Ejemplo n.º 1
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    def test_non_alchemical_protocol(self):
        """Any property of the ThermodynamicSystem can be specified in the protocol."""
        name, thermodynamic_state, sampler_state, topography = self.host_guest_implicit
        protocol = {
            'lambda_sterics': [0.0, 0.5, 1.0],
            'temperature': [300, 320, 300] * unit.kelvin
        }
        alchemical_phase = AlchemicalPhase(sampler=ReplicaExchangeSampler())
        with self.temporary_storage_path() as storage_path:
            alchemical_phase.create(thermodynamic_state,
                                    sampler_state,
                                    topography,
                                    protocol,
                                    storage_path,
                                    restraint=yank.restraints.Harmonic())
            self.check_protocol(alchemical_phase, protocol)

        # If temperatures of the end states is different, an error is raised.
        protocol['temperature'][-1] = 330 * unit.kelvin
        alchemical_phase = AlchemicalPhase(sampler=ReplicaExchangeSampler())
        with nose.tools.assert_raises(ValueError):
            alchemical_phase.create(thermodynamic_state,
                                    sampler_state,
                                    topography,
                                    protocol,
                                    'not_created.nc',
                                    restraint=yank.restraints.Harmonic())
Ejemplo n.º 2
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def mix_replicas(n_swaps=100, n_states=16, u_kl=None, nswap_attempts=None):
    """
    Utility function to generate replicas and call the mixing function a certain number of times

    Arguments
    ---------
    n_swaps : int (optional)
        The number of times to call the mixing code (default 100)
    n_states : int (optional)
        The number of replica states to include (default 16)
    u_kl : n_states x n_states ndarray of float64 (optional)
        Energies for each state. If None, will be initialized to zeros

    Returns
    -------
    permutation_list : n_states x n_swaps ndarray of np.int64
        Contains the result of each swap
    """

    if u_kl is None:
        u_kl = np.zeros([n_states, n_states], dtype=np.float64)
    replica_states = np.array(range(n_states), np.int64)
    if nswap_attempts is None:
        nswap_attempts = n_states**4
    Nij_proposed =  np.zeros([n_states,n_states], dtype=np.int64)
    Nij_accepted = np.zeros([n_states,n_states], dtype=np.int64)
    permutation_list = []
    from openmmtools.multistate import ReplicaExchangeSampler
    for i in range(n_swaps):
        ReplicaExchangeSampler._mix_all_replicas_numba(nswap_attempts, n_states, replica_states, u_kl, Nij_proposed, Nij_accepted)
        permutation_list.append(copy.deepcopy(replica_states))
    permutation_list_np = np.array(permutation_list, dtype=np.int64)
    return permutation_list_np
Ejemplo n.º 3
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    def test_randomize_ligand(self):
        """Test method AlchemicalPhase.randomize_ligand."""
        _, thermodynamic_state, sampler_state, topography = self.host_guest_implicit
        restraint = yank.restraints.Harmonic()

        ligand_atoms, receptor_atoms = topography.ligand_atoms, topography.receptor_atoms
        ligand_positions = sampler_state.positions[ligand_atoms]
        receptor_positions = sampler_state.positions[receptor_atoms]

        with self.temporary_storage_path() as storage_path:
            alchemical_phase = AlchemicalPhase(ReplicaExchangeSampler())
            alchemical_phase.create(thermodynamic_state,
                                    sampler_state,
                                    topography,
                                    self.protocol,
                                    storage_path,
                                    restraint=restraint)

            # Randomize ligand positions.
            alchemical_phase.randomize_ligand()

            # The new sampler states have the same receptor positions
            # but different ligand positions.
            for sampler_state in alchemical_phase._sampler.sampler_states:
                assert np.allclose(sampler_state.positions[receptor_atoms],
                                   receptor_positions)
                assert not np.allclose(sampler_state.positions[ligand_atoms],
                                       ligand_positions)
Ejemplo n.º 4
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    def test_create(self):
        """Alchemical state correctly creates the simulation object."""
        available_restraints = [
            restraint for restraint in
            yank.restraints.available_restraint_classes().values()
            if not (hasattr(restraint, "dev_validate")
                    and not restraint.dev_validate)
        ]

        for test_index, test_case in enumerate(self.all_test_cases):
            test_name, thermodynamic_state, sampler_state, topography = test_case

            # Add random restraint if this is ligand-receptor system in implicit solvent.
            if len(topography.ligand_atoms) > 0:
                restraint_cls = available_restraints[np.random.randint(
                    0, len(available_restraints))]
                restraint = restraint_cls()
                protocol = self.restrained_protocol
                test_name += ' with restraint {}'.format(
                    restraint_cls.__name__)
            else:
                restraint = None
                protocol = self.protocol

            # Add either automatic of fixed correction cutoff.
            if test_index % 2 == 0:
                correction_cutoff = 12 * unit.angstroms
            else:
                correction_cutoff = 'auto'

            # Replace the reaction field of the reference system to compare
            # also cutoff and switch width for the electrostatics.
            reference_system = thermodynamic_state.system
            mmtools.forcefactories.replace_reaction_field(reference_system,
                                                          return_copy=False)

            alchemical_phase = AlchemicalPhase(
                sampler=ReplicaExchangeSampler())
            with self.temporary_storage_path() as storage_path:
                alchemical_phase.create(
                    thermodynamic_state,
                    sampler_state,
                    topography,
                    protocol,
                    storage_path,
                    restraint=restraint,
                    anisotropic_dispersion_cutoff=correction_cutoff)

                yield prepare_yield(self.check_protocol, test_name,
                                    alchemical_phase, protocol)
                yield prepare_yield(self.check_standard_state_correction,
                                    test_name, alchemical_phase, topography,
                                    restraint)
                yield prepare_yield(self.check_expanded_states, test_name,
                                    alchemical_phase, protocol,
                                    correction_cutoff, reference_system)

                # Free memory.
                del alchemical_phase
Ejemplo n.º 5
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def run_replica_exchange_done(job):
    output_directory = os.path.join(job.workspace(), "output")
    output_data = os.path.join(output_directory, "output.nc")
    rep_exch_completed = 0
    if os.path.isfile(output_data):
        rep_exch_status = ReplicaExchangeSampler.read_status(output_data)
        rep_exch_completed = rep_exch_status.is_completed
    return rep_exch_completed
Ejemplo n.º 6
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 def test_illegal_restraint(self):
     """Raise an error when restraint is handled incorrectly."""
     # An error is raised with ligand-receptor systems in implicit without restraint.
     test_name, thermodynamic_state, sampler_state, topography = self.host_guest_implicit
     alchemical_phase = AlchemicalPhase(sampler=ReplicaExchangeSampler())
     with nose.tools.assert_raises(ValueError):
         alchemical_phase.create(thermodynamic_state, sampler_state, topography,
                                 self.protocol, 'not_created.nc')
Ejemplo n.º 7
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def CEI_replica_exchange_done(job):
    output_directory = os.path.join(job.workspace(),"output_CEI")
    output_data = os.path.join(output_directory, "output.nc")
    rep_exch_completed = 0
    if os.path.isfile(output_data):
        # ***Note: this can sometimes fail if the .nc files are currently being written to
        rep_exch_status = ReplicaExchangeSampler.read_status(output_data)
        rep_exch_completed = rep_exch_status.is_completed
    return rep_exch_completed
Ejemplo n.º 8
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    def test_minimize(self):
        """Test AlchemicalPhase minimization of positions in reference state."""
        # Ligand-receptor in implicit solvent.
        test_system = testsystems.AlanineDipeptideVacuum()
        thermodynamic_state = states.ThermodynamicState(test_system.system,
                                                        temperature=300 *
                                                        unit.kelvin)
        topography = Topography(test_system.topology)

        # We create 3 different sampler states that will be distributed over
        # replicas in a round-robin fashion.
        displacement_vector = np.ones(3) * unit.nanometer
        positions2 = test_system.positions + displacement_vector
        positions3 = positions2 + displacement_vector
        box_vectors = test_system.system.getDefaultPeriodicBoxVectors()
        sampler_state1 = states.SamplerState(positions=test_system.positions,
                                             box_vectors=box_vectors)
        sampler_state2 = states.SamplerState(positions=positions2,
                                             box_vectors=box_vectors)
        sampler_state3 = states.SamplerState(positions=positions3,
                                             box_vectors=box_vectors)
        sampler_states = [sampler_state1, sampler_state2, sampler_state3]

        with self.temporary_storage_path() as storage_path:
            # Create alchemical phase.
            alchemical_phase = AlchemicalPhase(ReplicaExchangeSampler())
            alchemical_phase.create(thermodynamic_state, sampler_states,
                                    topography, self.protocol, storage_path)

            # Measure the average distance between positions. This should be
            # maintained after minimization.
            sampler_states = alchemical_phase._sampler.sampler_states
            original_diffs = [
                np.average(sampler_states[i].positions -
                           sampler_states[i + 1].positions)
                for i in range(len(sampler_states) - 1)
            ]

            # Minimize.
            alchemical_phase.minimize()

            # The minimized positions should be still more or less
            # one displacement vector from each other.
            sampler_states = alchemical_phase._sampler.sampler_states
            new_diffs = [
                np.average(sampler_states[i].positions -
                           sampler_states[i + 1].positions)
                for i in range(len(sampler_states) - 1)
            ]
            assert np.allclose(
                original_diffs, new_diffs, rtol=0.1
            ), "original_diffs {} are not close to new_diffs {}".format(
                original_diffs, new_diffs)
Ejemplo n.º 9
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 def test_illegal_protocol(self):
     """An error is raised when the protocol parameters have a different number of states."""
     name, thermodynamic_state, sampler_state, topography = self.host_guest_implicit
     protocol = {
         'lambda_sterics': [0.0, 1.0],
         'lambda_electrostatics': [1.0]
     }
     alchemical_phase = AlchemicalPhase(sampler=ReplicaExchangeSampler())
     restraint = yank.restraints.Harmonic()
     with nose.tools.assert_raises(ValueError):
         alchemical_phase.create(thermodynamic_state,
                                 sampler_state,
                                 topography,
                                 protocol,
                                 'not_created.nc',
                                 restraint=restraint)
Ejemplo n.º 10
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    def test_from_storage(self):
        """When resuming, the AlchemicalPhase recover the correct sampler."""
        _, thermodynamic_state, sampler_state, topography = self.host_guest_implicit
        restraint = yank.restraints.Harmonic()

        with self.temporary_storage_path() as storage_path:
            alchemical_phase = AlchemicalPhase(ReplicaExchangeSampler())
            alchemical_phase.create(thermodynamic_state, sampler_state, topography,
                                    self.protocol, storage_path, restraint=restraint)

            # Delete old alchemical phase to close storage file.
            del alchemical_phase

            # Resume, the sampler has the correct class.
            alchemical_phase = AlchemicalPhase.from_storage(storage_path)
            assert isinstance(alchemical_phase._sampler, ReplicaExchangeSampler)
Ejemplo n.º 11
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    def test_illegal_restraint(self):
        """Raise an error when restraint is handled incorrectly."""
        # An error is raised with ligand-receptor systems in implicit without restraint.
        test_name, thermodynamic_state, sampler_state, topography = self.host_guest_implicit
        alchemical_phase = AlchemicalPhase(sampler=ReplicaExchangeSampler())
        with nose.tools.assert_raises(ValueError):
            alchemical_phase.create(thermodynamic_state, sampler_state,
                                    topography, self.protocol,
                                    'not_created.nc')

        # An error is raised when trying to apply restraint to non ligand-receptor systems.
        restraint = yank.restraints.Harmonic()
        test_name, thermodynamic_state, sampler_state, topography = self.alanine_explicit
        with nose.tools.assert_raises(RuntimeError):
            alchemical_phase.create(thermodynamic_state,
                                    sampler_state,
                                    topography,
                                    self.protocol,
                                    'not_created.nc',
                                    restraint=restraint)
Ejemplo n.º 12
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def run_replica_exchange(
    topology,
    system,
    positions,
    total_simulation_time=1.0 * unit.picosecond,
    simulation_time_step=None,
    temperature_list=None,
    friction=1.0 / unit.picosecond,
    minimize=True,
    exchange_frequency=1000,
    output_data="output/output.nc",
):
    """
    Run a OpenMMTools replica exchange simulation using an OpenMM coarse grained model.
    
    :param topology: OpenMM Topology
    :type topology: `Topology() <https://simtk.org/api_docs/openmm/api4_1/python/classsimtk_1_1openmm_1_1app_1_1topology_1_1Topology.html>`_

    :param system: OpenMM System()
    :type system: `System() <https://simtk.org/api_docs/openmm/api4_1/python/classsimtk_1_1openmm_1_1openmm_1_1System.html>`_

    :param positions: Positions array for the model we would like to test
    :type positions: `Quantity() <http://docs.openmm.org/development/api-python/generated/simtk.unit.quantity.Quantity.html>`_ ( np.array( [cgmodel.num_beads,3] ), simtk.unit )

    :param total_simulation_time: Total run time for individual simulations
    :type total_simulation_time: `SIMTK <https://simtk.org/>`_ `Unit() <http://docs.openmm.org/7.1.0/api-python/generated/simtk.unit.unit.Unit.html>`_

    :param simulation_time_step: Simulation integration time step
    :type simulation_time_step: `SIMTK <https://simtk.org/>`_ `Unit() <http://docs.openmm.org/7.1.0/api-python/generated/simtk.unit.unit.Unit.html>`_

    :param temperature_list: List of temperatures for which to perform replica exchange simulations, default = None
    :type temperature: List( float * simtk.unit.temperature )

    :param friction: Langevin thermostat friction coefficient, default = 1 / ps
    :type friction: `SIMTK <https://simtk.org/>`_ `Unit() <http://docs.openmm.org/7.1.0/api-python/generated/simtk.unit.unit.Unit.html>`_

    :param minimize: Whether minimization is done before running the simulation
    :type minimize: bool

    :param output_data: Name of NETCDF file where we will write simulation data
    :type output_data: string

    :param exchange_frequency: Number of time steps between replica exchange attempts, Default = None
    :type exchange_frequency: int	

    :param output_data: file to put the output .nc 
    :type output_data: netCDF4 file as generated by OpenMM  

    :returns:
        - replica_energies ( `Quantity() <http://docs.openmm.org/development/api-python/generated/simtk.unit.quantity.Quantity.html>`_ ( np.float( [number_replicas,number_simulation_steps] ), simtk.unit ) ) - The potential energies for all replicas at all (printed) time steps
        - replica_positions ( `Quantity() <http://docs.openmm.org/development/api-python/generated/simtk.unit.quantity.Quantity.html>`_ ( np.float( [number_replicas,number_simulation_steps,cgmodel.num_beads,3] ), simtk.unit ) ) - The positions for all replicas at all (printed) time steps

        - replica_state_indices ( np.int64( [number_replicas,number_simulation_steps] ), simtk.unit ) - The thermodynamic state assignments for all replicas at all (printed) time steps

    :Example:

    >>> from foldamers.cg_model.cgmodel import CGModel
    >>> from cg_openmm.simulation.rep_exch import *
    >>> cgmodel = CGModel()
    >>> replica_energies,replica_positions,replica_state_indices = run_replica_exchange(cgmodel.topology,cgmodel.system,cgmodel.positions)

    """

    simulation_steps = int(
        np.floor(total_simulation_time / simulation_time_step))

    exchange_attempts = int(np.floor(simulation_steps / exchange_frequency))

    if temperature_list is None:
        temperature_list = [((300.0 + i) * unit.kelvin)
                            for i in range(-50, 50, 10)]

    num_replicas = len(temperature_list)
    sampler_states = list()
    thermodynamic_states = list()

    # Define thermodynamic states.
    # box_vectors = system.getDefaultPeriodicBoxVectors()
    for temperature in temperature_list:
        thermodynamic_state = openmmtools.states.ThermodynamicState(
            system=system, temperature=temperature)
        thermodynamic_states.append(thermodynamic_state)
        sampler_states.append(openmmtools.states.SamplerState(
            positions))  # no box vectors, non-periodic system.

    # Create and configure simulation object.
    move = openmmtools.mcmc.LangevinDynamicsMove(
        timestep=simulation_time_step,
        collision_rate=friction,
        n_steps=exchange_frequency,
        reassign_velocities=False,
    )

    simulation = ReplicaExchangeSampler(
        mcmc_moves=move,
        number_of_iterations=exchange_attempts,
        replica_mixing_scheme='swap-neighbors',
    )

    if os.path.exists(output_data):
        os.remove(output_data)

    reporter = MultiStateReporter(output_data, checkpoint_interval=1)
    simulation.create(thermodynamic_states, sampler_states, reporter)

    if minimize:
        simulation.minimize()

    print("Running replica exchange simulations with OpenMM...")
    print(f"Using a time step of {simulation_time_step}")
    try:
        simulation.run()
    except BaseException:
        print(
            "Replica exchange simulation failed, try verifying your model/simulation settings."
        )
        exit()
Ejemplo n.º 13
0
            else:
                restraint = None
                protocol = self.protocol

            # Add either automatic of fixed correction cutoff.
            if test_index % 2 == 0:
                correction_cutoff = 12 * unit.angstroms
            else:
                correction_cutoff = 'auto'

            # Replace the reaction field of the reference system to compare
            # also cutoff and switch width for the electrostatics.
            reference_system = thermodynamic_state.system
            mmtools.forcefactories.replace_reaction_field(reference_system, return_copy=False)

            alchemical_phase = AlchemicalPhase(sampler=ReplicaExchangeSampler())
            with self.temporary_storage_path() as storage_path:
                alchemical_phase.create(thermodynamic_state, sampler_state, topography,
                                        protocol, storage_path, restraint=restraint,
                                        anisotropic_dispersion_cutoff=correction_cutoff)

                yield prepare_yield(self.check_protocol, test_name, alchemical_phase, protocol)
                yield prepare_yield(self.check_standard_state_correction, test_name, alchemical_phase,
                                    topography, restraint)
                yield prepare_yield(self.check_expanded_states, test_name, alchemical_phase,
                                    protocol, correction_cutoff, reference_system)

                # Free memory.
                del alchemical_phase

    def test_default_alchemical_region(self):
Ejemplo n.º 14
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    def __init__(self, config_: Config, old_sampler_state=None):
        """

        :param systemLoader:
        :param config:
        """
        self._times = None
        self.config = config_
        self.logger = make_message_writer(self.config.verbose,
                                          self.__class__.__name__)
        with self.logger("__init__") as logger:
            self.explicit = self.config.systemloader.explicit
            self.amber = bool(
                self.config.systemloader.config.method == 'amber')
            self._trajs = np.zeros((1, 1))
            self._id_number = int(self.config.systemloader.params_written)

            if self.config.systemloader.system is None:
                self.system = self.config.systemloader.get_system(
                    self.config.parameters.createSystem)
                cache.global_context_cache.set_platform(
                    self.config.parameters.platform,
                    self.config.parameters.platform_config)
                cache.global_context_cache.time_to_live = 10

            else:
                self.system = self.config.systemloader.system
            self.topology = self.config.systemloader.topology
            positions, velocities = self.config.systemloader.get_positions(
            ), None

            sequence_move = mmWrapperUtils.prepare_mcmc(
                self.topology, self.config)

            thermo_states = [
                openmmtools.states.ThermodynamicState(
                    copy.deepcopy(self.system),
                    temperature=t,
                    pressure=1.0 * unit.atmosphere
                    if self.config.systemloader.explicit else None)
                for t in self.config.temps_in_k
            ]

            if self.explicit:
                sampler_states = [
                    openmmtools.states.SamplerState(
                        positions=positions,
                        velocities=velocities,
                        box_vectors=self.config.systemloader.boxvec)
                    for _ in thermo_states
                ]
            else:
                sampler_states = [
                    openmmtools.states.SamplerState(positions=positions,
                                                    velocities=velocities)
                    for _ in thermo_states
                ]

            self.simulation = ReplicaExchangeSampler(mcmc_moves=sequence_move,
                                                     number_of_iterations=500)
            self.storage_path = tempfile.NamedTemporaryFile(
                delete=True).name + '.nc'
            self.reporter = openmmtools.multistate.MultiStateReporter(
                self.storage_path, checkpoint_interval=10)
            self.simulation.create(thermodynamic_states=thermo_states,
                                   sampler_states=sampler_states,
                                   storage=self.reporter)

            logger.log("Minimizing...", self.simulation.Status)
            self.simulation.minimize(
                max_iterations=self.config.parameters.minMaxIters)
            self.simulation.equilibrate(1)
            logger.log("Done, minimizing...", self.simulation.Status)
Ejemplo n.º 15
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class MCMCReplicaExchangeOpenMMSimulationWrapper:
    class Config(Config):
        def __init__(self, args):
            self.t_max_k = None
            self.t_min_k = None
            self.n_replicas = None
            self.temps_in_k = None
            self.hybrid = None
            self.ligand_pertubation_samples = None
            self.displacement_sigma = None
            self.verbose = None
            self.n_steps = None
            self.parameters = mmWrapperUtils.SystemParams(args['params'])
            self.warmupparameters = None
            if "warmupparams" in args:
                self.warmupparameters = mmWrapperUtils.SystemParams(
                    args['warmupparams'])

            self.systemloader = None
            if args is not None:
                self.__dict__.update(args)

            if self.temps_in_k is None:
                self.T_min = self.t_min_k * unit.kelvin  # Minimum temperature.
                self.T_max = self.t_max_k * unit.kelvin  # Maximum temperature.
                self.temps_in_k = [
                    self.T_min + (self.T_max - self.T_min) *
                    (math.exp(float(i) / float(self.n_replicas - 1)) - 1.0) /
                    (math.e - 1.0) for i in range(self.n_replicas)
                ]
                print("MCMCReplicaExchange Temps", self.temps_in_k)
            elif None in [self.T_min, self.T_max, self.n_replicas]:
                self.temps_in_k = self.temps_in_k * unit.kelvin
                self.T_min = min(self.temps_in_k)
                self.T_max = max(self.temps_in_k)
                self.n_replicas = len(self.temps_in_k)
            else:
                assert (False)

        def get_obj(self, system_loader, *args, **kwargs):
            self.systemloader = system_loader
            return MCMCReplicaExchangeOpenMMSimulationWrapper(
                self, *args, **kwargs)

    def __init__(self, config_: Config, old_sampler_state=None):
        """

        :param systemLoader:
        :param config:
        """
        self._times = None
        self.config = config_
        self.logger = make_message_writer(self.config.verbose,
                                          self.__class__.__name__)
        with self.logger("__init__") as logger:
            self.explicit = self.config.systemloader.explicit
            self.amber = bool(
                self.config.systemloader.config.method == 'amber')
            self._trajs = np.zeros((1, 1))
            self._id_number = int(self.config.systemloader.params_written)

            if self.config.systemloader.system is None:
                self.system = self.config.systemloader.get_system(
                    self.config.parameters.createSystem)
                cache.global_context_cache.set_platform(
                    self.config.parameters.platform,
                    self.config.parameters.platform_config)
                cache.global_context_cache.time_to_live = 10

            else:
                self.system = self.config.systemloader.system
            self.topology = self.config.systemloader.topology
            positions, velocities = self.config.systemloader.get_positions(
            ), None

            sequence_move = mmWrapperUtils.prepare_mcmc(
                self.topology, self.config)

            thermo_states = [
                openmmtools.states.ThermodynamicState(
                    copy.deepcopy(self.system),
                    temperature=t,
                    pressure=1.0 * unit.atmosphere
                    if self.config.systemloader.explicit else None)
                for t in self.config.temps_in_k
            ]

            if self.explicit:
                sampler_states = [
                    openmmtools.states.SamplerState(
                        positions=positions,
                        velocities=velocities,
                        box_vectors=self.config.systemloader.boxvec)
                    for _ in thermo_states
                ]
            else:
                sampler_states = [
                    openmmtools.states.SamplerState(positions=positions,
                                                    velocities=velocities)
                    for _ in thermo_states
                ]

            self.simulation = ReplicaExchangeSampler(mcmc_moves=sequence_move,
                                                     number_of_iterations=500)
            self.storage_path = tempfile.NamedTemporaryFile(
                delete=True).name + '.nc'
            self.reporter = openmmtools.multistate.MultiStateReporter(
                self.storage_path, checkpoint_interval=10)
            self.simulation.create(thermodynamic_states=thermo_states,
                                   sampler_states=sampler_states,
                                   storage=self.reporter)

            logger.log("Minimizing...", self.simulation.Status)
            self.simulation.minimize(
                max_iterations=self.config.parameters.minMaxIters)
            self.simulation.equilibrate(1)
            logger.log("Done, minimizing...", self.simulation.Status)

    def run(self, iters, steps_per_iter, idx=0):
        """

        :param steps:
        """
        with self.logger("run") as logger:

            if 'cur_sim_steps' not in self.__dict__:
                self.cur_sim_steps = 0.0 * unit.picosecond

            pbar = tqdm(
                range(1),
                desc="running {} steps per sample".format(steps_per_iter))
            # self._trajs = np.zeros((iters, self.system.getNumParticles(), 3))
            # self._times = np.zeros((iters))
            # dcdreporter = DCDReporter(f"{self.config.tempdir()}/traj.dcd", 1, append=False)
            for i in pbar:
                self.simulation.run(1)
                # self.cur_sim_steps += (steps_per_iter * self.get_sim_time())
                #
                # positions = self.simulation.sampler_states[idx].positions
                # boxvectors = self.simulation.sampler_states[idx].box_vectors
                #
                # dcdreporter.report_ns(self.topology, positions, boxvectors, (i + 1), 0.5 * unit.femtosecond)
                #
                # log trajectory
                # self._trajs[i] = np.array(positions.value_in_unit(unit.angstrom)).reshape(
                #     (self.system.getNumParticles(), 3))
                # self._times[i] = self.cur_sim_steps.value_in_unit(unit.picosecond)
            pbar.close()
            exit()

    def writetraj(self, idx=0):
        if self.explicit:
            lengths, angles = mmWrapperUtils.get_mdtraj_box(
                boxvec=self.simulation.sampler_states[idx].box_vectors,
                iterset=self._trajs.shape[0])
            traj = md.Trajectory(self._trajs,
                                 md.Topology.from_openmm(self.topology),
                                 unitcell_lengths=lengths,
                                 unitcell_angles=angles,
                                 time=self._times)
            traj.image_molecules(inplace=True)
        else:
            traj = md.Trajectory(self._trajs,
                                 md.Topology.from_openmm(self.topology),
                                 time=self._times)

        traj.save_hdf5(f'{self.config.tempdir()}/mdtraj_traj.h5')

    def run_amber_mmgbsa(self, run_decomp=False):
        mmWrapperUtils.run_amber_mmgbsa(self.logger,
                                        self.explicit,
                                        self.config.tempdir(),
                                        run_decomp=run_decomp)

    def get_sim_time(self):
        return self.config.n_steps * self.config.parameters.integrator_params[
            'timestep']

    def get_velocities(self, idx=0):
        return self.simulation.sampler_states[idx].velocities

    def get_coordinates(self, idx=0):
        return mmWrapperUtils.get_coordinates_samplers(
            self.topology, self.simulation.sampler_states[idx], self.explicit)

    def get_pdb(self, file_name=None, idx=0):
        mmWrapperUtils.get_pdb(self.topology,
                               self.get_coordinates(idx),
                               file_name=file_name)