Esempio n. 1
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def test_socketio_espresso(factory):
    name = factory.name
    if name == 'abinit':
        factory.require_version('9.4')

    atoms = bulk('Si')

    exe = factory.factory.executable
    unixsocket = f'ase_test_socketio_{name}'

    espresso = factory.calc(
        kpts=[2, 2, 2],
    )
    template = commands[name]
    command = template.format(exe=exe, unixsocket=unixsocket)
    espresso.command = command

    atoms.rattle(stdev=.2, seed=42)

    with BFGS(ExpCellFilter(atoms)) as opt, \
         pytest.warns(UserWarning, match='Subprocess exited'), \
         SocketIOCalculator(espresso, unixsocket=unixsocket) as calc:
        atoms.calc = calc
        for _ in opt.irun(fmax=0.05):
            e = atoms.get_potential_energy()
            fmax = max(np.linalg.norm(atoms.get_forces(), axis=0))
            print(e, fmax)
Esempio n. 2
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def run_server(launchclient=True):
    atoms = getatoms()

    with SocketIOCalculator(log=sys.stdout, port=port,
                            timeout=timeout) as calc:
        if launchclient:
            thread = launch_client_thread()
        atoms.calc = calc
        opt = BFGS(atoms)
        opt.run()

    if launchclient:
        thread.join()

    forces = atoms.get_forces()
    energy = atoms.get_potential_energy()

    atoms.calc = EMT()
    ref_forces = atoms.get_forces()
    ref_energy = atoms.get_potential_energy()

    refatoms = run_normal()
    ref_energy = refatoms.get_potential_energy()
    eerr = abs(energy - ref_energy)
    ferr = np.abs(forces - ref_forces).max()

    perr = np.abs(refatoms.positions - atoms.positions).max()
    print('errs e={} f={} pos={}'.format(eerr, ferr, perr))
    assert eerr < 1e-11, eerr
    assert ferr < 1e-11, ferr
    assert perr < 1e-11, perr
Esempio n. 3
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    def __init__(self,
                 workflow: str,
                 label: str = 'balsam',
                 atoms: Atoms = None,
                 job_args: str = None,
                 job_kwargs: Dict[str, Any] = dict(),
                 **kwargs: Any) -> None:
        ''' Define Balsam Socket IO Calculator

        Parameters
        ----------
        workflow : str
            name of the workflow, e.g.

            >>> workflow='QE_Socket'

        label : str, optional
            label for the created balsam calculator, by default 'balsam'
        atoms : Atoms, optional
            an Atoms object, by default None
        job_args : str, optional
            by default None
        job_kwargs : Dict[str, Any], optional
            by default dict(), e.g.

            >>> balsam_exe_settings = {'num_nodes': 1,
                                    'ranks_per_node': 48,
                                    'threads_per_rank': 1}

        '''
        SocketIOCalculator.__init__(self, port=0)
        self._port = self.server.serversocket.getsockname()[1]
        BalsamCalculator.__init__(self,
                                  workflow=workflow,
                                  label=label,
                                  atoms=atoms,
                                  job_args=job_args,
                                  job_kwargs=job_kwargs,
                                  **kwargs)
Esempio n. 4
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    def calculate(self,
                  atoms: Atoms = None,
                  properties: List[str] = ['energy'],
                  system_changes: List[str] = all_changes) -> None:
        ''' Run calculator

        Parameters
        ----------
        atoms : Atoms
            an Atom object representing the system studied, by default None
        properties : List[str], optional
            by default ['energy']
        system_changes : List[str], optional
            by default all_changes

        '''
        Calculator.calculate(self, atoms, properties, system_changes)
        if self.job is None or not self.job_running(self.job.state):
            self.job = self.create_job()
            self.directory = self.job.working_directory
            self.format_socket_keywords()
            self.write_input(self.atoms, properties, system_changes)
            self.job.save()
        SocketIOCalculator.calculate(self, atoms, properties, system_changes)
Esempio n. 5
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def main():
    '''Main driver routine.'''

    system = read(GEO_PATH, format='gen')
    write('geo.gen', system, format='gen')

    opt = BFGS(system, trajectory='opt.traj', logfile='opt.log')

    with SocketIOCalculator(log=sys.stdout, unixsocket=UNIXSOCKET) as calc:
        Popen(DFTBP_PATH)
        system.set_calculator(calc)
        opt.run(fmax=1.00E-09)

    forces = system.get_forces()
    energy = system.get_potential_energy()
Esempio n. 6
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def test_socketio_python():
    from ase.build import bulk
    from ase.constraints import ExpCellFilter
    from ase.optimize import BFGS

    atoms = bulk('Au') * (2, 2, 2)
    atoms.rattle(stdev=0.05)
    fmax = 0.01
    atoms.cell += np.random.RandomState(42).rand(3, 3) * 0.05

    client = PySocketIOClient(EMT)

    pid = os.getpid()
    with SocketIOCalculator(launch_client=client,
                            unixsocket=f'ase-python-{pid}') as atoms.calc:
        with BFGS(ExpCellFilter(atoms)) as opt:
            opt.run(fmax=fmax)
    forces = atoms.get_forces()
    assert np.linalg.norm(forces, axis=0).max() < fmax
def run_server(launchclient=True, sockettype='unix'):
    atoms = getatoms()

    port = None
    unixsocket = None

    if sockettype == 'unix':
        unixsocket = f'ase_ipi_protocol_bfgs_test_{pid}'
    else:
        assert sockettype == 'inet'
        port = inet_port

    with SocketIOCalculator(log=sys.stdout,
                            port=port,
                            unixsocket=unixsocket,
                            timeout=timeout) as calc:
        if launchclient:
            thread = launch_client_thread(port=port, unixsocket=unixsocket)
        atoms.calc = calc
        with BFGS(atoms) as opt:
            opt.run()

    if launchclient:
        thread.join()

    forces = atoms.get_forces()
    energy = atoms.get_potential_energy()

    atoms.calc = EMT()
    ref_forces = atoms.get_forces()
    ref_energy = atoms.get_potential_energy()

    refatoms = run_normal()
    ref_energy = refatoms.get_potential_energy()
    eerr = abs(energy - ref_energy)
    ferr = np.abs(forces - ref_forces).max()

    perr = np.abs(refatoms.positions - atoms.positions).max()
    print('errs e={} f={} pos={}'.format(eerr, ferr, perr))
    assert eerr < 1e-11, eerr
    assert ferr < 1e-11, ferr
    assert perr < 1e-11, perr
Esempio n. 8
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def main():
    '''Main driver routine.'''

    system = read(GEO_PATH, format='gen')
    write('dummy.gen', system, format='gen')

    initial = read('NH3_initial.traj')
    final = read('NH3_final.traj')

    images = [initial]
    images += [initial.copy() for ii in range(NIMAGES)]
    images += [final]

    neb = NEB(images)
    neb.interpolate()

    opt = BFGS(neb, trajectory='i2f.traj')

    socketids = range(1, NIMAGES + 1)
    wdirs = ['_calc/image_{:d}'.format(socket) for socket in socketids]
    unixsockets = ['dftbplus_{:d}'.format(socket) for socket in socketids]

    write_modhsd(socketids)

    calcs = [
        SocketIOCalculator(log='socket.log', unixsocket=unixsocket)
        for unixsocket in unixsockets
    ]

    for ii, calc in enumerate(calcs):
        images[ii + 1].set_calculator(calc)

    for cwd in wdirs:
        Popen(DFTBP_PATH, cwd=cwd)

    opt.run(fmax=1.00E-02)

    for calc in calcs:
        calc.close()
Esempio n. 9
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import sys

from ase.build import molecule
from ase.optimize import BFGS
from ase.calculators.aims import Aims
from ase.calculators.socketio import SocketIOCalculator

# Environment-dependent parameters -- please configure according to machine
# Note that FHI-aim support for the i-PI protocol must be specifically
# enabled at compile time, e.g.: make -f Makefile.ipi ipi.mpi
species_dir = '/home/aimsuser/src/fhi-aims.171221_1/species_defaults/light'
command = 'ipi.aims.171221_1.mpi.x'

# This example uses INET; see other examples for how to use UNIX sockets.
port = 31415

atoms = molecule('H2O', vacuum=3.0)
atoms.rattle(stdev=0.1)

aims = Aims(command=command,
            use_pimd_wrapper=('localhost', port),
            compute_forces=True,
            xc='LDA',
            species_dir=species_dir)

opt = BFGS(atoms, trajectory='opt.aims.traj', logfile='opt.aims.log')

with SocketIOCalculator(aims, log=sys.stdout, port=port) as calc:
    atoms.calc = calc
    opt.run(fmax=0.05)
Esempio n. 10
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# In this example we use a UNIX socket.  See other examples for INET socket.
# UNIX sockets are faster then INET sockets, but cannot run over a network.
# UNIX sockets are files.  The actual path will become /tmp/ipi_ase_espresso.
unixsocket = 'ase_espresso'

# Configure pw.x command for UNIX or INET.
#
# UNIX: --ipi {unixsocket}:UNIX
# INET: --ipi {host}:{port}
#
# See also QE documentation, e.g.:
#
#    https://www.quantum-espresso.org/Doc/pw_user_guide/node13.html
#
command = ('pw.x < PREFIX.pwi --ipi {unixsocket}:UNIX > PREFIX.pwo'.format(
    unixsocket=unixsocket))

espresso = Espresso(command=command,
                    ecutwfc=30.0,
                    pseudopotentials=pseudopotentials,
                    pseudo_dir=pseudo_dir)

opt = BFGS(atoms, trajectory='opt.traj', logfile='opt.log')

with SocketIOCalculator(espresso, log=sys.stdout,
                        unixsocket=unixsocket) as calc:
    atoms.calc = calc
    opt.run(fmax=0.05)

# Note: QE does not generally quit cleanly - expect nonzero exit codes.
Esempio n. 11
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    "outfilename": "aims.out",
}

dft_settings = {
    # system settings
    "xc": "pbe",
    "spin": "none",
    "compute_forces": True,
}

# ################# Set aims calculator ######################
workdir = "aims_rundir"
port_aims = 12345
aux_settings = {"label": workdir, "use_pimd_wrapper": ("localhost", port_aims)}

calc = Aims(**usr_settings, **dft_settings, **aux_settings)

# atoms.set_calculator(calc)

# ################# Create Client ############################
# inet
port_ipi = 10200
host_ipi = "localhost"
client = SocketClient(host=host_ipi, port=port_ipi)

# ################# Create ASE SERVER ############################

with SocketIOCalculator(calc, log="socketio.log", port=port_aims) as io_calc:
    atoms.set_calculator(io_calc)
    client.run(atoms)
Esempio n. 12
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def get_aims_and_sockets_calculator(
        dimensions,
        # i-Pi settings for sockets
        port=None,
        host=None,
        logfile='socketio.log',
        # Debug setting
        check_socket=True,
        verbose=False,
        codata_warning=True,
        # Passthrough of other objects for calculator
        **kwargs):
    '''
    Method to return a sockets calculator (for i-Pi based socket connectivity)
    and also an associated FHI-aims calculator for ASE

    Args:
        dimensions: Integer
            Dimensions is _not_ used in this routine, but we make it necessary so
            the passthrough isn't problematic for inexperienced users. See get_aims_calculator()
        port: None or Integer
            The port for connection between FHI-aims and ASE with i-Pi sockets.
            This is fairly arbitrary as long as it doesn't clash with local settings.
            If None an integer between 12345 and 60000 will be picked at random.
        host: String
            Name of host computer for ASE. Necessary for calculations where MPI runs on the compute nodes.
            This is now defaulted to None, and then will self-identify the host name if unidentified.
            Long-term, we should consider removing this variable to insulate the users from having to set it.
        logfile: String
            Location of output from sockets communication.
        check_socket: Boolean
            Whether we want the automatically identify and resolve port clashes.
        verbose: Boolean
            For testing of the interface when searching for empty ports.
        codata_warning: Boolean
            Warn the user about Hartree to eV conversion being performed in ASE rather than FHI-aims.
            ASE uses CODATA 2014 and FHI-aims uses CODATA 2002 which yields energy discrepancies.
            The warning message can be turned off if set to False.

    Returns:
        Socket_calc: Wrapper for ASE calculator
            Used for i-Pi connectvity, and should be assigned to optimisation/dynamics Object
        FHI_calc: FHI-aims ASE calculator
    '''

    import socket

    if host is None:
        # On machines where ASE and FHI-aims are run separately (e.g. ASE on login node, FHI-aims on compute nodes)
        # we need to specifically state what the name of the login node is so the two packages can communicate
        # In order to manage this communication in all situations, here we will find and use the hostname *even*
        # if on the same computer (it should work irrespective)
        host = socket.gethostname()

    # Random port assignment
    if port:
        pass
    else:
        import random
        port = random.randint(12345, 60000)

    if check_socket:
        port = _check_socket(host, port, verbose)

    # **kwargs is a passthrough of keyword arguments
    fhi_calc = get_aims_calculator(dimensions, **kwargs)
    # Add in PIMD command to get sockets working
    fhi_calc.set(use_pimd_wrapper=[host, port])

    # Setup sockets calculator that "wraps" FHI-aims
    from ase.calculators.socketio import SocketIOCalculator
    socket_calc = SocketIOCalculator(fhi_calc, log=logfile, port=port)

    if codata_warning:
        print(
            "You are using i-Pi based socket connectivity between ASE and FHI-aims."
        )
        print(
            "The communicated energy in Hartree units will be converted to eV in ASE and not FHI-aims."
        )
        print(
            "The eV/Hartree unit in FHI-aims is given by CODATA 2002 (Web Version 4.0 2003-12-09), Peter J. Mohr, Barry N. Taylor"
        )
        print(
            "ASE uses CODATA 2014, thus the energy in eV from ASE and the FHI-aims outputs will differ."
        )
        print("Please be consistent in the unit conversion for data analysis!")
        print(
            "You can turn off this message by setting 'codata_warning' keyword to False."
        )

    return socket_calc, fhi_calc
Esempio n. 13
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import os
from ase import Atoms
from ase.optimize import BFGS
from ase.calculators.aims import Aims
from ase.calculators.socketio import SocketIOCalculator

os.environ['ASE_AIMS_COMMAND'] = 'aims.x'
os.environ[
    'AIMS_SPECIES_DIR'] = '/home/alumne/software/FHIaims/species_defaults/light'

atoms = Atoms('HOH', positions=[[0, 0, -1], [0, 1, 0], [0, 0, 1]])
opt = BFGS(atoms, trajectory='opt-aims-socketio.traj')

aims = Aims(xc='LDA',
            compute_forces=True,
            use_pimd_wrapper=('UNIX:mysocket', 31415))

with SocketIOCalculator(aims, unixsocket='mysocket') as calc:
    atoms.calc = calc
    opt.run(fmax=0.05)
Esempio n. 14
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 def socket_driver(self, **kwargs):
     from ase.calculators.socketio import SocketIOCalculator
     calc = SocketIOCalculator(self, **kwargs)
     return calc
Esempio n. 15
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import sys
from ase.build import molecule
from ase.calculators.dftb import Dftb
from ase.calculators.socketio import SocketIOCalculator
from ase.optimize import BFGS


atoms = molecule('H2O')
dftb = Dftb(Hamiltonian_MaxAngularMomentum_='',
            Hamiltonian_MaxAngularMomentum_O='"p"',
            Hamiltonian_MaxAngularMomentum_H='"s"',
            Driver_='',
            Driver_Socket_='',
            Driver_Socket_File='Hello')
opt = BFGS(atoms, trajectory='test.traj')


with SocketIOCalculator(dftb, log=sys.stdout, unixsocket='Hello') as calc:
    atoms.calc = calc
    opt.run(fmax=0.01)
Esempio n. 16
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# function to make sure the structure stays tetragonal
def tetragonalize(atoms):
    """ make the lattice of atoms object tetragonal """
    cell = atoms.cell
    scaled_pos = atoms.get_scaled_positions()

    a = (cell[0, 0] + cell[1, 1]) / 2
    c = cell[2, 2]

    new_cell = np.array([[a, 0, 0], [0, a, 0], [0, 0, c]])

    atoms.cell = new_cell
    atoms.set_scaled_positions(scaled_pos)


# run the optimization and write out every step
with SocketIOCalculator(calc, log="socketio.log", port=port) as calc:
    atoms.set_calculator(calc)
    # create the optimizer for the filtered atoms object
    opt = optimizer(opt_atoms, logfile=log_name, trajectory=trajectory_name)
    for ii, _ in enumerate(opt.irun(fmax=0.001, steps=20)):
        # tetragonalize the structure
        tetragonalize(atoms)
        # write out every intermediate structure (not necessary)
        atoms.write(f"{workdir}/geometry.in.next.{ii}", "aims", scaled=True)

# write final result
atoms.write("geometry.out", "aims", scaled=True)
Esempio n. 17
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import sys

from ase.build import molecule
from ase.io import write
from ase.optimize import BFGS
from ase.calculators.socketio import SocketIOCalculator

unixsocket = 'ase_server_socket'

atoms = molecule('H2O', vacuum=3.0)
atoms.rattle(stdev=0.1)
write('initial.traj', atoms)

opt = BFGS(atoms, trajectory='opt.driver.traj', logfile='opt.driver.log')

with SocketIOCalculator(log=sys.stdout, unixsocket=unixsocket) as calc:
    # Server is now running and waiting for connections.
    # If you want to launch the client process here directly,
    # instead of manually in the terminal, uncomment these lines:
    #
    # from subprocess import Popen
    # proc = Popen([sys.executable, 'example_client_gpaw.py'])

    atoms.calc = calc
    opt.run(fmax=0.05)
Esempio n. 18
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# write(os.path.join(working_dir, 'geo.gen'), at, format='gen')
# shutil.copyfile(os.path.join(suppporting, "dftb_in.hsd"),
# os.path.join(working_dir, "dftb_in.hsd"))

# calc = Dftb(atoms=at,
# Hamiltonian_='DFTB',
# Hamiltonian_SCC='Yes',
# Hamiltonian_SCCTolerance=1e-6,
# Hamiltonian_MaxAngularMomentum_='',
# Hamiltonian_MaxAngularMomentum_H='s',
# Hamiltonian_MaxAngularMomentum_O='p',
# Hamiltonian_MaxAngularMomentum_C='p',
# Hamiltonian_MaxAngularMomentum_N='p',
# Hamiltonian_MaxAngularMomentum_S='d')
# kpts = (1,1,1))

# at.calc=calc
# calc.calculate(at)
# sys.exit(0)
# text = "Driver = Socket {\n\
# File = \"dftbplus\"\n\
# Protocol = i-PI {}\n\
# MaxSteps = 1000\n\
# Verbosity = 0\n\}\n"

# with open(os.path.join(working_dir, "dftb_in.hsd"), "a") as dftb:
# dftb.write(text)
# sys.exit(0)
calculator = SocketIOCalculator(log=sys.stdout, unixsocket=UNIXSOCKET)
Popen(DFTBP_PATH)