Example #1
0
def dump_config(filename,
                pos=None,
                diam=None,
                ptypes=None,
                box=None,
                compress=None):
    file_ext = os.path.splitext(filename)[1]
    cell = Cell(side=box)
    npart = pos.shape[0]

    particles = []
    for i in range(npart):
        p = Particle(species=ptypes[i],
                     position=pos[i, :] - box / 2.,
                     radius=diam[i] / 2.)
        particles.append(p)

    system = System(particle=particles, cell=cell)

    with Trajectory(filename, "w") as traj:
        # Step is always 0 for now.
        traj.write(system, 0)

    if file_ext == ".xyz":
        compress = True
    else:
        compress = False

    if compress:
        subprocess.run(["gzip", "-f", filename])
Example #2
0
    def read_sample(self, frame):
        """ returns System instance. """
        snap = self.trajectory[frame]
        ndim = snap.configuration.dimensions

        # Convert typeid from [0, 0, 1, ...] to ['A', 'A', 'B', ...] when snap.particles.types = ['A', 'B']
        distinct_species = snap.particles.types
        distinct_typeids = list(range(len(distinct_species)))
        typeid_to_species = {}
        for i in distinct_typeids:
            typeid_to_species[i] = distinct_species[i]

        box = snap.configuration.box[:
                                     ndim]  # atooms does not handle sheared boxes.
        cell = Cell(side=box)

        N = snap.particles.position.shape[0]
        particles = []
        for i in range(N):
            p = Particle(mass=snap.particles.mass[i],
                         species=typeid_to_species[snap.particles.typeid[i]],
                         position=snap.particles.position[i, :ndim],
                         velocity=snap.particles.velocity[i, :ndim],
                         radius=snap.particles.diameter[i] / 2)
            particles.append(p)

        return System(particle=particles, cell=cell)
Example #3
0
 def read_init(self):
     # Grab cell from the end of file if it is there
     try:
         side = self._read_comment(0)['cell']
         self._cell = Cell(side)
     except KeyError:
         self._cell = self._parse_cell()
    def read_sample(self, frame):
        """ returns System instance. """

        L = self.header[0]
        if self.ndim == 3:
            cell = Cell(side=[L, L, L])
        elif self.ndim == 2:
            cell = Cell(side=[L, L])

        N = self.data.shape[0]
        pos = self.data[:, :self.ndim]
        # Lerner group format has positions from [0, 1).
        pos = pos*L - L/2

        if self.velocity_present:
            # Next is the velocity, if it exists.
            vel = self.data[:, self.ndim:2*self.ndim]

        # # In 2D, we add a zero z-coordinate to be consistent with other formats.
        # if self.ndim == 3:
        #     # First ndim columns are always the position.
        # elif self.ndim == 2:
        #     new_pos = np.zeros((N, 3)).astype(float)
        #     new_pos[:, :self.ndim] = pos
        #     pos = new_pos
        #     if self.velocity_present:
        #         vel = np.zeros((N, 3)).astype(float)
        #         vel[:, :self.ndim] = self.data[:, self.ndim:2*self.ndim]

        particles = []
        for i in range(N):
            p = Particle()
            p.position = pos[i, :]
            if self.velocity_present:
                p.velocity = vel[i, :]
            if self.species_present and self.radius_present:
                p.species = str( int(self.data[i, -1]) )
                p.radius  = self.data[i, -2]
            elif self.radius_present:
                p.radius = self.data[i, -1]
            elif self.species_present:
                p.species = str( int(self.data[i, -1]) )

            particles.append(p)

        return System(particle=particles, cell=cell)
Example #5
0
 def _parse_cell(self):
     """Internal emergency method to grab the cell."""
     cell = None
     if self._index_cell:
         self.trajectory.seek(self._index_cell)
         side = numpy.fromstring(self.trajectory.readline(), sep=' ')
         cell = Cell(side)
     return cell
Example #6
0
 def read_sample(self, frame):
     cfg, box, pos, typ, vel = self.__read_one(self.__f_frames[frame])
     if vel is None:
         particle = [Particle(species=t, position=numpy.array(p)) for p, t in zip(pos, typ)]
     else:
         particle = [Particle(species=t, position=numpy.array(p), velocity=numpy.array(v))
                     for p, t, v in zip(pos, typ, vel)]
     cell = Cell(numpy.array(box))
     return System(particle, cell)
Example #7
0
 def setUp(self):
     N = 100
     L = 10.0
     self.ref = System()
     self.ref.cell = Cell([L, L, L])
     self.ref.particle = []
     self.ref.thermostat = Thermostat(1.0)
     self.ref.barostat = Barostat(1.0)
     self.ref.reservoir = Reservoir(1.0)
     while len(self.ref.particle) <= N:
         pos = [(random.random() - 0.5) * L, (random.random() - 0.5) * L,
                (random.random() - 0.5) * L]
         self.ref.particle.append(Particle(position=pos))
Example #8
0
 def test_overlap_random(self):
     # This test may fail from time to time
     from atooms.system.particle import collective_overlap
     N = 1000
     L = 5.0
     sys = [System(), System()]
     sys[0].cell = Cell([L, L, L])
     sys[1].cell = Cell([L, L, L])
     sys[0].particle = []
     sys[1].particle = []
     for _ in range(N):
         pos = [(random.random() - 0.5) * L, (random.random() - 0.5) * L,
                (random.random() - 0.5) * L]
         sys[0].particle.append(Particle(position=pos))
     for _ in range(N):
         pos = [(random.random() - 0.5) * L, (random.random() - 0.5) * L,
                (random.random() - 0.5) * L]
         sys[1].particle.append(Particle(position=pos))
     a = 0.3
     q_rand = ((a**3 * 4. / 3 * 3.1415) * N / sys[0].cell.volume)
     self.assertTrue(
         abs(q_rand - collective_overlap(sys[0].particle, sys[1].particle,
                                         a, sys[0].cell.side)) < 0.5)
Example #9
0
    def read_sample(self, frame):
        # Read metadata of this frame
        meta = self._read_comment(frame)

        # Get number of particles
        self.trajectory.seek(self._index_header[frame])
        npart = int(self.trajectory.readline())

        # Read frame now
        self.trajectory.seek(self._index_frame[frame])
        particle = []
        for ipart in range(npart):
            p = Particle()
            data = self.trajectory.readline().split()
            i = 0
            for key, fmt, ndims in meta['Properties']:
                ndims = int(ndims)
                if key in self.alias:
                    key = self.alias[key]
                if ndims == 1:
                    if fmt == 'R':
                        setattr(p, key, float(data[i]))
                    elif fmt == 'I':
                        setattr(p, key, int(data[i]))
                    elif fmt == 'S':
                        setattr(p, key, data[i])
                    else:
                        raise ValueError('unknown format key')
                else:
                    if fmt == 'R':
                        setattr(
                            p, key,
                            numpy.array(data[i:i + ndims],
                                        dtype=numpy.float64))
                    elif fmt == 'I':
                        setattr(
                            p, key,
                            numpy.array(data[i:i + ndims], dtype=numpy.int64))
                    elif fmt == 'S':
                        setattr(p, key, numpy.array(data[i:i + ndims]))
                    else:
                        raise ValueError('unknown format key')
                i += ndims
            particle.append(p)

        side = meta["Lattice"]
        # TODO: remove hard coded
        cell = Cell([side[0], side[4], side[8]])
        return System(particle, cell)
Example #10
0
 def test_ovito(self):
     try:
         import ovito
     except ImportError:
         self.skipTest('missing ovito')
     N = 3
     L = 5.0
     system = System()
     system.cell = Cell([L, L, L])
     system.particle = []
     for _ in range(N):
         pos = (numpy.random.random(len(system.cell.side)) -
                0.5) * system.cell.side
         p = Particle(position=pos)
         system.particle.append(p)
     image = system.show('ovito')
Example #11
0
    def test_write_initial_state(self):
        p = [
            PairPotential('lennard_jones', {
                'epsilon': 1.0,
                'sigma': 1.0
            }, [1, 1], CutOff('CS', 2.5))
        ]
        i = [Interaction(p, 'atomic')]
        s = System()
        s.cell = Cell([1.0, 1.0, 1.0])
        t = TrajectoryHDF5('/tmp/test_potential.h5', 'w')
        t.write_interaction(i)
        t.close()

        t = TrajectoryHDF5('/tmp/test_potential.h5', 'r')
        i = t.read_interaction()
        t.close()
Example #12
0
    def read_sample(self, frame):
        meta = self._read_comment(frame)
        self.trajectory.seek(self._index_frame[frame])

        # Read particles
        particle = []
        for _ in range(meta['npart']):
            data = self.trajectory.readline().strip().split()
            species = data[0]
            r = numpy.array(data[1:4], dtype=float)
            particle.append(Particle(species=species, position=r))

        # Read cell
        try:
            side = meta['cell']
            self._cell = Cell(side)
        except KeyError:
            pass

        return System(particle, self._cell)
Example #13
0
    def read_sample(self, frame):
        # Setup fields again, in case they have changed
        if self.__cache_fields != self.fields:
            self._setup_fields()
        # Read metadata of this frame
        meta = self._read_comment(frame)
        # Define read callbacks list before reading lines
        callbacks_read = []

        def _skip(p, data, meta):
            return data[1:]

        for key in self.fields:
            # If the key is associated to a explicit callback, go
            # for it. Otherwise we throw the field in an particle
            # attribute named key. If the key is None it means we skip
            # this column.
            if key is None:
                callbacks_read.append(_skip)
            elif key in self.callback_read:
                callbacks_read.append(self.callback_read[key])
            else:
                # Trick. We instantiate dynamically a fallback function
                # to avoid adding `key` to the other callbacks' interface
                namespace = {}
                exec(
                    """
from atooms.core.utils import tipify
def fallback(p, data, meta):
    p.__dict__['%s'] = tipify(data[0])
    return data[1:]
""" % key, namespace)
                callbacks_read.append(namespace['fallback'])

        # Read frame now
        self.trajectory.seek(self._index_frame[frame])
        particle = []
        for i in range(meta['npart']):
            p = Particle()
            # Note: we cannot optimize by shifting an index instead of
            # cropping lists all the time
            data = self.trajectory.readline().split()
            for cbk in callbacks_read:
                data = cbk(p, data, meta)
            particle.append(p)

        # Fix the masses.
        # We assume masses read from the header are sorted by species name.
        # The mass metadata must be adjusted to the given frame.
        if 'mass' in meta:
            if isinstance(meta['mass'], list) or isinstance(
                    meta['mass'], tuple):
                species = distinct_species(particle)
                # We must have as many mass entries as species
                if len(species) != len(meta['mass']):
                    raise ValueError('mass metadata issue %s, %s' %
                                     (species, meta['mass']))
                db = {}
                for key, value in zip(species, meta['mass']):
                    db[key] = value
                for p in particle:
                    p.mass = float(db[p.species])
            else:
                for p in particle:
                    p.mass = float(meta['mass'])

        # Add cell info
        if 'cell' in meta:
            cell = Cell(meta['cell'])
        else:
            cell = None

        return System(particle, cell)
Example #14
0
    def read_init(self):
        # read particles
        group = self.trajectory['/initialstate/particle']
        n = self.trajectory['/initialstate/particle/number_of_particles'][0]
        rad = None
        for entry in group:
            # TODO: refactor this
            if entry == 'element':
                spe = group[entry][:]
            if entry == 'mass':
                mas = group[entry][:]
            if entry == 'position':
                pos = group[entry][:]
            if entry == 'velocity':
                vel = group[entry][:]
            if entry == 'radius':
                rad = group[entry][:]
        if rad is not None:
            particle = [
                Particle(species=spe[i].decode().strip(),
                         mass=mas[i],
                         position=pos[i, :],
                         velocity=vel[i, :],
                         radius=rad[i]) for i in range(n)
            ]
        else:
            particle = [
                Particle(species=spe[i].decode().strip(),
                         mass=mas[i],
                         position=pos[i, :],
                         velocity=vel[i, :]) for i in range(n)
            ]

        # read cell
        group = self.trajectory['/initialstate/cell']
        for entry in group:
            if entry == 'sidebox':
                sidebox = group[entry][:]
        cell = Cell(sidebox)

        # read interaction
        interaction = self.read_interaction()

        # build system
        self._system = System(particle, cell, interaction)

        # read matrix
        if 'matrix' in self.trajectory['/initialstate']:
            group = self.trajectory['/initialstate/matrix']
            for entry in group:
                if entry == 'element':
                    spe = group[entry][:]
                if entry == 'mass':
                    mas = group[entry][:]
                if entry == 'position':
                    pos = group[entry][:]
            matrix = [
                Particle(species=spe[i].decode().strip(),
                         mass=mas[i],
                         position=pos[i, :]) for i in range(len(spe))
            ]
            self._system.matrix = copy.deepcopy(matrix)

        return self._system
Example #15
0
 def cell(self):
     box = self.sample.GetSimulationBox()
     L = [box.GetLength(i) for i in range(3)]
     return Cell(L)