)
    bonds.put(b4)

    del p1, p2, p3, p4, b1, b2, b3, b4
    polymer1 = StructureContainer(atoms1, bonds)
    del atoms1, bonds
    polymer1.setBoxLengths([[-3.0, 100], [-5, 23.0], [34.3, 100.1]])

    print "Initial state of structure before reset ", polymer1

    newPtclPos = [[1, 0.111, 0.222, 0.333], [2, 0.222, 0.333, 0.444],
                  [4, 0.444, 0.555, 0.666]]

    print "new positions = ", newPtclPos

    polymer1.setPtclPositions(newPtclPos)

    ptclPosList = polymer1.getPtclPositions()

    print "new positions from structure = ", ptclPosList
    print " "
    print "After position reset/get ", polymer1
def main():
    """
    This test shows how to save/dump/restore state of structureContainers using pickle
    """
    print "************************************************************************************"
    print " This test shows how to save/dump/restore state of structureContainers using pickle"
    print "************************************************************************************ \n"

    p1 = Particle([0.2, 1.3, 33.0], "Si", 2.0, 1.23)
    p2 = Particle([5.0, 2.3, -22.1], "C", 1.0, 2.34)
    p3 = Particle([5.0, 2.3, -20.1], "C", 1.0, 2.34)
    p4 = Particle([0.0, 2.3, -20.1], "C", 1.0, 2.34)

    b1 = Bond(1, 2, 1.233, "hooke")
    b2 = Bond(2, 3, 0.500, "hooke")
    b3 = Bond(3, 4, 2.301, "hooke")
    b4 = Bond(1, 3, 0.828, "hooke")

    atoms1 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    atoms1.put(p4)

    bonds = BondContainer()
    bonds.put(b1)
    bonds.put(b2)
    bonds.put(b3)
    bonds.put(b4)

    del p1, p2, p3, p4, b1, b2, b3, b4
    polymer1 = StructureContainer(atoms1, bonds)
    del atoms1, bonds
    polymer1.setBoxLengths([[-3.0, 100], [-5, 23.0], [34.3, 100.1]])

    print "Initial state of structure before dump ", polymer1

    print "-------------------------------------------------------------------------------- \n"

    polymer1.dump('polymer1')

    polymerNew = StructureContainer()
    polymerNew.restore('polymer1.pkl')

    print "After load from pickle \n"
    print polymerNew
    print "-------------------------------------------------------------------------------- \n"
def atoms_and_bonds_from_structure(structure, atom_types, bond_types):
    """
    Defines the atoms and bonds from the structure and given information from params.
    
    Args:
        structure (obj): A pymatgen structural object created from the transformed matrix structure, with forces included as site properties.
        atom_types (list(obj)): AtomType objects including atom_type_index (int), label (str), mass (float), charge (float), and core_shell (str).
        bond_types (list(obj)): BondType objects including bond_type_index (int) and label (str).

    Returns:
        atoms (list(obj)): Atom objects including atom_index (int), molecule_index (int), coords (np.array), forces (np.array), and atom_type (obj:AtomType).
        bonds (list(obj)): Bond objects including bond_index (int), atom_indices (list(int)), and bond_type (obj:BondType).
    """
    atoms = []
    bonds = []
    atom_types_dict = {}
    atom_types_dict = {at.label: at for at in atom_types}
    bond_types_dict = {}
    bond_types_dict = {bt.label: bt for bt in bond_types}
    atom_index = 0
    bond_index = 0
    molecule_index = 0
    for site in structure:
        molecule_index += 1
        if site.species_string in atom_types_dict:  # not core-shell atom
            atom_index += 1
            atom_type = atom_types_dict[site.species_string]
            atoms.append(
                Atom(atom_index=atom_index,
                     molecule_index=molecule_index,
                     coords=site.coords,
                     atom_forces=site.properties['forces'],
                     atom_type=atom_type))
        else:  # need to handle core + shell
            atom_index += 1
            atom_type = atom_types_dict[site.species_string + ' core']
            atoms.append(
                Atom(atom_index=atom_index,
                     molecule_index=molecule_index,
                     coords=site.coords,
                     atom_forces=site.properties['forces'],
                     atom_type=atom_type))
            atom_index += 1
            atom_type = atom_types_dict[site.species_string + ' shell']
            atoms.append(
                Atom(atom_index=atom_index,
                     molecule_index=molecule_index,
                     coords=site.coords,
                     atom_forces=np.array([0.0, 0.0, 0.0]),
                     atom_type=atom_type))
            bond_index += 1
            bond_type = bond_types_dict['{}-{} spring'.format(
                site.species_string, site.species_string)]
            bonds.append(
                Bond(bond_index=bond_index,
                     atom_indices=[atom_index - 1, atom_index],
                     bond_type=bond_type))
    return atoms, bonds
Пример #8
0
    def read_cply(self, cply_file, debug=False):
        """
        Read cply file
        """

        # Load periodic table
        pt = periodictable()

        read_lattice = False
        read_segment = False

        with open(cply_file) as f:
            for line in f:
                col = line.split()
                if (read_lattice):
                    self.latvec[lv_cnt][0] = float(col[0])
                    self.latvec[lv_cnt][1] = float(col[1])
                    self.latvec[lv_cnt][2] = float(col[2])
                    if (lv_cnt == 2):
                        read_lattice = False
                    lv_cnt += 1
                elif (read_segment):
                    if (debug):
                        print " Readin degment line ", col

                    if (str(col[0]) == 'unit'):
                        if (len(col) > 2):
                            error_line = "Each segment can only have 1 unit "
                            error_line += "\n {} in unit line will be ignored ".format(
                                str(col[2::]))
                            print error_line
                        segment_i['unit'] = col[1]
                    if (str(col[0]) == 'func'):
                        segment_i['func'] = col[1::]
                    if (str(col[0]) == 'end'):
                        read_segment = False

                elif (len(col) >= 4 and col[0] != "bond" and col[0] != "#"):

                    pt_i = Particle()
                    pt_i.type = str(col[0])
                    pt_i.position = [
                        float(col[1]),
                        float(col[2]),
                        float(col[3])
                    ]

                    add_dict = pt_i.tagsDict
                    el = pt.getelementWithSymbol(str(col[0]))
                    add_dict["symbol"] = str(col[0])
                    add_dict["number"] = el.number
                    add_dict["mass"] = el.mass

                    add_dict["cplytag"] = ""
                    add_dict["linkid"] = ""
                    add_dict["link"] = ""
                    pt_i.mass = el.mass
                    add_dict["chain"] = 1
                    add_dict["ring"] = 0
                    add_dict["residue"] = 1
                    add_dict["resname"] = "RES"
                    add_dict["qgroup"] = 1
                    add_dict["fftype"] = "??"
                    add_dict["label"] = el.symbol
                    add_dict["cov_radii"] = el.cov_radii
                    add_dict["vdw_radii"] = el.vdw_radii
                    add_dict["lmptype"] = -1
                    if (len(col) >= 14):
                        add_dict["label"] = str(col[4])
                        add_dict["fftype"] = str(col[5])
                        add_dict["mass"] = float(col[6])
                        pt_i.mass = float(col[6])
                        pt_i.charge = float(col[7])
                        add_dict["qgroup"] = int(col[8])
                        add_dict["ring"] = int(col[9])
                        add_dict["residue"] = int(col[10])
                        add_dict["resname"] = str(col[11])
                        add_dict["chain"] = int(col[12])
                        add_dict["cplytag"] = str(col[13])
                    elif (len(col) == 13):
                        add_dict["label"] = str(col[4])
                        add_dict["fftype"] = str(col[5])
                        add_dict["mass"] = float(col[6])
                        pt_i.mass = float(col[6])
                        pt_i.charge = float(col[7])
                        add_dict["qgroup"] = int(col[8])
                        add_dict["ring"] = int(col[9])
                        add_dict["residue"] = int(col[10])
                        add_dict["resname"] = str(col[11])
                        add_dict["chain"] = int(col[12])
                    elif (len(col) == 8):
                        add_dict["residue"] = int(col[5])
                        add_dict["resname"] = str(col[6])
                        add_dict["cplytag"] = str(col[7])
                    elif (len(col) == 7):
                        pt_i.charge = float(col[4])
                        add_dict["residue"] = int(col[5])
                        add_dict["resname"] = str(col[6])
                    elif (len(col) == 5):
                        add_dict["cplytag"] = str(col[4])

                    pt_i.setTagsDict(add_dict)
                    self.ptclC.put(pt_i)

                    # # # print "debug pt_i ",len(col),pt_i

                elif (len(col) >= 3):
                    if (col[0] == "bond"):
                        b_i = int(col[1])
                        b_j = int(col[2])
                        bnd = Bond(b_i, b_j)
                        #print "process_line bond line ",col
                        self.bondC.put(bnd)
                # Key word search
                if (len(col) > 0):
                    if (str(col[0]) == 'lattice'):
                        read_lattice = True
                        lv_cnt = 0
                    if (str(col[0]) == 'segment'):
                        read_segment = True
                        segment_i = {}  #segment(str(col[1]))
                        # segment_i = segment()
                        segment_i['tag'] = str(col[1])
                        segment_i['segment'] = {}
                        self.segments.append(segment_i)
        if (debug):
            print segments
            sys.exit("debug in read_cply is True ")
Пример #9
0
def main():
    
    """
    This test shows how to set up Structure container with Particle/Bond-Containers
    and shows how IDs changed in StructureContainer propagate to values set in BondContainer for its
    held particle ID values
    Illustrates how a substructure method can return subgroup
    """
    print "*****************************************************************************************************"
    print " This test shows how to set up Structure container with Particle/Bond-Containers \n"
    print " and shows how IDs changed in StructureContainer propagate to values set in BondContainer for its "
    print "    held particle ID values \n"
    print " Illustrates how a substructure method can return subgroup"
    print "************************************************************************************ \n"

    p1 = Particle( [0.2, 1.3,  33.0], "Si", 2.0, 1.23)
    p2 = Particle( [5.0, 2.3, -22.1], "C",  1.0, 2.34)
    p3 = Particle( [5.0, 2.3, -20.1], "C",  1.0, 2.34)
    p4 = Particle( [0.0, 2.3, -20.1], "C",  1.0, 2.34)
    p5 = Particle( [0.2, 1.3,  33.0], "Si", 2.0, 1.23)

    b1 = Bond( 5, 2, 1.233, "hooke")  # This setup mimics earlier state of test
    b2 = Bond( 2, 3, 0.500, "hooke")  # Still matches with diagram
    b3 = Bond( 3, 4, 2.301, "hooke")
    b4 = Bond( 5, 3, 0.828, "hooke")

    atoms1 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    atoms1.put(p4)
    atoms1.put(p5)

    del atoms1[1]  # This is to mimic state of container for an older test

    bonds = BondContainer()
    bonds.put(b1)
    bonds.put(b2)
    bonds.put(b3)
    bonds.put(b4)

    del p1, p2, p3, p4, b1, b2, b3, b4
    polymer1 = StructureContainer(atoms1, bonds)
    del atoms1, bonds

    print "********************************************************** \n"
    print polymer1
    print diagramAfter
    print "********************************************************** \n"

    print "-------------------------------------------------------------------------------- \n"

    print "********************************************************** \n"
    print "Testing polymer1.getSubStructure([5,2])"
    print "   currently ID's are reassigned in substructure \n"
    subpolymer = polymer1.getSubStructure([5,2])
    print subpolymer
    print diagramAfter
    print "********************************************************** \n"

    print "********************************************************** \n"
    print "polymer1 Struture after returning sub-structure"
    print polymer1
    print "********************************************************** \n"

    print "-------------------------------------------------------------------------------- \n"

    print "********************************************************** \n"
    print "Testing polymer1.getSubStructure([2,3,4])"
    print "   currently ID's are reassigned in substructure \n"
    subpolymer = polymer1.getSubStructure([2,3,4])
    print subpolymer
    print diagramAfter
    print "********************************************************** \n"
def main():
    """
    This shows operations on empty StructureContainer objects for 'robustness'
    """
    print "************************************************************************************"
    print " This shows operations on empty StructureContainer objects for 'robustness'"
    print "************************************************************************************ \n"

    atoms1 = ParticleContainer()
    bonds1 = BondContainer()

    p1 = Particle([0.2, 1.3, 33.0], "Si", 2.0, 1.23)
    p2 = Particle([5.0, 2.3, -22.1], "C", 1.0, 2.34)
    p3 = Particle([5.0, 2.3, -20.1], "C", 1.0, 2.34)
    b1 = Bond(1, 2, 1.233, "hooke")
    b2 = Bond(2, 3, 0.500, "hooke")

    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    bonds1.put(b1)
    bonds1.put(b2)

    atoms2 = ParticleContainer()
    bonds2 = BondContainer()

    polymer1 = StructureContainer(atoms1, bonds1)  # Non-empty structure 1
    polymer2 = StructureContainer(atoms2, bonds2)  # Empty     structure 2

    # ------------------------------------------------------------------------------------------------------------------------

    print "Non-empty container", polymer1
    print "Empty container", polymer2

    print "Testing empty dump"
    polymer2.dump("empty")

    print "Testing empty compressPtclIDs"
    polymer2.compressPtclIDs()

    print "Testing empty getSubStructure"
    subStruc = polymer2.getSubStructure([])
    print "subStruc = ", subStruc

    print "Testing empty getPtclPositions"
    posList = polymer2.getPtclPositions()
    print "posList = ", posList

    print "------------------------------------------------------------------------------------ \n"

    print "Testing struc add --> non-empty (polymer1) += empty (polymer2)"
    polymer1 += polymer2
    print "polymer1 = ", polymer1
    print "------------------------------------------------------------------------------------ \n"
    print "polymer2 = ", polymer2

    print "------------------------------------------------------------------------------------ \n"

    print "Testing struc add --> empty (polymer2) += non-empty (polymer1)"
    polymer2 += polymer1
    print "polymer2 = ", polymer2
    print "------------------------------------------------------------------------------------ \n"
    print "polymer1 = ", polymer1

    print "------------------------------------------------------------------------------------ \n"

    print "Testing empty getSubStructure with non-zero id list (should return ERROR)"
    polymer3 = StructureContainer()
    subStruc = polymer3.getSubStructure([1, 2])
    print "subStruc = ", subStruc
def main():
    """
    Illustrates how a substructure method returns subgroup with ONLY particle container included
    This is for speed considerations
    """
    print "**********************************************************************************************"
    print "Illustrates how a substructure method returns subgroup with ONLY particle container included"
    print "This is for speed considerations"
    print "**********************************************************************************************\n"

    p1 = Particle([1.1, 1.1, 1.1], "Si", 2.0, 1.23)
    p2 = Particle([2.2, 2.2, 2.2], "Si", 1.0, 2.34)
    p3 = Particle([3.3, 3.3, 3.3], "Si", 1.0, 2.34)
    p4 = Particle([4.4, 4.4, 4.4], "Si", 1.0, 2.34)
    p5 = Particle([5.5, 5.5, 5.5], "C", 1.0, 2.34)  # 1
    p6 = Particle([6.6, 6.6, 6.6], "C", 1.0, 2.34)  # 2
    p7 = Particle([7.7, 7.7, 7.7], "C", 1.0, 2.34)  # 3
    p8 = Particle([8.8, 8.8, 8.8], "C", 1.0, 2.34)  # 4

    b1 = Bond(1, 2, 1.11, "hooke")
    b2 = Bond(2, 3, 2.22, "hooke")
    b3 = Bond(3, 4, 3.33, "hooke")
    b4 = Bond(4, 5, 4.44, "hooke")
    b5 = Bond(5, 6, 5.55, "hooke")
    b6 = Bond(6, 7, 6.66, "hooke")
    b7 = Bond(7, 8, 7.77, "hooke")

    a1 = Angle(1, 2, 3, 1.11, "harmonic")
    a2 = Angle(2, 3, 4, 2.22, "harmonic")
    a3 = Angle(3, 4, 5, 3.33, "harmonic")
    a4 = Angle(4, 5, 6, 4.44, "harmonic")
    a5 = Angle(5, 6, 7, 5.55, "harmonic")
    a6 = Angle(6, 7, 8, 6.66, "harmonic")

    d1 = Dihedral(1, 2, 3, 4, 1.11, "stiff")
    d2 = Dihedral(2, 3, 4, 5, 2.22, "stiff")
    d3 = Dihedral(3, 4, 5, 6, 3.33, "stiff")
    d4 = Dihedral(4, 5, 6, 7, 4.44, "stiff")
    d5 = Dihedral(5, 6, 7, 8, 5.55, "stiff")

    atoms1 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    atoms1.put(p4)
    atoms1.put(p5)
    atoms1.put(p6)
    atoms1.put(p7)
    atoms1.put(p8)

    bonds = BondContainer()
    bonds.put(b1)
    bonds.put(b2)
    bonds.put(b3)
    bonds.put(b4)
    bonds.put(b5)
    bonds.put(b6)
    bonds.put(b7)

    angles = AngleContainer()
    angles.put(a1)
    angles.put(a2)
    angles.put(a3)
    angles.put(a4)
    angles.put(a5)
    angles.put(a6)

    dihedrals = DihedralContainer()
    dihedrals.put(d1)
    dihedrals.put(d2)
    dihedrals.put(d3)
    dihedrals.put(d4)
    dihedrals.put(d5)

    del p1, p2, p3, p4, p5, p6, p7, p8
    del b1, b2, b3, b4, b5, b6, b7
    del a1, a2, a3, a4, a5, a6
    del d1, d2, d3, d4, d5

    polymer1 = StructureContainer(atoms1, bonds, angles, dihedrals)
    del atoms1, bonds, angles, dihedrals

    print "********************************************************** \n"
    print "polymer1 Structure before returning sub-structure"
    print polymer1
    print "********************************************************** \n"

    print "-------------------------------------------------------------------------------- \n"

    print "********************************************************** \n"
    print "Testing polymer1.getSubParticleContainer([2,3,4])"
    print "   currently ID's are reassigned in substructure \n"
    subPtclC = polymer1.getSubStructure([2, 3, 4], particlesOnly=True)
    print subPtclC
    print "********************************************************** \n"
def main():
    """
    This test shows various operators within Angle and AngleContainer classes.
    Shows memory management structure and access methods
    """

    p1 = Particle([1.1, 1.1, 1.1], "Si", 2.0, 1.23)
    p2 = Particle([2.2, 2.2, 2.2], "Si", 1.0, 2.34)
    p3 = Particle([3.3, 3.3, 3.3], "Si", 1.0, 2.34)
    #
    p4 = Particle([4.4, 4.4, 4.4], "C", 1.0, 2.34)  # ptcl 1
    p5 = Particle([5.5, 5.5, 5.5], "C", 1.0, 2.34)  # ptcl 2
    p6 = Particle([6.6, 6.6, 6.6], "C", 1.0, 2.34)  # ptcl 3

    b1 = Bond(1, 2, 1.11, "hooke")
    b2 = Bond(2, 3, 2.22, "hooke")
    #
    b3 = Bond(1, 2, 3.33, "hooke")
    b4 = Bond(2, 3, 4.44, "hooke")

    a1 = Angle(1, 2, 3, 1.11, "harmonic")
    #
    a2 = Angle(1, 2, 3, 2.22, "harmonic")

    atoms1 = ParticleContainer()
    atoms2 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    #
    atoms2.put(p4)
    atoms2.put(p5)
    atoms2.put(p6)

    bonds1 = BondContainer()
    bonds2 = BondContainer()
    bonds1.put(b1)
    bonds1.put(b2)
    bonds2.put(b3)
    bonds2.put(b4)

    angles1 = AngleContainer()
    angles2 = AngleContainer()
    angles1.put(a1)
    angles2.put(a2)

    del p1, p2, p3, p4, p5, p6, b1, b2, b3, b4, a1, a2
    print "\n Cleaning memory for initial objects \n"

    print "angles1 container"
    print angles1

    print " "
    print "angles2 container"
    print angles2

    print "Testing 'in' operator (1 in angles1)"
    if (1 in angles1):
        print "angles1 contains gid 1"
    else:
        print "key not found in angles1"

    print "Testing 'in' operator (5 in angles1)"
    if (5 in angles1):
        print "angles1 contains gid 5"
    else:
        print "key not found in angles1"

    print " "
    angles1 += angles2
    print "Will print the new angles1 after adding angles1 += angles2"
    print angles1

    print "Check for pre-existing angle"
    if angles1.hasAngle([3, 2, 1]):
        print "angle 1--2--3 exists"
    else:
        print "angle 1--2--3 does NOT exists"

    print "Check for pre-existing angle"
    if angles1.hasAngle([2, 3, 1]):
        print "angle 2--3--1 exists"
    else:
        print "angle 2--3--1 does NOT exists"
def main():
    """
    This test shows structureContainer functionality with dihedrals included
    """
    print "************************************************************************************"
    print " This test shows structureContainer functionality with dihedrals included"
    print "************************************************************************************ \n"

    p1 = Particle([1.1, 1.1, 1.1], "Si", 2.0, 1.23)
    p2 = Particle([2.2, 2.2, 2.2], "Si", 1.0, 2.34)
    p3 = Particle([3.3, 3.3, 3.3], "Si", 1.0, 2.34)
    p4 = Particle([4.4, 4.4, 4.4], "Si", 1.0, 2.34)
    #
    p5 = Particle([5.5, 5.5, 5.5], "C", 1.0, 2.34)  # 1
    p6 = Particle([6.6, 6.6, 6.6], "C", 1.0, 2.34)  # 2
    p7 = Particle([7.7, 7.7, 7.7], "C", 1.0, 2.34)  # 3
    p8 = Particle([8.8, 8.8, 8.8], "C", 1.0, 2.34)  # 4

    b1 = Bond(1, 2, 1.11, "hooke")
    b2 = Bond(2, 3, 2.22, "hooke")
    b3 = Bond(3, 4, 3.33, "hooke")
    #
    b4 = Bond(1, 2, 4.44, "hooke")
    b5 = Bond(2, 3, 5.55, "hooke")
    b6 = Bond(3, 4, 6.66, "hooke")

    a1 = Angle(1, 2, 3, 1.11, "harmonic")
    #
    a2 = Angle(1, 2, 3, 2.22, "harmonic")

    d1 = Dihedral(1, 2, 3, 4, 1.11, "stiff")
    #
    d2 = Dihedral(1, 2, 3, 4, 2.22, "stiff")

    atoms1 = ParticleContainer()
    atoms2 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    atoms1.put(p4)
    #
    atoms2.put(p5)
    atoms2.put(p6)
    atoms2.put(p7)
    atoms2.put(p8)

    bonds1 = BondContainer()
    bonds2 = BondContainer()
    bonds1.put(b1)
    bonds1.put(b2)
    bonds1.put(b3)
    #
    bonds2.put(b4)
    bonds2.put(b5)
    bonds2.put(b6)

    angles1 = AngleContainer()
    angles2 = AngleContainer()
    angles1.put(a1)
    angles2.put(a2)

    dih1 = DihedralContainer()
    dih2 = DihedralContainer()
    dih1.put(d1)
    dih2.put(d2)

    polymer1 = StructureContainer(atoms1, bonds1, angles1, dih1)
    polymer2 = StructureContainer(atoms2, bonds2, angles2, dih2)

    del p1, p2, p3, p4, p5, p6, p7, p8
    del b1, b2, b3, b4, b5, b6, a1, a2, d1, d2
    del atoms1, atoms2, bonds1, bonds2, angles1, angles2, dih1, dih2
    print "\n Cleaning memory for initial objects \n"

    print "-------------------- Initial structures --------------------"
    print "polymer1 = ", polymer1
    print "polymer2 = ", polymer2
    print " "

    print "-------------- After adding  (polymer1 += polymer2) ----------------"
    polymer2 += polymer1
    print "polymer2 = ", polymer2
Пример #14
0
def read_lmpdata( strucC , parmC , data_file):
    """
    Read Lammps data file


    Arguments:
        strucC     (StructureContainer)
        parmC      (ParameterContainer)
        data_file  (str) data file
    
    ReturnS:
        strucC     (StructureContainer)
        parmC      (ParameterContainer)
    
    """
        
    debug = 0
    verbose = True

    set_chain_numbers = True

    if( not set_chain_numbers ):
        print " Warning not reading in chain numbers!!! "

    # Load periodic table 
    pt = periodictable()
    

    F = open(data_file , 'r' )
    lines = F.readlines()
    F.close()
    
    #
    # Read in data header with number of parameters 
    #
    for line in lines:
        col = line.split()
        if ( len(col) >=2 ):
            # Read in number of each topolgical component  
            if( col[1] == "atoms" ):
                n_atoms = int( col[0] )
            elif( col[1] == "bonds" ):
                n_bonds = int( col[0] )
            elif( col[1] == "angles" ):
                n_angles = int( col[0] )
            elif( col[1] == "dihedrals" ):
                n_dihedrals = int( col[0] )
            elif( col[1] == "impropers" ):
                n_impropers = int( col[0] )

        if ( len(col) >= 3 ):
            # Read in number of each parameter type 
            if( col[1] == "atom" and   col[2] == "types" ):
                n_atypes = int( col[0] )
            elif( col[1] == "bond" and   col[2] == "types"  ):
                n_btypes = int( col[0] )
            elif( col[1] == "angle" and   col[2] == "types"  ):
                n_angtypes = int( col[0] )
            elif( col[1] == "dihedral" and   col[2] == "types"  ):
                n_dtypes = int( col[0] )
            elif( col[1] == "improper" and   col[2] == "types"  ):
                n_imptypes = int( col[0] )
                
        # Read in box size    
        if ( len(col) >= 4 ):
            if( col[2]  == "xlo"  and col[3]  == "xhi"  ):
                strucC.latvec[0][0] = float( col[1] ) - float( col[0] ) 
            if( col[2]  == "ylo"  and col[3]  == "yhi"  ):
                strucC.latvec[1][1] = float( col[1] ) - float( col[0] ) 
            if( col[2]  == "zlo"  and col[3]  == "zhi"  ):
                strucC.latvec[2][2] = float( col[1] ) - float( col[0] )

    # Prind debug
    if( verbose ):
        print " atoms ",n_atoms
        print " n_bonds ",n_bonds
        print " n_angles ",n_angles
        print " n_dihedrals ",n_dihedrals
        print " n_impropers ",n_impropers
        print ""
        print "n_atom_types",n_atypes
        print "n_bond_types",n_btypes
        print "n_angle_types",n_angtypes
        print "n_dihedral_types",n_dtypes
        print "n_imp_dihedral_types",n_imptypes



    # Check to see if a previous read has occured
    pt_overwrite = False
    if( len(strucC.ptclC) > 0 ):
        pt_overwrite = True
    # Check of conistent number of atoms
    if( pt_overwrite ):
        if(  len(strucC.ptclC)  != n_atoms):
            print "  %d atoms in passed structure "%(len(strucC.ptclC))
            print "  %d atoms in data file "%(n_atoms)
            sys.exit(" Inconsistent number of atoms " )

    else:
        #
        # Initialize particle container
        #
        for pid_i in range(n_atoms):
            pt_i = Particle( )
            strucC.ptclC.put(pt_i)

 
    bonds_overwrite = False
    if( len(strucC.bondC) > 0 ):
        bonds_overwrite = True

        if(  len(strucC.bondC)  != n_bonds):
            print "  %d bonds in passed structure "%(len(strucC.bondC))
            print "  %d bonds in data file "%(n_bonds)
            sys.exit(" Inconsistent number of bonds " )
    
    angles_overwrite = False
    if( len(strucC.angleC) > 0 ):
        angles_overwrite = True
        if(  len(strucC.angleC)  != n_angles):
            print "  %d angles in passed structure "%(len(strucC.angleC))
            print "  %d angles in data file "%(n_angles)
            sys.exit(" Inconsistent number of angles " )
    
    dih_overwrite = False
    if( len(strucC.dihC) > 0 ):
        dih_overwrite = True
        if(  len(strucC.dihC)  != n_dihedrals):
            print "  %d dihedrals in passed structure "%(len(strucC.dihC))
            print "  %d dihedrals in data file "%(n_dihedrals)
            sys.exit(" Inconsistent number of dihedrals " )
              
    imp_overwrite = False
    if( len(strucC.impC) > 0 ):
        imp_overwrite = True
        if(  len(strucC.impC)  != n_impropers):
            print "  %d impropers in passed structure "%(len(strucC.impC))
            print "  %d impropers in data file "%(n_impropers)
            sys.exit(" Inconsistent number of impropers " )          
            
    #
    # Intialize
    #   - read in boolean to off
    #
    read_Masses = 0
    read_Pair = 0
    read_Bond_coeff = 0
    read_Angle_coeff = 0
    read_Dihedral_coeff = 0
    read_Improper_coeff = 0
    
    read_Atoms = 0
    read_Bonds = 0
    read_Angles = 0
    read_Dihedrals = 0
    read_Impropers = 0
    
    #   - lists as indecise can be out of order in data file
    ATYPE_REF = n_atypes*[""]
    ATYPE_MASS = np.zeros(n_atypes)
    ATYPE_EP = np.zeros(n_atypes)
    ATYPE_SIG = np.zeros(n_atypes)
    
    BTYPE_REF = n_btypes*[2*[""]]
    BONDTYPE_R0 = np.zeros(n_btypes)
    BONDTYPE_K = np.zeros(n_btypes)
    
    ANGTYPE_REF = n_angtypes*[3*[""]]
    ANGLETYPE_R0 = np.zeros(n_angtypes)
    ANGLETYPE_K = np.zeros(n_angtypes)
    
    DTYPE_REF = n_dtypes*[4*[""]]
    DIHTYPE_C = np.zeros((n_dtypes,4))
    DIHTYPE_F = np.zeros(n_dtypes)
    DIHTYPE_K = np.zeros(n_dtypes)
    DIHTYPE_PN = np.zeros(n_dtypes)
    DIHTYPE_PHASE = np.zeros(n_dtypes)

    IMPTYPE_REF = n_imptypes*[4*[""]]
    IMPTYPE_F = np.zeros(n_imptypes)
    IMPTYPE_E0 = np.zeros(n_imptypes)
    IMPTYPE_K = np.zeros(n_imptypes)

    MOLNUMB = n_atoms*[0]
    ATYPE_IND  = n_atoms*[0]
    CHARGES  = np.zeros(n_atoms)
    R = n_atoms*[np.zeros(3)]
    ATYPE  = n_atoms*[""]
    
    BONDS = n_bonds*[[0,0]]
    BTYPE_IND = n_bonds*[0]
    
    ANGLES = n_angles*[[0,0,0]]
    ANGTYPE_IND = n_angles*[0]
    
    DIH = n_dihedrals*[[0,0,0,0]]
    DTYPE_IND = n_dihedrals*[0]


    

    #
    # Check if values exist and need to be updated or don't and need to be created 
    #
    ljtyp_update = False
    ljtyp_cnt = 0 
    if( len(parmC.ljtypC) > 0 ):
        print " LJ types will be updated "
        ljtyp_update = True
    btyp_update = False
    btyp_cnt = 0 
    if( len(parmC.btypC) > 0 ):
        print " Bond types will be updated "
        btyp_update = True
    atyp_update = False
    atyp_cnt = 0 
    if( len(parmC.atypC) > 0 ):
        print " Angle types will be updated "
        atyp_update = True
    dtyp_update = False
    dtyp_cnt = 0 
    if( len(parmC.dtypC) > 0 ):
        print " Dihedral types will be updated "
        dtyp_update = True
    imptyp_update = False
    imptyp_cnt = 0 
    if( len(parmC.imptypC) > 0 ):
        print " Improper dihedrals types will be updated "
        imptyp_update = True
    #
    # Read in data parameters 
    #
    
    for line in lines:
        col = line.split()
        if( read_Masses and  len(col) >= 2 ):
            
            cnt_Masses += 1
            ind = int(col[0]) - 1
            ATYPE_MASS[ind] = float(col[1])
                
            if( len(col) >= 4 ):
                ATYPE_REF[ind] = col[3]
                ptype1 = col[3]
            else:
                ATYPE_REF[ind] = "??"
                ptype1 = "??"
            
            mass_i = float(col[1])

        
            if( ljtyp_update ):
                ljtyp_cnt = ind  + 1
                if( ljtyp_cnt > len(parmC.ljtypC) ):
                    print "Mass index %d larger then length of previously read ljtypC %d"%(ind,len(parmC.ljtypC))
                ljtyp_i = parmC.ljtypC[ljtyp_cnt]
                ljtyp_i.setmass(mass_i)
            else:
                ljtyp_i = ljtype(ptype1)
                ljtyp_i.setmass(mass_i)
                parmC.ljtypC.put(ljtyp_i)
            
            # Turn of mass read
            if(cnt_Masses ==  n_atypes ):
                read_Masses = 0

        if( read_Pair and  len(col) >= 3 ):
            cnt_Pair += 1
            
            ind = int(col[0]) - 1
            ATYPE_EP[ind] = float(col[1])
            ATYPE_SIG[ind] = float(col[2])

            epsilon = float(col[1])
            sigma = float(col[2])
            ljtyp_ind = int(col[0])

            ljtyp_i = parmC.ljtypC[ljtyp_ind]
            ljtyp_i.setparam(epsilon,sigma)
            # Turn pair parameter read off 
            if(cnt_Pair >=  n_atypes ):
                read_Pair = 0

        
        if( read_Bond_coeff and  len(col) >= 3 ):
            cnt_Bond_coeff += 1
            #AT_i = int(col[0])
            #AT_j = int(col[1])
            b_ind = int( col[0]) - 1
            if( b_ind > n_btypes ):
                error_line = " Error in data file index of bond parameter exceeds number of bond parameters specified with bond types "
                sys.exit(error_line)
                
            BTYPE_REF[b_ind][0] = "??"
            BTYPE_REF[b_ind][1] = "??"
            BONDTYPE_K[b_ind] = float(col[1])
            BONDTYPE_R0[b_ind] = float(col[2])

            ptype1 = "??"
            ptype2 = "??"
            lmpindx = int( col[0])
            kb = float(col[1]) 
            r0 = float(col[2]) 
            btype = "harmonic"
            g_type = 1

            if( btyp_update ):
                btyp_cnt = b_ind + 1 
                btyp_i = parmC.btypC[btyp_cnt]
                btyp_i.setharmonic(r0,kb)
                btyp_i.set_g_indx(g_type)
                btyp_i.set_lmpindx(lmpindx)
            else:
                btyp_i = bondtype(ptype1,ptype2,btype)
                btyp_i.setharmonic(r0,kb)
                btyp_i.set_g_indx(g_type)
                btyp_i.set_lmpindx(lmpindx)
                parmC.btypC.put(btyp_i)
            
            if( cnt_Bond_coeff >=  n_btypes ):
                read_Bond_coeff = 0
                
        
        if( read_Angle_coeff and  len(col) >= 3 ):
            cnt_Angle_coeff += 1
            #AT_i = int(col[0])
            #AT_j = int(col[1])
            a_ind = int( col[0]) - 1
            if( a_ind > n_angtypes ):
                print sys.exit(" Error in data file index of angle parameter exceeds number of angle parameters specified with angle types ")
                
            ANGTYPE_REF[a_ind][0] = "??"
            ANGTYPE_REF[a_ind][1] = "??"
            ANGTYPE_REF[a_ind][2] = "??"
            ANGLETYPE_K[a_ind] = float(col[1])
            ANGLETYPE_R0[a_ind] = float(col[2])

            ptype1 = "??"
            ptype2 = "??"
            ptype3 = "??"
            lmpindx = int( col[0])
            theta0 = float( col[2] )        # degrees 
            kb =  float( col[1] ) 
            atype = "harmonic"
            gfunc_type = 1


            if( atyp_update ):
                atyp_cnt = a_ind + 1 
                atyp_i = parmC.atypC[atyp_cnt]
                atyp_i.set_g_indx(gfunc_type)
                atyp_i.set_lmpindx(lmpindx)
                atyp_i.setharmonic(theta0,kb)
            else:
                atyp_i = angletype(ptype1,ptype2,ptype3,atype)
                atyp_i.set_g_indx(gfunc_type)
                atyp_i.set_lmpindx(lmpindx)
                atyp_i.setharmonic(theta0,kb)
                parmC.atypC.put(atyp_i)
            
            if( cnt_Angle_coeff >=  n_angtypes ):
                read_Angle_coeff = 0
                
        
        if( read_Dihedral_coeff and  len(col) >= 3 ):
            cnt_Dihedral_coeff += 1
            #AT_i = int(col[0])
            #AT_j = int(col[1])
            d_ind = int( col[0]) - 1
            
            if( debug): print " reading dih type ",d_ind," cnt ",cnt_Dihedral_coeff," of ",n_dtypes
            
            if( d_ind > n_dtypes ):
                error_line =  " Error in data file index of dihedral parameter %d exceeds number of dihedral parameters %d "%(d_ind , n_dtypes)
                error_line += " specified with dihedral types "
                print sys.exit(error_line)
                
            DTYPE_REF[d_ind][0] = "??"
            DTYPE_REF[d_ind][1] = "??"
            DTYPE_REF[d_ind][2] = "??"
            DTYPE_REF[d_ind][3] = "??"
            
            # Assume OPLS dihedral type
            DIHTYPE_F[d_ind] = 3
            DIHTYPE_C[d_ind][0] = float(col[1])
            DIHTYPE_C[d_ind][1] = float(col[2])
            DIHTYPE_C[d_ind][2] = float(col[3])
            DIHTYPE_C[d_ind][3] = float(col[4])

            ptype1 = "??"
            ptype2 = "??"
            ptype3 = "??"
            ptype4 = "??"
            # Set parameters according to type 
            gfunc_type = 3 
            dtype = "opls"

            lmpindx = int( col[0] )
            k1 =  float( col[1] )
            k2 =  float( col[2] ) 
            k3 =  float( col[3] ) 
            k4 =  float( col[4] )


            if( dtyp_update ):
                dtyp_cnt = d_ind + 1 
                dtyp_i = parmC.dtypC[dtyp_cnt]
                dtyp_i.set_g_indx(gfunc_type)
                dtyp_i.set_lmpindx(lmpindx)
                dtyp_i.setopls(k1,k2,k3,k4)
            else:
                dtyp_i = dihtype(ptype1,ptype2,ptype3,ptype4,dtype)
                dtyp_i.set_g_indx(gfunc_type)
                dtyp_i.set_lmpindx(lmpindx)
                dtyp_i.setopls(k1,k2,k3,k4)
                parmC.dtypC.put(dtyp_i)
            
            if( cnt_Dihedral_coeff >=  n_dtypes ):
                read_Dihedral_coeff = 0
                
        
        if( read_Improper_coeff and  len(col) >= 3 ):
            cnt_Improper_coeff += 1
            #AT_i = int(col[0])
            #AT_j = int(col[1])
            imp_ind = int( col[0]) - 1
            
            if( debug): print " reading imp dih type ",imp_ind," cnt ",cnt_Improper_coeff," of ",n_imptypes
            
            if( imp_ind > n_imptypes ):
                error_line =  " Error in data file index of improper parameter %d exceeds number of improper parameters %d "%(imp_ind , n_imptypes)
                error_line += " specified with dihedral types "
                print sys.exit(error_line)
                
            IMPTYPE_REF[imp_ind][0] = "??"
            IMPTYPE_REF[imp_ind][1] = "??"
            IMPTYPE_REF[imp_ind][2] = "??"
            IMPTYPE_REF[imp_ind][3] = "??"
            
            # Assume OPLS dihedral type
            IMPTYPE_F[imp_ind] = 2
            KE = float(col[1])
            Eo = float(col[2])
            IMPTYPE_E0[imp_ind] = Eo
            IMPTYPE_K[imp_ind] = KE

            ptype1 = "??"
            ptype2 = "??"
            ptype3 = "??"
            ptype4 = "??"
            # Set parameters according to type 
            g_indx = 2
            dtype = "improper"

            lmpindx = int( col[0] )


            if( imptyp_update ):
                imptyp_cnt = imp_ind + 1 
                imptyp_i = parmC.imptypC[imptyp_cnt]
                imptyp_i.set_g_indx(g_indx)
                imptyp_i.setimp(Eo,KE)
                imptyp_i.set_lmpindx(lmpindx)                
            else:
                imptyp_i = imptype(ptype1,ptype2,ptype3,ptype4,dtype)
                imptyp_i.set_g_indx(g_indx)
                imptyp_i.setimp(Eo,KE)
                imptyp_i.set_lmpindx(lmpindx)
                parmC.imptypC.put(imptyp_i)
            
            if( cnt_Improper_coeff >=  n_imptypes ):
                read_Improper_coeff = 0
            
        if( read_Atoms and len(col) >= 7 ):
            cnt_Atoms += 1
            ind = int( col[0]) - 1
            if( ind > n_atoms ):
                print sys.exit(" Error in data file index of atoms exceeds number of atoms specified with atoms ")
            
            chain_i = int(col[1]) 
            lmptype_i = int(col[2]) #- 1
            indx = int(col[2]) - 1
            q_i = float(col[3])
            m_i = ATYPE_MASS[indx]
            fftype_i = ATYPE_REF[indx]
            el = pt.getelementWithMass(m_i)
            
            if( el.symbol == "VS" ):
                el.symbol = ATYPE_l[atom_indx].strip()
                fftype_i = "VS"
                m_i = 0.0 

            # HACK !!
            if( ATYPE_MASS[indx] == 9.0  ):
                el.symbol = "LP"
                fftype_i = "LP"
                m_i = 0.0
            
            r_i =  [ float(col[4]),float(col[5]),float(col[6])] 
            type_i = str(lmptype_i)

            #tagsD = {"chain":chain_i,"symbol":el.symbol,"number":el.number,"mass":el.mass,"cov_radii":el.cov_radii,"vdw_radii":el.vdw_radii}
            #if( pt_overwrite ):
            pt_i = strucC.ptclC[ind+1]
            pt_i.position = r_i

            update_coord = True
            if( not update_coord ):

                pt_i.type = el.symbol
                pt_i.charge = q_i
                pt_i.mass = m_i

                add_dict = pt_i.tagsDict
                # Set properties read in data file 
                if( set_chain_numbers ): add_dict["chain"] = chain_i
                add_dict["symbol"] = el.symbol
                add_dict["number"] = el.number
                add_dict["mass"] = el.mass
                add_dict["cov_radii"] = el.cov_radii
                add_dict["vdw_radii"] = el.vdw_radii
                add_dict["lmptype"] = lmptype_i
                add_dict["fftype"] = fftype_i 
                # 
                add_dict["ffmass"] = ATYPE_MASS[indx]
                add_dict["residue"] = chain_i
                add_dict["qgroup"] = chain_i
                add_dict["resname"] = "MOLR"
                add_dict["ring"] = 0
                add_dict["label"] = add_dict["symbol"]
                pt_i.setTagsDict(add_dict)

            
            if( cnt_Atoms >=  n_atoms ):
                read_Atoms = 0

        if(read_Bonds and len(col) >= 4 ):
            cnt_Bonds += 1
            ind = int( col[0]) - 1

            if( ind > n_bonds ):
                print sys.exit(" Error in data file index of bonds exceeds number of bonds specified with bonds ")
                
            BTYPE_IND[ind] = int(col[1] ) - 1
            BONDS[ind] = [int(col[2]) - 1 , int(col[3]) - 1 ]
            i_o = int(col[2])
            j_o = int(col[3])

            if( bonds_overwrite ):
                bondObj = strucC.bondC[cnt_Bonds]
                bondObj.pgid1 = i_o
                bondObj.pgid2 = j_o
                bondObj.set_lmpindx(int(col[1] ))
            else:
                bondObj = Bond( i_o, j_o )
                bondObj.set_lmpindx(int(col[1] ))
                strucC.bondC.put(bondObj)
                
            if( cnt_Bonds >=  n_bonds ):
                read_Bonds = 0

        if(read_Angles and len(col) >= 5 ):
            cnt_Angles += 1
            ind = int( col[0]) - 1
            ANGTYPE_IND[ind] = int(col[1] ) - 1
            ANGLES[ind] = [int(col[2]) - 1, int(col[3]) - 1, int(col[4]) - 1 ]
            
            k_o = int(col[2])
            i_o = int(col[3])
            j_o = int(col[4])
            
            if( cnt_Angles >=  n_angles ):
                read_Angles = 0

            if( angles_overwrite ):
                angleObj = strucC.angleC[cnt_Angles]
                angleObj.pgid1 = k_o
                angleObj.pgid2 = i_o
                angleObj.pgid3 = j_o
                angleObj.set_lmpindx(int(col[1] ))
            else:
                angleObj = Angle( k_o,i_o, j_o )
                angleObj.set_lmpindx(int(col[1] ))
                strucC.angleC.put(angleObj)
            
                
            
        if(read_Dihedrals and len(col) >= 6 ):
            cnt_Dihedrals += 1
            ind = int( col[0]) - 1
            
            DTYPE_IND[ind] = int(col[1] ) - 1
            DIH[ind] = [int(col[2]) - 1,int(col[3]) - 1, int(col[4]) - 1,int(col[5]) - 1]

            k_o = int(col[2])
            i_o = int(col[3])
            j_o = int(col[4])
            l_o = int(col[5])
            
            if( dih_overwrite ):
                dObj = strucC.dihC[cnt_Dihedrals]
                dObj.pgid1 = k_o
                dObj.pgid2 = i_o
                dObj.pgid3 = j_o
                dObj.pgid4 = l_o
                dObj.set_lmpindx(int(col[1] ))
            else:
                dObj = Dihedral( k_o,i_o, j_o,l_o )
                dObj.set_lmpindx(int(col[1] ))
                strucC.dihC.put(dObj)
                
            if( cnt_Dihedrals >=  n_dihedrals ):
                read_Dihedrals = 0
                
            
        if(read_Impropers and len(col) >= 2 ):
            cnt_Impropers += 1
            ind = int( col[0]) - 1
            
            k_o = int(col[2])
            i_o = int(col[3])
            j_o = int(col[4])
            l_o = int(col[5])
            
            if( imp_overwrite ):
                impObj = strucC.impC[cnt_Impropers]
                impObj.pgid1 = k_o
                impObj.pgid2 = i_o
                impObj.pgid3 = j_o
                impObj.pgid4 = l_o
                impObj.set_lmpindx(int(col[1] ))
                impObj.set_type("improper")
            else:
                impObj = Improper( k_o,i_o, j_o,l_o )
                impObj.set_lmpindx(int(col[1] ))
                impObj.set_type("improper")
                strucC.impC.put(impObj)
                

            if( cnt_Impropers >=  n_impropers ):
                read_Impropers = 0

        if ( len(col) >= 1  ):
            if( col[0] == "Masses" ):
                read_Masses = 1
                cnt_Masses = 0
                
            if( col[0] == "Atoms" ):
                read_Atoms = 1
                cnt_Atoms = 0
                
            if( col[0] == "Bonds" ):
                read_Bonds = 1
                cnt_Bonds = 0
                
            if( col[0] == "Angles" ):
                read_Angles = 1
                cnt_Angles  = 0
                
            if( col[0] == "Dihedrals" ):
                read_Dihedrals = 1
                cnt_Dihedrals = 0
                
            if( col[0] == "Impropers" ):
                read_Impropers = 1
                cnt_Impropers = 0
                
        if ( len(col) >= 2 ):
            if( col[0] == "Pair" and col[1] == "Coeffs" ):
                read_Pair = 1
                cnt_Pair = 0
            if( col[0] == "Bond" and col[1] == "Coeffs" ):
                read_Bond_coeff = 1
                cnt_Bond_coeff = 0
            if( col[0] == "Angle" and col[1] == "Coeffs" ):
                read_Angle_coeff  = 1
                cnt_Angle_coeff = 0
            if( col[0] == "Dihedral" and col[1] == "Coeffs" ):
                read_Dihedral_coeff  = 1
                cnt_Dihedral_coeff  = 0
                
            if( col[0] == "Improper" and col[1] == "Coeffs" ):
                read_Improper_coeff  = 1
                cnt_Improper_coeff  = 0
                            
        #    cnt_Bonds += 1
        #    ind = int( col[0]) - 1
        #    BTYPE_IND[ind] = int(col[1] ) - 1
        #    BONDS[ind][0] = int(col[2])
        #    if( cnt_Bonds >=  n_atoms ):
        #        read_Bonds = 0
        #        
            

                #
    if( ljtyp_update ):
        if( ljtyp_cnt != len(parmC.ljtypC) ):
            print " Number of LJ types read in %d does not match previously read %d "%(ljtyp_cnt,len(parmC.ljtypC))

    if( debug):
        for ind in range(len(ATYPE_MASS)):
            print ind+1,ATYPE_MASS[ind]
            
        for ind in range(len(ATYPE_EP)):
            print ind+1,ATYPE_EP[ind],ATYPE_SIG[ind]
        
        for ind in range(n_btypes):
            print ind+1,BONDTYPE_R0[ind],BONDTYPE_K[ind]
                
        for ind in range(n_angtypes):
            print ind+1,ANGLETYPE_R0[ind],ANGLETYPE_K[ind]
        
        for ind in range(n_dtypes):
            print ind+1,DIHTYPE_C[ind]
        
    debug =0
    
    if( debug):
        for ind in range(len(BONDS)):
            print ind+1,BONDS[ind]
            
    if(debug):
        sys.exit("debug 1 ")
    #
    #      
    return (strucC,parmC)
Пример #15
0
def read_lmpdata(strucC, parmC, data_file):
    """
    Read Lammps data file


    Arguments:
        strucC     (StructureContainer)
        parmC      (ParameterContainer)
        data_file  (str) data file
    
    ReturnS:
        strucC     (StructureContainer)
        parmC      (ParameterContainer)
    
    """

    debug = 0
    verbose = True

    set_chain_numbers = True

    if (not set_chain_numbers):
        print " Warning not reading in chain numbers!!! "

    # Load periodic table
    pt = periodictable()

    F = open(data_file, 'r')
    lines = F.readlines()
    F.close()

    #
    # Read in data header with number of parameters
    #
    for line in lines:
        col = line.split()
        if (len(col) >= 2):
            # Read in number of each topolgical component
            if (col[1] == "atoms"):
                n_atoms = int(col[0])
            elif (col[1] == "bonds"):
                n_bonds = int(col[0])
            elif (col[1] == "angles"):
                n_angles = int(col[0])
            elif (col[1] == "dihedrals"):
                n_dihedrals = int(col[0])
            elif (col[1] == "impropers"):
                n_impropers = int(col[0])

        if (len(col) >= 3):
            # Read in number of each parameter type
            if (col[1] == "atom" and col[2] == "types"):
                n_atypes = int(col[0])
            elif (col[1] == "bond" and col[2] == "types"):
                n_btypes = int(col[0])
            elif (col[1] == "angle" and col[2] == "types"):
                n_angtypes = int(col[0])
            elif (col[1] == "dihedral" and col[2] == "types"):
                n_dtypes = int(col[0])
            elif (col[1] == "improper" and col[2] == "types"):
                n_imptypes = int(col[0])

        # Read in box size
        if (len(col) >= 4):
            if (col[2] == "xlo" and col[3] == "xhi"):
                strucC.latvec[0][0] = float(col[1]) - float(col[0])
            if (col[2] == "ylo" and col[3] == "yhi"):
                strucC.latvec[1][1] = float(col[1]) - float(col[0])
            if (col[2] == "zlo" and col[3] == "zhi"):
                strucC.latvec[2][2] = float(col[1]) - float(col[0])

    # Prind debug
    if (verbose):
        print " atoms ", n_atoms
        print " n_bonds ", n_bonds
        print " n_angles ", n_angles
        print " n_dihedrals ", n_dihedrals
        print " n_impropers ", n_impropers
        print ""
        print "n_atom_types", n_atypes
        print "n_bond_types", n_btypes
        print "n_angle_types", n_angtypes
        print "n_dihedral_types", n_dtypes
        print "n_imp_dihedral_types", n_imptypes

    # Check to see if a previous read has occured
    pt_overwrite = False
    if (len(strucC.ptclC) > 0):
        pt_overwrite = True
    # Check of conistent number of atoms
    if (pt_overwrite):
        if (len(strucC.ptclC) != n_atoms):
            print "  %d atoms in passed structure " % (len(strucC.ptclC))
            print "  %d atoms in data file " % (n_atoms)
            sys.exit(" Inconsistent number of atoms ")

    else:
        #
        # Initialize particle container
        #
        for pid_i in range(n_atoms):
            pt_i = Particle()
            strucC.ptclC.put(pt_i)

    bonds_overwrite = False
    if (len(strucC.bondC) > 0):
        bonds_overwrite = True

        if (len(strucC.bondC) != n_bonds):
            print "  %d bonds in passed structure " % (len(strucC.bondC))
            print "  %d bonds in data file " % (n_bonds)
            sys.exit(" Inconsistent number of bonds ")

    angles_overwrite = False
    if (len(strucC.angleC) > 0):
        angles_overwrite = True
        if (len(strucC.angleC) != n_angles):
            print "  %d angles in passed structure " % (len(strucC.angleC))
            print "  %d angles in data file " % (n_angles)
            sys.exit(" Inconsistent number of angles ")

    dih_overwrite = False
    if (len(strucC.dihC) > 0):
        dih_overwrite = True
        if (len(strucC.dihC) != n_dihedrals):
            print "  %d dihedrals in passed structure " % (len(strucC.dihC))
            print "  %d dihedrals in data file " % (n_dihedrals)
            sys.exit(" Inconsistent number of dihedrals ")

    imp_overwrite = False
    if (len(strucC.impC) > 0):
        imp_overwrite = True
        if (len(strucC.impC) != n_impropers):
            print "  %d impropers in passed structure " % (len(strucC.impC))
            print "  %d impropers in data file " % (n_impropers)
            sys.exit(" Inconsistent number of impropers ")

    #
    # Intialize
    #   - read in boolean to off
    #
    read_Masses = 0
    read_Pair = 0
    read_Bond_coeff = 0
    read_Angle_coeff = 0
    read_Dihedral_coeff = 0
    read_Improper_coeff = 0

    read_Atoms = 0
    read_Bonds = 0
    read_Angles = 0
    read_Dihedrals = 0
    read_Impropers = 0

    #   - lists as indecise can be out of order in data file
    ATYPE_REF = n_atypes * [""]
    ATYPE_MASS = np.zeros(n_atypes)
    ATYPE_EP = np.zeros(n_atypes)
    ATYPE_SIG = np.zeros(n_atypes)

    BTYPE_REF = n_btypes * [2 * [""]]
    BONDTYPE_R0 = np.zeros(n_btypes)
    BONDTYPE_K = np.zeros(n_btypes)

    ANGTYPE_REF = n_angtypes * [3 * [""]]
    ANGLETYPE_R0 = np.zeros(n_angtypes)
    ANGLETYPE_K = np.zeros(n_angtypes)

    DTYPE_REF = n_dtypes * [4 * [""]]
    DIHTYPE_C = np.zeros((n_dtypes, 4))
    DIHTYPE_F = np.zeros(n_dtypes)
    DIHTYPE_K = np.zeros(n_dtypes)
    DIHTYPE_PN = np.zeros(n_dtypes)
    DIHTYPE_PHASE = np.zeros(n_dtypes)

    IMPTYPE_REF = n_imptypes * [4 * [""]]
    IMPTYPE_F = np.zeros(n_imptypes)
    IMPTYPE_E0 = np.zeros(n_imptypes)
    IMPTYPE_K = np.zeros(n_imptypes)

    MOLNUMB = n_atoms * [0]
    ATYPE_IND = n_atoms * [0]
    CHARGES = np.zeros(n_atoms)
    R = n_atoms * [np.zeros(3)]
    ATYPE = n_atoms * [""]

    BONDS = n_bonds * [[0, 0]]
    BTYPE_IND = n_bonds * [0]

    ANGLES = n_angles * [[0, 0, 0]]
    ANGTYPE_IND = n_angles * [0]

    DIH = n_dihedrals * [[0, 0, 0, 0]]
    DTYPE_IND = n_dihedrals * [0]

    #
    # Check if values exist and need to be updated or don't and need to be created
    #
    ljtyp_update = False
    ljtyp_cnt = 0
    if (len(parmC.ljtypC) > 0):
        print " LJ types will be updated "
        ljtyp_update = True
    btyp_update = False
    btyp_cnt = 0
    if (len(parmC.btypC) > 0):
        print " Bond types will be updated "
        btyp_update = True
    atyp_update = False
    atyp_cnt = 0
    if (len(parmC.atypC) > 0):
        print " Angle types will be updated "
        atyp_update = True
    dtyp_update = False
    dtyp_cnt = 0
    if (len(parmC.dtypC) > 0):
        print " Dihedral types will be updated "
        dtyp_update = True
    imptyp_update = False
    imptyp_cnt = 0
    if (len(parmC.imptypC) > 0):
        print " Improper dihedrals types will be updated "
        imptyp_update = True
    #
    # Read in data parameters
    #

    for line in lines:
        col = line.split()
        if (read_Masses and len(col) >= 2):

            cnt_Masses += 1
            ind = int(col[0]) - 1
            ATYPE_MASS[ind] = float(col[1])

            if (len(col) >= 4):
                ATYPE_REF[ind] = col[3]
                ptype1 = col[3]
            else:
                ATYPE_REF[ind] = "??"
                ptype1 = "??"

            mass_i = float(col[1])

            if (ljtyp_update):
                ljtyp_cnt = ind + 1
                if (ljtyp_cnt > len(parmC.ljtypC)):
                    print "Mass index %d larger then length of previously read ljtypC %d" % (
                        ind, len(parmC.ljtypC))
                ljtyp_i = parmC.ljtypC[ljtyp_cnt]
                ljtyp_i.setmass(mass_i)
            else:
                ljtyp_i = ljtype(ptype1)
                ljtyp_i.setmass(mass_i)
                parmC.ljtypC.put(ljtyp_i)

            # Turn of mass read
            if (cnt_Masses == n_atypes):
                read_Masses = 0

        if (read_Pair and len(col) >= 3):
            cnt_Pair += 1

            ind = int(col[0]) - 1
            ATYPE_EP[ind] = float(col[1])
            ATYPE_SIG[ind] = float(col[2])

            epsilon = float(col[1])
            sigma = float(col[2])
            ljtyp_ind = int(col[0])

            ljtyp_i = parmC.ljtypC[ljtyp_ind]
            ljtyp_i.setparam(epsilon, sigma)
            # Turn pair parameter read off
            if (cnt_Pair >= n_atypes):
                read_Pair = 0

        if (read_Bond_coeff and len(col) >= 3):
            cnt_Bond_coeff += 1
            #AT_i = int(col[0])
            #AT_j = int(col[1])
            b_ind = int(col[0]) - 1
            if (b_ind > n_btypes):
                error_line = " Error in data file index of bond parameter exceeds number of bond parameters specified with bond types "
                sys.exit(error_line)

            BTYPE_REF[b_ind][0] = "??"
            BTYPE_REF[b_ind][1] = "??"
            BONDTYPE_K[b_ind] = float(col[1])
            BONDTYPE_R0[b_ind] = float(col[2])

            ptype1 = "??"
            ptype2 = "??"
            lmpindx = int(col[0])
            kb = float(col[1])
            r0 = float(col[2])
            btype = "harmonic"
            g_type = 1

            if (btyp_update):
                btyp_cnt = b_ind + 1
                btyp_i = parmC.btypC[btyp_cnt]
                btyp_i.setharmonic(r0, kb)
                btyp_i.set_g_indx(g_type)
                btyp_i.set_lmpindx(lmpindx)
            else:
                btyp_i = bondtype(ptype1, ptype2, btype)
                btyp_i.setharmonic(r0, kb)
                btyp_i.set_g_indx(g_type)
                btyp_i.set_lmpindx(lmpindx)
                parmC.btypC.put(btyp_i)

            if (cnt_Bond_coeff >= n_btypes):
                read_Bond_coeff = 0

        if (read_Angle_coeff and len(col) >= 3):
            cnt_Angle_coeff += 1
            #AT_i = int(col[0])
            #AT_j = int(col[1])
            a_ind = int(col[0]) - 1
            if (a_ind > n_angtypes):
                print sys.exit(
                    " Error in data file index of angle parameter exceeds number of angle parameters specified with angle types "
                )

            ANGTYPE_REF[a_ind][0] = "??"
            ANGTYPE_REF[a_ind][1] = "??"
            ANGTYPE_REF[a_ind][2] = "??"
            ANGLETYPE_K[a_ind] = float(col[1])
            ANGLETYPE_R0[a_ind] = float(col[2])

            ptype1 = "??"
            ptype2 = "??"
            ptype3 = "??"
            lmpindx = int(col[0])
            theta0 = float(col[2])  # degrees
            kb = float(col[1])
            atype = "harmonic"
            gfunc_type = 1

            if (atyp_update):
                atyp_cnt = a_ind + 1
                atyp_i = parmC.atypC[atyp_cnt]
                atyp_i.set_g_indx(gfunc_type)
                atyp_i.set_lmpindx(lmpindx)
                atyp_i.setharmonic(theta0, kb)
            else:
                atyp_i = angletype(ptype1, ptype2, ptype3, atype)
                atyp_i.set_g_indx(gfunc_type)
                atyp_i.set_lmpindx(lmpindx)
                atyp_i.setharmonic(theta0, kb)
                parmC.atypC.put(atyp_i)

            if (cnt_Angle_coeff >= n_angtypes):
                read_Angle_coeff = 0

        if (read_Dihedral_coeff and len(col) >= 3):
            cnt_Dihedral_coeff += 1
            #AT_i = int(col[0])
            #AT_j = int(col[1])
            d_ind = int(col[0]) - 1

            if (debug):
                print " reading dih type ", d_ind, " cnt ", cnt_Dihedral_coeff, " of ", n_dtypes

            if (d_ind > n_dtypes):
                error_line = " Error in data file index of dihedral parameter %d exceeds number of dihedral parameters %d " % (
                    d_ind, n_dtypes)
                error_line += " specified with dihedral types "
                print sys.exit(error_line)

            DTYPE_REF[d_ind][0] = "??"
            DTYPE_REF[d_ind][1] = "??"
            DTYPE_REF[d_ind][2] = "??"
            DTYPE_REF[d_ind][3] = "??"

            # Assume OPLS dihedral type
            DIHTYPE_F[d_ind] = 3
            DIHTYPE_C[d_ind][0] = float(col[1])
            DIHTYPE_C[d_ind][1] = float(col[2])
            DIHTYPE_C[d_ind][2] = float(col[3])
            DIHTYPE_C[d_ind][3] = float(col[4])

            ptype1 = "??"
            ptype2 = "??"
            ptype3 = "??"
            ptype4 = "??"
            # Set parameters according to type
            gfunc_type = 3
            dtype = "opls"

            lmpindx = int(col[0])
            k1 = float(col[1])
            k2 = float(col[2])
            k3 = float(col[3])
            k4 = float(col[4])

            if (dtyp_update):
                dtyp_cnt = d_ind + 1
                dtyp_i = parmC.dtypC[dtyp_cnt]
                dtyp_i.set_g_indx(gfunc_type)
                dtyp_i.set_lmpindx(lmpindx)
                dtyp_i.setopls(k1, k2, k3, k4)
            else:
                dtyp_i = dihtype(ptype1, ptype2, ptype3, ptype4, dtype)
                dtyp_i.set_g_indx(gfunc_type)
                dtyp_i.set_lmpindx(lmpindx)
                dtyp_i.setopls(k1, k2, k3, k4)
                parmC.dtypC.put(dtyp_i)

            if (cnt_Dihedral_coeff >= n_dtypes):
                read_Dihedral_coeff = 0

        if (read_Improper_coeff and len(col) >= 3):
            cnt_Improper_coeff += 1
            #AT_i = int(col[0])
            #AT_j = int(col[1])
            imp_ind = int(col[0]) - 1

            if (debug):
                print " reading imp dih type ", imp_ind, " cnt ", cnt_Improper_coeff, " of ", n_imptypes

            if (imp_ind > n_imptypes):
                error_line = " Error in data file index of improper parameter %d exceeds number of improper parameters %d " % (
                    imp_ind, n_imptypes)
                error_line += " specified with dihedral types "
                print sys.exit(error_line)

            IMPTYPE_REF[imp_ind][0] = "??"
            IMPTYPE_REF[imp_ind][1] = "??"
            IMPTYPE_REF[imp_ind][2] = "??"
            IMPTYPE_REF[imp_ind][3] = "??"

            # Assume OPLS dihedral type
            IMPTYPE_F[imp_ind] = 2
            KE = float(col[1])
            Eo = float(col[2])
            IMPTYPE_E0[imp_ind] = Eo
            IMPTYPE_K[imp_ind] = KE

            ptype1 = "??"
            ptype2 = "??"
            ptype3 = "??"
            ptype4 = "??"
            # Set parameters according to type
            g_indx = 2
            dtype = "improper"

            lmpindx = int(col[0])

            if (imptyp_update):
                imptyp_cnt = imp_ind + 1
                imptyp_i = parmC.imptypC[imptyp_cnt]
                imptyp_i.set_g_indx(g_indx)
                imptyp_i.setimp(Eo, KE)
                imptyp_i.set_lmpindx(lmpindx)
            else:
                imptyp_i = imptype(ptype1, ptype2, ptype3, ptype4, dtype)
                imptyp_i.set_g_indx(g_indx)
                imptyp_i.setimp(Eo, KE)
                imptyp_i.set_lmpindx(lmpindx)
                parmC.imptypC.put(imptyp_i)

            if (cnt_Improper_coeff >= n_imptypes):
                read_Improper_coeff = 0

        if (read_Atoms and len(col) >= 7):
            cnt_Atoms += 1
            ind = int(col[0]) - 1
            if (ind > n_atoms):
                print sys.exit(
                    " Error in data file index of atoms exceeds number of atoms specified with atoms "
                )

            chain_i = int(col[1])
            lmptype_i = int(col[2])  #- 1
            indx = int(col[2]) - 1
            q_i = float(col[3])
            m_i = ATYPE_MASS[indx]
            fftype_i = ATYPE_REF[indx]
            el = pt.getelementWithMass(m_i)

            if (el.symbol == "VS"):
                el.symbol = ATYPE_l[atom_indx].strip()
                fftype_i = "VS"
                m_i = 0.0

            # HACK !!
            if (ATYPE_MASS[indx] == 9.0):
                el.symbol = "LP"
                fftype_i = "LP"
                m_i = 0.0

            r_i = [float(col[4]), float(col[5]), float(col[6])]
            type_i = str(lmptype_i)

            #tagsD = {"chain":chain_i,"symbol":el.symbol,"number":el.number,"mass":el.mass,"cov_radii":el.cov_radii,"vdw_radii":el.vdw_radii}
            #if( pt_overwrite ):
            pt_i = strucC.ptclC[ind + 1]
            pt_i.position = r_i
            pt_i.charge = q_i
            pt_i.mass = m_i

            add_dict = pt_i.tagsDict
            # Set properties read in data file
            if (set_chain_numbers): add_dict["chain"] = chain_i
            add_dict["symbol"] = el.symbol
            add_dict["number"] = el.number
            add_dict["mass"] = el.mass
            add_dict["cov_radii"] = el.cov_radii
            add_dict["vdw_radii"] = el.vdw_radii
            add_dict["lmptype"] = lmptype_i
            add_dict["fftype"] = fftype_i
            #
            add_dict["ffmass"] = ATYPE_MASS[indx]
            pt_i.setTagsDict(add_dict)

            if (cnt_Atoms >= n_atoms):
                read_Atoms = 0

        if (read_Bonds and len(col) >= 4):
            cnt_Bonds += 1
            ind = int(col[0]) - 1

            if (ind > n_bonds):
                print sys.exit(
                    " Error in data file index of bonds exceeds number of bonds specified with bonds "
                )

            BTYPE_IND[ind] = int(col[1]) - 1
            BONDS[ind] = [int(col[2]) - 1, int(col[3]) - 1]
            i_o = int(col[2])
            j_o = int(col[3])

            if (bonds_overwrite):
                bondObj = strucC.bondC[cnt_Bonds]
                bondObj.pgid1 = i_o
                bondObj.pgid2 = j_o
                bondObj.set_lmpindx(int(col[1]))
            else:
                bondObj = Bond(i_o, j_o)
                bondObj.set_lmpindx(int(col[1]))
                strucC.bondC.put(bondObj)

            if (cnt_Bonds >= n_bonds):
                read_Bonds = 0

        if (read_Angles and len(col) >= 5):
            cnt_Angles += 1
            ind = int(col[0]) - 1
            ANGTYPE_IND[ind] = int(col[1]) - 1
            ANGLES[ind] = [int(col[2]) - 1, int(col[3]) - 1, int(col[4]) - 1]

            k_o = int(col[2])
            i_o = int(col[3])
            j_o = int(col[4])

            if (cnt_Angles >= n_angles):
                read_Angles = 0

            if (angles_overwrite):
                angleObj = strucC.angleC[cnt_Angles]
                angleObj.pgid1 = k_o
                angleObj.pgid2 = i_o
                angleObj.pgid3 = j_o
                angleObj.set_lmpindx(int(col[1]))
            else:
                angleObj = Angle(k_o, i_o, j_o)
                angleObj.set_lmpindx(int(col[1]))
                strucC.angleC.put(angleObj)

        if (read_Dihedrals and len(col) >= 6):
            cnt_Dihedrals += 1
            ind = int(col[0]) - 1

            DTYPE_IND[ind] = int(col[1]) - 1
            DIH[ind] = [
                int(col[2]) - 1,
                int(col[3]) - 1,
                int(col[4]) - 1,
                int(col[5]) - 1
            ]

            k_o = int(col[2])
            i_o = int(col[3])
            j_o = int(col[4])
            l_o = int(col[5])

            if (dih_overwrite):
                dObj = strucC.dihC[cnt_Dihedrals]
                dObj.pgid1 = k_o
                dObj.pgid2 = i_o
                dObj.pgid3 = j_o
                dObj.pgid4 = l_o
                dObj.set_lmpindx(int(col[1]))
            else:
                dObj = Dihedral(k_o, i_o, j_o, l_o)
                dObj.set_lmpindx(int(col[1]))
                strucC.dihC.put(dObj)

            if (cnt_Dihedrals >= n_dihedrals):
                read_Dihedrals = 0

        if (read_Impropers and len(col) >= 2):
            cnt_Impropers += 1
            ind = int(col[0]) - 1

            k_o = int(col[2])
            i_o = int(col[3])
            j_o = int(col[4])
            l_o = int(col[5])

            if (imp_overwrite):
                impObj = strucC.impC[cnt_Impropers]
                impObj.pgid1 = k_o
                impObj.pgid2 = i_o
                impObj.pgid3 = j_o
                impObj.pgid4 = l_o
                impObj.set_lmpindx(int(col[1]))
                impObj.set_type("improper")
            else:
                impObj = Improper(k_o, i_o, j_o, l_o)
                impObj.set_lmpindx(int(col[1]))
                impObj.set_type("improper")
                strucC.impC.put(impObj)

            if (cnt_Impropers >= n_impropers):
                read_Impropers = 0

        if (len(col) >= 1):
            if (col[0] == "Masses"):
                read_Masses = 1
                cnt_Masses = 0

            if (col[0] == "Atoms"):
                read_Atoms = 1
                cnt_Atoms = 0

            if (col[0] == "Bonds"):
                read_Bonds = 1
                cnt_Bonds = 0

            if (col[0] == "Angles"):
                read_Angles = 1
                cnt_Angles = 0

            if (col[0] == "Dihedrals"):
                read_Dihedrals = 1
                cnt_Dihedrals = 0

            if (col[0] == "Impropers"):
                read_Impropers = 1
                cnt_Impropers = 0

        if (len(col) >= 2):
            if (col[0] == "Pair" and col[1] == "Coeffs"):
                read_Pair = 1
                cnt_Pair = 0
            if (col[0] == "Bond" and col[1] == "Coeffs"):
                read_Bond_coeff = 1
                cnt_Bond_coeff = 0
            if (col[0] == "Angle" and col[1] == "Coeffs"):
                read_Angle_coeff = 1
                cnt_Angle_coeff = 0
            if (col[0] == "Dihedral" and col[1] == "Coeffs"):
                read_Dihedral_coeff = 1
                cnt_Dihedral_coeff = 0

            if (col[0] == "Improper" and col[1] == "Coeffs"):
                read_Improper_coeff = 1
                cnt_Improper_coeff = 0

        #    cnt_Bonds += 1
        #    ind = int( col[0]) - 1
        #    BTYPE_IND[ind] = int(col[1] ) - 1
        #    BONDS[ind][0] = int(col[2])
        #    if( cnt_Bonds >=  n_atoms ):
        #        read_Bonds = 0
        #

        #
    if (ljtyp_update):
        if (ljtyp_cnt != len(parmC.ljtypC)):
            print " Number of LJ types read in %d does not match previously read %d " % (
                ljtyp_cnt, len(parmC.ljtypC))

    if (debug):
        for ind in range(len(ATYPE_MASS)):
            print ind + 1, ATYPE_MASS[ind]

        for ind in range(len(ATYPE_EP)):
            print ind + 1, ATYPE_EP[ind], ATYPE_SIG[ind]

        for ind in range(n_btypes):
            print ind + 1, BONDTYPE_R0[ind], BONDTYPE_K[ind]

        for ind in range(n_angtypes):
            print ind + 1, ANGLETYPE_R0[ind], ANGLETYPE_K[ind]

        for ind in range(n_dtypes):
            print ind + 1, DIHTYPE_C[ind]

    debug = 0

    if (debug):
        for ind in range(len(BONDS)):
            print ind + 1, BONDS[ind]

    if (debug):
        sys.exit("debug 1 ")
    #
    #
    return (strucC, parmC)
def main():
    """
    This test shows various operators within Dihedral and DihedralContainer classes
    Also shows memory management structure and access methods
    """

    print "************************************************************************************"
    print " This test shows various operators within Dihedral and DihedralContainer classes    "
    print " Also shows memory management structure and access methods                          "
    print "************************************************************************************ \n"

    p1 = Particle([1.1, 1.1, 1.1], "Si", 2.0, 1.23)
    p2 = Particle([2.2, 2.2, 2.2], "Si", 1.0, 2.34)
    p3 = Particle([3.3, 3.3, 3.3], "Si", 1.0, 2.34)
    p4 = Particle([4.4, 4.4, 4.4], "Si", 1.0, 2.34)
    #
    p5 = Particle([5.5, 5.5, 5.5], "C", 1.0, 2.34)
    p6 = Particle([6.6, 6.6, 6.6], "C", 1.0, 2.34)
    p7 = Particle([7.7, 7.7, 7.7], "C", 1.0, 2.34)
    p8 = Particle([8.8, 8.8, 8.8], "C", 1.0, 2.34)

    b1 = Bond(1, 2, 1.11, "hooke")
    b2 = Bond(2, 3, 2.22, "hooke")
    #
    b3 = Bond(1, 2, 3.33, "hooke")
    b4 = Bond(1, 2, 4.44, "hooke")

    d1 = Dihedral(1, 2, 3, 4, 1.11, "stiff")
    #
    d2 = Dihedral(1, 2, 3, 4, 2.22, "stiff")

    atoms1 = ParticleContainer()
    atoms2 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    #
    atoms2.put(p4)
    atoms2.put(p5)
    atoms2.put(p6)

    bonds1 = BondContainer()
    bonds2 = BondContainer()
    bonds1.put(b1)
    bonds1.put(b2)
    bonds2.put(b3)
    bonds2.put(b4)

    dihedrals1 = DihedralContainer()
    dihedrals2 = DihedralContainer()
    dihedrals1.put(d1)
    dihedrals2.put(d2)

    del p1, p2, p3, p4, p5, p6, b1, b2, b3, b4, d1, d2
    print "\n Cleaning memory for initial objects \n"

    print "dihedral1 container"
    print dihedrals1

    print " "
    print "dihedral2 container"
    print dihedrals2

    print "Testing 'in' operator (1 in dihedrals1)"
    if (1 in dihedrals1):
        print "dihedrals1 contains gid 1"
    else:
        print "key not found in dihedrals1"

    print "Testing 'in' operator (5 in dihedrals1)"
    if (5 in dihedrals1):
        print "dihedrals1 contains gid 5"
    else:
        print "key not found in dihedrals1"

    print " "
    dihedrals1 += dihedrals2
    print "Will print the new dihedrals1 after adding dihedrals1 += dihedrals2"
    print dihedrals1

    print "Check for pre-existing dihedral"
    if dihedrals1.hasDihedral([4, 3, 2, 1]):
        print "dihedral 1--2--3--4 exists"
    else:
        print "dihedral 1--2--3--4 does NOT exists"

    print "Check for pre-existing dihedral"
    if dihedrals1.hasDihedral([2, 3, 1, 4]):
        print "dihedral 2--3--1--4 exists"
    else:
        print "dihedral 2--3--1--4 does NOT exists"
Пример #17
0
def main():
    """
    This test shows compressing IDs when structureContainer has angles included
    """

    p1 = Particle([1.1, 1.1, 1.1], "Si", 2.0, 1.23)
    p2 = Particle([2.2, 2.2, 2.2], "Si", 1.0, 2.34)
    p3 = Particle([3.3, 3.3, 3.3], "Si", 1.0, 2.34)
    p4 = Particle([0.0, 0.0, 0.0], "Si", 1.0, 2.34)
    #
    p5 = Particle([4.4, 4.4, 4.4], "C", 1.0, 2.34)  # 1
    p6 = Particle([5.5, 5.5, 5.5], "C", 1.0, 2.34)  # 2
    p7 = Particle([6.6, 6.6, 6.6], "C", 1.0, 2.34)  # 3

    b1 = Bond(1, 3, 1.11, "hooke")
    b2 = Bond(3, 4, 2.22, "hooke")
    #
    b3 = Bond(1, 2, 3.33, "hooke")
    b4 = Bond(2, 3, 4.44, "hooke")

    a1 = Angle(1, 3, 4, 1.11, "harmonic")
    #
    a2 = Angle(1, 2, 3, 2.22, "harmonic")

    atoms1 = ParticleContainer()
    atoms2 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    atoms1.put(p4)
    #
    atoms2.put(p5)
    atoms2.put(p6)
    atoms2.put(p7)

    del atoms1[2]  # remove 2nd particle so ID's are non-consecutive

    bonds1 = BondContainer()
    bonds2 = BondContainer()
    bonds1.put(b1)
    bonds1.put(b2)
    bonds2.put(b3)
    bonds2.put(b4)

    angles1 = AngleContainer()
    angles2 = AngleContainer()
    angles1.put(a1)
    angles2.put(a2)

    polymer1 = StructureContainer(atoms1, bonds1, angles1)
    polymer2 = StructureContainer(atoms2, bonds2, angles2)

    del p1, p2, p3, p4, p5, p6, b1, b2, b3, b4, a1, a2
    del atoms1, atoms2, bonds1, bonds2, angles1, angles2
    print "\n Cleaning memory for initial objects \n"

    print "-------------------- Initial structures --------------------"
    print "polymer1 = ", polymer1
    print "polymer2 = ", polymer2
    print " "

    print "-------------- After adding  (polymer2 += polymer1) ----------------"
    polymer2 += polymer1
    print "polymer2 = ", polymer2

    polymer2.compressPtclIDs()

    print "-------------------- After compressing --------------------"
    print "polymer2 = ", polymer2
Пример #18
0
    def __iadd__(self, other):
        """
        'Magic' method to implement the '+=' operator (eg struc1 += struc2)
        
        Compare global IDs of particles and reassign globalIDs for particle
        container using the max ID between the two lists. Tracks these changes
        for all other (bond, angle, dihedral) containers that reference particleIDs
        """

        self.verbose = False

        # Empty container checks
        if len(other) == 0:  # If struc2 is empty (has no particles)
            return self  #   simply return unchanged current container
        if len(self
               ) == 0:  # If struc1 (this struc) is empty (has no particles)
            return copy.deepcopy(other)  #    full copy other and return

        #
        #  Special method for connecting building blocks
        #
        # Count number of connectors
        connect_along_bond = False
        if (self.type != "mol" and other.type != "mol"):
            # IF not complete molecules that will just be added
            #   connect along bonds
            connect_along_bond = True

            self.cnt_connectors()
            other.cnt_connectors()
            if (self.verbose):
                log_line = "\n building block 1 type {}  ".format(self.type)
                log_line += "\n   building block 1 has {} connections ".format(
                    self.connect_cnt)
                log_line += "\n   building block 1 has {} func connections ".format(
                    self.func_connect_cnt)
                log_line += "\n building block 2 type {}  ".format(other.type)
                log_line += "\n   building block 2 has {} connections ".format(
                    other.connect_cnt)
                log_line += "\n   building block 2 has {} func connections ".format(
                    other.func_connect_cnt)
                print log_line

            self.connect_id = "term_"
            self.cap_id = "termcap_"
            other.connect_id = "term_"
            other.cap_id = "termcap_"
            if (self.type == "unit" and other.type == "unit"):
                self.connectionpoint = 1
                other.connectionpoint = 0
                new_termpoint = 1
            elif (self.type == "term" and other.type == "unit"):
                # elif( self.connect_cnt == 1 and other.connect_cnt  == 2 ):
                self.connectionpoint = 0
                other.connectionpoint = 0
                new_termpoint = 0
            elif (self.type == "term" and other.type == "term"):
                #        elif( self.connect_cnt == 1 and other.connect_cnt  == 1 ):
                self.connectionpoint = 0
                other.connectionpoint = 0
                new_termpoint = -1
            elif (self.type == "unit" and other.type == "term"):
                #elif( self.connect_cnt == 2 and other.connect_cnt  == 1 ):
                self.connectionpoint = 1
                other.connectionpoint = 0
                new_termpoint = -1
            elif (self.type == "unit" and other.type == "func"):
                #elif( self.connect_cnt == 2 and other.connect_cnt  == 1 ):
                self.connect_id = "func_"
                self.cap_id = "funccap_"
                # this is zero since each functional possition will be removed once a functional group is added
                self.connectionpoint = 0
                other.connect_id = "term_"
                other.connectionpoint = 0
                new_termpoint = -1
            else:
                error_line = " Unknow connection configuration {} - {}  \n".format(
                    self.type, other.type)
                error_line += " building block 1 has {} connnections \n".format(
                    self.connect_cnt)
                error_line += " building block 2 has {} connnections \n".format(
                    other.connect_cnt)
                sys.exit(error_line)

            if (self.verbose):
                log_line = "\n Adding connection along bond "
                log_line += "\n  Connecting block 2 {} at point {} ".format(
                    other.connect_id, other.connectionpoint)
                log_line += "\n  to  block 1 {} at point {} ".format(
                    self.connect_id, self.connectionpoint)
                print log_line

            # Shift second buildingblock so first connector is bonded to the second connector of  first buildingblock
            if (self.verbose): print " Shift  along bonds "
            self.align_termbond(self.connectionpoint, origin="term")
            other.align_termbond(other.connectionpoint, origin="termcap")

            if (self.verbose): print " Find terminal atoms  "
            self.get_connectors(self.connectionpoint)
            other.get_connectors(other.connectionpoint)
            bond_length = np.array([
                self.ptclC[self.pid_term].radii +
                other.ptclC[other.pid_term].radii, 0.0, 0.0
            ])

            # Shift second building block to have the correct bond length
            other.ptclC.shift(
                (bond_length -
                 1.0 * np.array(other.ptclC[other.pid_term].position)))

            # Delete termcaps
            self.bondC.deletepid(self.pid_termcap)
            other.bondC.deletepid(other.pid_termcap)
            del self.ptclC[self.pid_termcap]
            del other.ptclC[other.pid_termcap]

            # Reset term tags to null
            self.ptclC[self.pid_term].tagsDict["cplytag"] = ""
            other.ptclC[other.pid_term].tagsDict["cplytag"] = ""

            # If an intern ring connection is made change the fftype
            if (self.ptclC[self.pid_term].tagsDict["ring"] > 0
                    and other.ptclC[other.pid_term].tagsDict["ring"] > 0):
                #print " ring self ", self.ptclC[self.pid_term].tagsDict["ring"]
                #print " ring other ", other.ptclC[other.pid_term].tagsDict["ring"]

                self.ptclC[self.pid_term].tagsDict["fftype"] = 'C!'
                other.ptclC[other.pid_term].tagsDict["fftype"] = 'C!'

                # sys.exit(" ring test ")

        idFromToDict = dict(
        )  # Need to keep track of all ptcl ID changes at once
        # {fromID1:toID1, fromID2:toID2...}
        # eg {1:3, 3:5, 2:20...}

        bondC = BondContainer()  # Local bond container copy so ptclIDs
        angleC = AngleContainer()  # Local angle container copy so ptclIDs
        dihC = DihedralContainer()  # Local dihedral container copy so ptclIDs

        bondC = copy.deepcopy(
            other.bondC)  #  inside can be changed (for adding below)
        angleC = copy.deepcopy(
            other.angleC)  #  inside can be changed (for adding below)
        dihC = copy.deepcopy(
            other.dihC)  #  inside can be changed (for adding below)
        impC = copy.deepcopy(
            other.impC)  #  inside can be changed (for adding below)

        keys1 = self.ptclC.particles.keys(
        )  # global IDs of particles in this object
        keys2 = other.ptclC.particles.keys(
        )  # global IDs in object being added
        self.ptclC.maxgid = max(
            keys1 + keys2)  # find max globalID in keys, set this object maxID

        self.get_max()
        other.get_max()
        # Update chain, residue and charge group number
        if (self.max_chain == other.max_chain):

            other.shift_tag("qgroup", self.max_qgroup)
            other.shift_tag("residue", self.max_residue)
            other.shift_tag("ring", self.max_ring)
        else:
            other.add_chain(self.max_chain)

        for ptclkey2 in other.ptclC.particles:
            self.ptclC.put(other.ptclC.particles[ptclkey2]
                           )  # Pushes ptcl to this struc's ptcl container
            fromPtclID = ptclkey2  # Track IDs from--->to
            toPtclID = self.ptclC.maxgid  #  --> toID (to is the maxid of this ptclC)

            idFromToDict[fromPtclID] = toPtclID  # Store ID changes

        if (connect_along_bond):
            # Add inter building block bond
            if (self.verbose): print " Add inter building block bond "
            bb_bb = Bond(self.pid_term, idFromToDict[other.pid_term])
            self.bondC.put(bb_bb)

        bondC.replacePtclIDs(idFromToDict)  # Use tracked list of ID changes
        self.bondC += bondC  # Now add bondC with 'corrected' IDs

        angleC.replacePtclIDs(
            idFromToDict)  # Now add angleC with 'corrected' IDs
        self.angleC += angleC  # Use tracked list of ID changes

        dihC.replacePtclIDs(idFromToDict)  # Use tracked list of ID changes
        self.dihC += dihC  # Now add dihC with 'corrected' IDs

        impC.replacePtclIDs(idFromToDict)  # Use tracked list of ID changes
        self.impC += impC  # Now add impC with 'corrected' IDs

        if (connect_along_bond):
            self.compressPtclIDs()
            self.bondC_nblist()
            if (new_termpoint >= 0):

                if (self.verbose): print " Add new cplytag to  "

                self.get_connectors(new_termpoint)
                self.ptclC[
                    self.pid_term].tagsDict["cplytag"] = "term_C({})".format(
                        self.pid_term)
                self.ptclC[self.pid_termcap].tagsDict[
                    "cplytag"] = "termcap_H({})_on_C({})".format(
                        self.pid_termcap, self.pid_term)

        # Append segments
        for seg_i in other.segments:
            self.segments.append(seg_i)

        return self
Пример #19
0
def main():
    """
    This test shows how to add StructureContainer objects together
    """
    print "************************************************************************************"
    print " This test shows how to add StructureContainer objects together "
    print "************************************************************************************ \n"

    p1 = Particle([0.2, 1.3, 33.0], "Si", 2.0, 1.23)
    p2 = Particle([5.0, 2.3, -22.1], "C", 1.0, 2.34)
    p3 = Particle([5.0, 2.3, -20.1], "C", 1.0, 2.34)

    b1 = Bond(1, 2, 1.233, "hooke")
    b2 = Bond(2, 3, 0.500, "hooke")

    atoms1 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)

    bonds1 = BondContainer()
    bonds1.put(b1)
    bonds1.put(b2)

    polymer1 = StructureContainer(atoms1, bonds1)  # Complete structure 1

    p1other = Particle([0.0, 2.3, -20.1], "C", 1.0, 2.34)
    p2other = Particle([50.0, 0.3, -0.1], "Ar", 2.0, 2.34)

    b1other = Bond(1, 2, 1.233,
                   "hooke")  # Correct ptclIDs for second structure

    atoms2 = ParticleContainer()
    atoms2.put(p1other)
    atoms2.put(p2other)

    bonds2 = BondContainer()
    bonds2.put(b1other)

    polymer2 = StructureContainer(atoms2, bonds2)  # Complete structure 2
    print "Number of particles in polymer2 = ", polymer2.getPtclNum()

    del p1, p2, p3, p1other, p2other, b1, b2, b1other, atoms1, atoms2, bonds1, bonds2
    print "\n Cleaning memory for initial objects \n"

    print "-------------------- Before adding --------------------"
    print "polymer1 = ", polymer1
    print "polymer2 = ", polymer2
    print " "

    print "-------------------- After adding --------------------"
    polymer1 += polymer2
    print "polymer1 = ", polymer1
    print "Number of particles in polymer1 after add = ", polymer1.getPtclNum()

    print "-------------------- Results (check above) --------------------"
    print " 1---b1---2---b2---3 + 1---b1----2   should go to"
    print " "
    print " 1---b1---2---b2---3   4---b3----5 \n"

    print " "
    print "------ After adding polymer 2 should be unchanged--------------"
    print "polymer2 = ", polymer2
def main():
    """
    Tests a specifc workflow for LAMMPS that uses the simulationLAMMPS1 derived class
    """
    global g
    global p
    
    # Get useful methods
    g=Geometry()

    # Get comm object
    p = mpiBase.getMPISerialObject()
    rank = p.getRank()
    size = p.getCommSize()

    # Sync random stream for tests
    random.seed(0)

    #############################################################################################
    #
    # Generate list of  [gid, x,y,z] points ---> allPoints list
    # copied on all processors. # Global pt index included
    # UNITS distance --> A [0.1 nm]
    #
    #############################################################################################

    rad_avg = 15.0     # Moving to use this to make
    rad_sig = 0.025    # initial cubic grid thats used to pass to MD
    ptcl_dist = 10.0   # 

    # NOTE: this is an arbitrary choice
    cutoff_dist   = math.sqrt(2)*((2.00 * rad_avg) + ptcl_dist)
    nQD_spacing   = (2.00 * rad_avg) + ptcl_dist

    # Makes number of points along side grid
    nQDs = [5, 5, 5]
    sysLs = setSystemSizes(nQDs, nQD_spacing)

    # Set boundary condition list (used in PBC calc)
    xL = sysLs[0]
    yL = sysLs[1]
    zL = sysLs[2]
    bcLs = [0.0, yL[1]-yL[0], zL[1]-zL[0] ] # x is NOT PB

    # Status info
    if rank == 0:
        print "rad_avg     = ", rad_avg
        print "rad_sig     = ", rad_sig
        print "cutoff_dist = ", cutoff_dist
        print " "
        print "bcLs  = ", bcLs
        print "sysLs = ", sysLs
        print " "

    #############################################################################################
    # Generate initial points

    p.barrier()

    tmpPoints = setRandomGridPoints(nQDs, rad_avg, ptcl_dist) # Generate global pts lst
    allPoints = p.bcast(tmpPoints)                            # ensures rand pts same across procs

    numpoints = len(allPoints) # Total number of points (for diag)
    if numpoints == 0:
        print "Number of points generated == 0"
        sys.exit(3)

    myPoints  = p.splitListOnProcs(allPoints) # Split elements on across processors
    p.barrier()
    #############################################################################################


    ###################################################################
    # Store particles in struc and find neighbors/bonds
    # ptPos includes index eg. [1, 3.4, 1.2, -2.0]

    nanoPtcls = ParticleContainer()
    nanoBonds = BondContainer()

    for ptPos in allPoints:

        axisLoc = [bcLs[1]/2.0, bcLs[2]/2.0]
        cylinderRadius = 120.0
        inside  = isPtInCylinder(ptPos[1:], axisLoc, "yz", cylinderRadius)

        if inside:
            pt = Particle(ptPos[1:], type="QDbig",   mass=2.0)
            tagsD = {"molnum":1, "QDSizeAvg":20.0}
        else:
            pt = Particle(ptPos[1:], type="QDsmall", mass=1.0)
            tagsD = {"molnum":1, "QDSizeAvg":15.0}

        pt.setTagsDict(tagsD)
        nanoPtcls.put(pt)

    p.barrier()

    # Get bond info
    allDist, allNeighbors, numTotalNeighbors, allBonds = \
          setQDNeighbors(myPoints, allPoints, cutoff_dist, bcLs, rank, size)

    if rank == 0:
        print "Begin building bond container"

    # Put bonds into container
    for bond in allBonds:

        if not nanoBonds.hasBond(bond):                   # Check if bond is unique
            bnd = Bond(bond[0], bond[1], type="normBond") # Put into STREAMM object
            nanoBonds.put(bnd)                            # add if not in container

    p.barrier()

    if rank == 0:
        print "length of bond container = ", len(nanoBonds)
    ###############################################################################


    ############################################################################
    # Write LAMMPS file with atoms/bonds

    strucQD = StructureContainer(nanoPtcls, nanoBonds)
    simObjQD = SimulationLAMMPS1("LammpsAug14", verbose=False)
    simObjQD.setStructureContainer(strucQD)

    if isinstance(simObjQD, SimulationLAMMPS1):
        print "strucQD is a SimulationLAMMPS1"
    else:
        print "strucQD is NOT a SimulationLAMMPS1"


    boxSizes = sysLs
    strucQD.setBoxLengths(boxSizes)

    small_rad_avg   = 15.0
    big_bond_min    =  (2.0*      rad_avg) + ptcl_dist
    small_sigma_min = ((2.0*small_rad_avg) + ptcl_dist) / pow(2, 1/6.)
    big_sigma_min   = ((2.0*      rad_avg) + ptcl_dist) / pow(2, 1/6.)


    ptclParamMap = {("QDsmall", "epsilon"):1.0, ("QDsmall", "sigma"):small_sigma_min,
                     ("QDbig",   "epsilon"):1.0, ("QDbig",  "sigma"):big_sigma_min}

    # Just one bond type for now
    bondParamMap = {("normBond", "Kenergy"):1.0, ("normBond", "r0"):big_bond_min}

    if rank == 0:
        # nanoPtcls.scatterPlot()
        # strucQD.dumpLammpsInputFile("qd.data", ptclParamMap, bondParamMap)
        # strucQD.writeInput("qd.data", ptclParamMap, bondParamMap)
        # simObjQD.writeInput("qd.data", ptclParamMap, bondParamMap)
        simObjQD.setCoeffs(ptclParamMap, bondParamMap)
        simObjQD.writeInput("qd.data")

    # For format of test check
    os.system("cat qd.data")
def main():

    """
    This test shows structureContainer functionality with angles included
    """    
    print "************************************************************************************"
    print " This test shows structureContainer functionality with angles included"
    print "************************************************************************************ \n"

    p1 = Particle( [1.1, 1.1, 1.1], "Si", 2.0, 1.23)
    p2 = Particle( [2.2, 2.2, 2.2], "Si",  1.0, 2.34)
    p3 = Particle( [3.3, 3.3, 3.3], "Si",  1.0, 2.34)
    #
    p4 = Particle( [4.4, 4.4, 4.4], "C",  1.0, 2.34)   # 1
    p5 = Particle( [5.5, 5.5, 5.5], "C",  1.0, 2.34)   # 2
    p6 = Particle( [6.6, 6.6, 6.6], "C",  1.0, 2.34)   # 3

    b1 = Bond( 1, 2, 1.11, "hooke")
    b2 = Bond( 2, 3, 2.22, "hooke")
    #
    b3 = Bond( 1, 2, 3.33, "hooke")
    b4 = Bond( 2, 3, 4.44, "hooke")

    a1 = Angle(1, 2, 3, 1.11, "harmonic")
    #
    a2 = Angle(1, 2, 3, 2.22, "harmonic")

    atoms1 = ParticleContainer()
    atoms2 = ParticleContainer()
    atoms1.put(p1)
    atoms1.put(p2)
    atoms1.put(p3)
    #
    atoms2.put(p4)
    atoms2.put(p5)
    atoms2.put(p6)

    bonds1 = BondContainer()
    bonds2 = BondContainer()
    bonds1.put(b1)
    bonds1.put(b2)
    bonds2.put(b3)
    bonds2.put(b4)

    angles1 = AngleContainer()
    angles2 = AngleContainer()
    angles1.put(a1)
    angles2.put(a2)

    polymer1 = StructureContainer(atoms1, bonds1, angles1)
    polymer2 = StructureContainer(atoms2, bonds2, angles2)


    del p1, p2, p3, p4, p5, p6, b1, b2, b3, b4, a1, a2
    del atoms1, atoms2, bonds1, bonds2, angles1, angles2
    print "\n Cleaning memory for initial objects \n" 

    print "-------------------- Initial structures --------------------"
    print "polymer1 = ", polymer1
    print "polymer2 = ", polymer2
    print " "

    print "-------------- After adding  (polymer1 += polymer2) ----------------"
    polymer2 += polymer1
    print "polymer2 = ", polymer2