def create_state_from_gsd(self, filename, frame=-1): """Create the simulation state from a GSD file. Args: filename (str): GSD file to read frame (int): Index of the frame to read from the file. Negative values index back from the last frame in the file. """ if self.state is not None: raise RuntimeError("Cannot initialize more than once\n") filename = _hoomd.mpi_bcast_str(filename, self.device._cpp_exec_conf) # Grab snapshot and timestep reader = _hoomd.GSDReader(self.device._cpp_exec_conf, filename, abs(frame), frame < 0) snapshot = Snapshot._from_cpp_snapshot(reader.getSnapshot(), self.device.communicator) step = reader.getTimeStep() if self.timestep is None else self.timestep self._state = State(self, snapshot) reader.clearSnapshot() # Store System and Reader for Operations self._cpp_sys = _hoomd.System(self.state._cpp_sys_def, step) self._init_communicator() self.operations._store_reader(reader)
def create_state_from_snapshot(self, snapshot): """Create the simulations state from a `Snapshot`. Args: snapshot (Snapshot or gsd.hoomd.Snapshot): Snapshot to initialize the state from. A `gsd.hoomd.Snapshot` will first be converted to a `hoomd.Snapshot`. When `timestep` is `None` before calling, `create_state_from_snapshot` sets `timestep` to 0. """ if self.state is not None: raise RuntimeError("Cannot initialize more than once\n") if isinstance(snapshot, Snapshot): # snapshot is hoomd.Snapshot self._state = State(self, snapshot) elif _match_class_path(snapshot, 'gsd.hoomd.Snapshot'): # snapshot is gsd.hoomd.Snapshot snapshot = Snapshot._from_gsd_snapshot(snapshot, self._device.communicator) self._state = State(self, snapshot) else: raise TypeError( "Snapshot must be a hoomd.Snapshot or gsd.hoomd.Snapshot.") step = 0 if self.timestep is not None: step = self.timestep # Store System and Reader for Operations self._cpp_sys = _hoomd.System(self.state._cpp_sys_def, step) self._init_communicator()
def create_state_from_snapshot(self, snapshot): """Create the simulations state from a `Snapshot`. Args: snapshot (Snapshot): Snapshot to initialize the state from. When `timestep` is `None` before calling, `create_state_from_snapshot` sets `timestep` to 0. Warning: *snapshot* must be a `hoomd.Snapshot`. Use `create_state_from_gsd` to read GSD files. `create_state_from_snapshot` does not support ``gsd.hoomd.Snapshot`` objects from the ``gsd`` Python package. """ if self.state is not None: raise RuntimeError("Cannot initialize more than once\n") self._state = State(self, snapshot) step = 0 if self.timestep is not None: step = self.timestep # Store System and Reader for Operations self._cpp_sys = _hoomd.System(self.state._cpp_sys_def, step) self._init_communicator()
def read_gsd(filename, restart=None, frame=0, time_step=None): R""" Read initial system state from an GSD file. Args: filename (str): File to read. restart (str): If it exists, read the file *restart* instead of *filename*. frame (int): Index of the frame to read from the GSD file. time_step (int): (if specified) Time step number to initialize instead of the one stored in the GSD file. All particles, bonds, angles, dihedrals, impropers, constraints, and box information are read from the given GSD file at the given frame index. To read and write GSD files outside of hoomd, see http://gsd.readthedocs.io/. :py:class:`hoomd.dump.gsd` writes GSD files. For restartable jobs, specify the initial condition in *filename* and the restart file in *restart*. :py:func:`hoomd.init.read_gsd` will read the restart file if it exists, otherwise it will read *filename*. If *time_step* is specified, its value will be used as the initial time step of the simulation instead of the one read from the GSD file. The result of :py:func:`hoomd.init.read_gsd` can be saved in a variable and later used to read and/or change particle properties later in the script. See :py:mod:`hoomd.data` for more information. See Also: :py:class:`hoomd.dump.gsd` """ hoomd.util.print_status_line() hoomd.context._verify_init() # check if initialization has already occured if is_initialized(): hoomd.context.msg.error("Cannot initialize more than once\n") raise RuntimeError("Error initializing") if restart is not None and os.path.exists(restart): reader = _hoomd.GSDReader(hoomd.context.exec_conf, restart, frame) else: reader = _hoomd.GSDReader(hoomd.context.exec_conf, filename, frame) snapshot = reader.getSnapshot() if time_step is None: time_step = reader.getTimeStep() # broadcast snapshot metadata so that all ranks have _global_box (the user may have set box only on rank 0) snapshot._broadcast(hoomd.context.exec_conf) my_domain_decomposition = _create_domain_decomposition( snapshot._global_box) if my_domain_decomposition is not None: hoomd.context.current.system_definition = _hoomd.SystemDefinition( snapshot, hoomd.context.exec_conf, my_domain_decomposition) else: hoomd.context.current.system_definition = _hoomd.SystemDefinition( snapshot, hoomd.context.exec_conf) # initialize the system hoomd.context.current.system = _hoomd.System( hoomd.context.current.system_definition, time_step) _perform_common_init_tasks() return hoomd.data.system_data(hoomd.context.current.system_definition)
def _init_system(self, step): """Initialize the system State. Perform additional initialization operations not in the State constructor. """ self._cpp_sys = _hoomd.System(self.state._cpp_sys_def, step) if self._seed is not None: self._state._cpp_sys_def.setSeed(self._seed) self._init_communicator()
def read_snapshot(snapshot): R""" Initializes the system from a snapshot. Args: snapshot (:py:mod:`hoomd.data` snapshot): The snapshot to initialize the system. Snapshots temporarily store system data. Snapshots contain the complete simulation state in a single object. Snapshots are set to time_step 0, and should not be used to restart a simulation. Example use cases in which a simulation may be started from a snapshot include user code that generates initial particle positions. Example:: snapshot = my_system_create_routine(.. parameters ..) system = init.read_snapshot(snapshot) See Also: :py:mod:`hoomd.data` """ hoomd.util.print_status_line() hoomd.context._verify_init() # check if initialization has already occurred if is_initialized(): hoomd.context.msg.error("Cannot initialize more than once\n") raise RuntimeError("Error initializing") # broadcast snapshot metadata so that all ranks have _global_box (the user may have set box only on rank 0) snapshot._broadcast_box(hoomd.context.exec_conf) my_domain_decomposition = _create_domain_decomposition( snapshot._global_box) if my_domain_decomposition is not None: hoomd.context.current.system_definition = _hoomd.SystemDefinition( snapshot, hoomd.context.exec_conf, my_domain_decomposition) else: hoomd.context.current.system_definition = _hoomd.SystemDefinition( snapshot, hoomd.context.exec_conf) # initialize the system hoomd.context.current.system = _hoomd.System( hoomd.context.current.system_definition, 0) _perform_common_init_tasks() return hoomd.data.system_data(hoomd.context.current.system_definition)
def create_random(N, phi_p=None, name="A", min_dist=0.7, box=None, seed=1, dimensions=3): R""" Generates N randomly positioned particles of the same type. Args: N (int): Number of particles to create. phi_p (float): Packing fraction of particles in the simulation box (unitless). name (str): Name of the particle type to create. min_dist (float): Minimum distance particles will be separated by (in distance units). box (:py:class:`hoomd.data.boxdim`): Simulation box dimensions. seed (int): Random seed. dimensions (int): The number of dimensions in the simulation. .. deprecated:: 2.0 Random initialization is best left to specific methods tailored by the user for their work. Either *phi_p* or *box* must be specified. If *phi_p* is provided, it overrides the value of *box*. Examples:: init.create_random(N=2400, phi_p=0.20) init.create_random(N=2400, phi_p=0.40, min_dist=0.5) system = init.create_random(N=2400, box=data.boxdim(L=20)) When *phi_p* is set, the dimensions of the created box are such that the packing fraction of particles in the box is *phi_p*. The number density \e n is related to the packing fraction by :math:`n = 2d/\pi \cdot \phi_P`, where *d* is the dimension, and assumes the particles have a radius of 0.5. All particles are created with the same type, given by *name*. The result of :py:func:`hoomd.deprecated.init.create_random` can be saved in a variable and later used to read and/or change particle properties later in the script. See :py:mod:`hoomd.data` for more information. """ hoomd.util.print_status_line(); hoomd.context._verify_init(); # check if initialization has already occurred if hoomd.init.is_initialized(): hoomd.context.msg.error("Cannot initialize more than once\n"); raise RuntimeError("Error initializing"); # check that dimensions are appropriate if dimensions not in (2,3): raise ValueError('dimensions must be 2 or 3') # abuse the polymer generator to generate single particles if phi_p is not None: # calculate the box size L = math.pow(math.pi/(2.0*dimensions)*N / phi_p, 1.0/dimensions); box = hoomd.data.boxdim(L=L, dimensions=dimensions); if box is None: raise RuntimeError('box or phi_p must be specified'); if not isinstance(box, hoomd.data.boxdim): hoomd.context.msg.error('box must be a data.boxdim object'); raise TypeError('box must be a data.boxdim object'); # create the generator generator = _deprecated.RandomGenerator(hoomd.context.exec_conf, box._getBoxDim(), seed, box.dimensions); # build type list type_vector = _hoomd.std_vector_string(); type_vector.append(name); # empty bond lists for single particles bond_ab = _hoomd.std_vector_uint(); bond_type = _hoomd.std_vector_string(); # create the generator generator.addGenerator(int(N), _deprecated.PolymerParticleGenerator(hoomd.context.exec_conf, 1.0, type_vector, bond_ab, bond_ab, bond_type, 100, box.dimensions)); # set the separation radius generator.setSeparationRadius(name, min_dist/2.0); # generate the particles generator.generate(); # initialize snapshot snapshot = generator.getSnapshot() my_domain_decomposition = hoomd.init._create_domain_decomposition(snapshot._global_box); if my_domain_decomposition is not None: hoomd.context.current.system_definition = _hoomd.SystemDefinition(snapshot, hoomd.context.exec_conf, my_domain_decomposition); else: hoomd.context.current.system_definition = _hoomd.SystemDefinition(snapshot, hoomd.context.exec_conf); # initialize the system hoomd.context.current.system = _hoomd.System(hoomd.context.current.system_definition, 0); hoomd.init._perform_common_init_tasks(); return hoomd.data.system_data(hoomd.context.current.system_definition);
def create_random_polymers(box, polymers, separation, seed=1): R""" Generates any number of randomly positioned polymers of configurable types. Args: box (:py:class:`hoomd.data.boxdim`): Simulation box dimensions polymers (list): Specification for the different polymers to create (see below) separation (dict): Separation radii for different particle types (see below) seed (int): Random seed to use .. deprecated:: 2.0 Random initialization is best left to specific methods tailored by the user for their work. Any number of polymers can be generated, of the same or different types, as specified in the argument *polymers*. Parameters for each polymer include bond length, particle type list, bond list, and count. The syntax is best shown by example. The below line specifies that 600 block copolymers A6B7A6 with a bond length of 1.2 be generated:: polymer1 = dict(bond_len=1.2, type=['A']*6 + ['B']*7 + ['A']*6, bond="linear", count=600) Here is an example for a second polymer, specifying just 100 polymers made of 5 B beads bonded in a branched pattern:: polymer2 = dict(bond_len=1.2, type=['B']*5, bond=[(0, 1), (1,2), (1,3), (3,4)] , count=100) The *polymers* argument can be given a list of any number of polymer types specified as above. *count* randomly generated polymers of each type in the list will be generated in the system. In detail: - bond_len defines the bond length of the generated polymers. This should not necessarily be set to the equilibrium bond length! The generator is dumb and doesn't know that bonded particles can be placed closer together than the separation (see below). Thus bond_len must be at a minimum set at twice the value of the largest separation radius. An error will be generated if this is not the case. - type is a python list of strings. Each string names a particle type in the order that they will be created in generating the polymer. - bond can be specified as "linear" in which case the generator connects all particles together with bonds to form a linear chain. bond can also be given a list if python tuples (see example above). - Each tuple in the form of \c (a,b) specifies that particle \c a of the polymer be bonded to particle \c b. These bonds are given the default type name of 'polymer' to be used when specifying parameters to bond forces such as bond.harmonic. - A tuple with three elements (a,b,type) can be used as above, but with a custom name for the bond. For example, a simple branched polymer with different bond types on each branch could be defined like so:: bond=[(0,1), (1,2), (2,3,'branchA'), (3,4,'branchA), (2,5,'branchB'), (5,6,'branchB')] separation must contain one entry for each particle type specified in polymers ('A' and 'B' in the examples above). The value given is the separation radius of each particle of that type. The generated polymer system will have no two overlapping particles. Examples:: init.create_random_polymers(box=data.boxdim(L=35), polymers=[polymer1, polymer2], separation=dict(A=0.35, B=0.35)); init.create_random_polymers(box=data.boxdim(L=31), polymers=[polymer1], separation=dict(A=0.35, B=0.35), seed=52); # create polymers in an orthorhombic box init.create_random_polymers(box=data.boxdim(Lx=18,Ly=10,Lz=25), polymers=[polymer2], separation=dict(A=0.35, B=0.35), seed=12345); # create a triclinic box with tilt factors xy=0.1 xz=0.2 yz=0.3 init.create_random_polymers(box=data.boxdim(L=18, xy=0.1, xz=0.2, yz=0.3), polymers=[polymer2], separation=dict(A=0.35, B=0.35)); With all other parameters the same, create_random_polymers will always create the same system if seed is the same. Set a different seed (any integer) to create a different random system with the same parameters. Note that different versions of HOOMD \e may generate different systems even with the same seed due to programming changes. Note: For relatively dense systems (packing fraction 0.4 and higher) the simple random generation algorithm may fail to find room for all the particles and print an error message. There are two methods to solve this. First, you can lower the separation radii allowing particles to be placed closer together. Then setup integrate.nve with the limit option set to a relatively small value. A few thousand time steps should relax the system so that the simulation can be continued without the limit or with a different integrator. For extremely troublesome systems, generate it at a very low density and shrink the box with the command update.box_resize to the desired final size. Note: The polymer generator always generates polymers as if there were linear chains. If you provide a non-linear bond topology, the bonds in the initial configuration will be stretched significantly. This normally doesn't pose a problem for harmonic bonds (bond.harmonic) as the system will simply relax over a few time steps, but can cause the system to blow up with FENE bonds (bond.fene). """ hoomd.util.print_status_line(); hoomd.context._verify_init(); # check if initialization has already occurred if hoomd.init.is_initialized(): hoomd.context.msg.error("Cannot initialize more than once\n"); raise RuntimeError("Error creating random polymers"); if len(polymers) == 0: hoomd.context.msg.error("Polymers list cannot be empty.\n"); raise RuntimeError("Error creating random polymers"); if len(separation) == 0: hoomd.context.msg.error("Separation dict cannot be empty.\n"); raise RuntimeError("Error creating random polymers"); if not isinstance(box, hoomd.data.boxdim): hoomd.context.msg.error('Box must be a data.boxdim object\n'); raise TypeError('box must be a data.boxdim object'); # create the generator generator = _deprecated.RandomGenerator(hoomd.context.exec_conf,box._getBoxDim(), seed, box.dimensions); # make a list of types used for an eventual check vs the types in separation for completeness types_used = []; # track the minimum bond length min_bond_len = None; # build the polymer generators for poly in polymers: type_list = []; # check that all fields are specified if not 'bond_len' in poly: hoomd.context.msg.error('Polymer specification missing bond_len\n'); raise RuntimeError("Error creating random polymers"); if min_bond_len is None: min_bond_len = poly['bond_len']; else: min_bond_len = min(min_bond_len, poly['bond_len']); if not 'type' in poly: hoomd.context.msg.error('Polymer specification missing type\n'); raise RuntimeError("Error creating random polymers"); if not 'count' in poly: hoomd.context.msg.error('Polymer specification missing count\n'); raise RuntimeError("Error creating random polymers"); if not 'bond' in poly: hoomd.context.msg.error('Polymer specification missing bond\n'); raise RuntimeError("Error creating random polymers"); # build type list type_vector = _hoomd.std_vector_string(); for t in poly['type']: type_vector.append(t); if not t in types_used: types_used.append(t); # build bond list bond_a = _hoomd.std_vector_uint(); bond_b = _hoomd.std_vector_uint(); bond_name = _hoomd.std_vector_string(); # if the bond setting is 'linear' create a default set of bonds if poly['bond'] == 'linear': for i in range(0,len(poly['type'])-1): bond_a.append(i); bond_b.append(i+1); bond_name.append('polymer') #if it is a list, parse the user custom bonds elif type(poly['bond']) == type([]): for t in poly['bond']: # a 2-tuple gets the default 'polymer' name for the bond if len(t) == 2: a,b = t; name = 'polymer'; # and a 3-tuple specifies the name directly elif len(t) == 3: a,b,name = t; else: hoomd.context.msg.error('Custom bond ' + str(t) + ' must have either two or three elements\n'); raise RuntimeError("Error creating random polymers"); bond_a.append(a); bond_b.append(b); bond_name.append(name); else: hoomd.context.msg.error('Unexpected argument value for polymer bond\n'); raise RuntimeError("Error creating random polymers"); # create the generator generator.addGenerator(int(poly['count']), _deprecated.PolymerParticleGenerator(hoomd.context.exec_conf, poly['bond_len'], type_vector, bond_a, bond_b, bond_name, 100, box.dimensions)); # check that all used types are in the separation list for t in types_used: if not t in separation: hoomd.context.msg.error("No separation radius specified for type " + str(t) + "\n"); raise RuntimeError("Error creating random polymers"); # set the separation radii, checking that it is within the minimum bond length for t,r in separation.items(): generator.setSeparationRadius(t, r); if 2*r >= min_bond_len: hoomd.context.msg.error("Separation radius " + str(r) + " is too big for the minimum bond length of " + str(min_bond_len) + " specified\n"); raise RuntimeError("Error creating random polymers"); # generate the particles generator.generate(); # copy over data to snapshot snapshot = generator.getSnapshot() my_domain_decomposition = hoomd.init._create_domain_decomposition(snapshot._global_box); if my_domain_decomposition is not None: hoomd.context.current.system_definition = _hoomd.SystemDefinition(snapshot, hoomd.context.exec_conf, my_domain_decomposition); else: hoomd.context.current.system_definition = _hoomd.SystemDefinition(snapshot, hoomd.context.exec_conf); # initialize the system hoomd.context.current.system = _hoomd.System(hoomd.context.current.system_definition, 0); hoomd.init._perform_common_init_tasks(); return hoomd.data.system_data(hoomd.context.current.system_definition);
def read_xml(filename, restart = None, time_step = None, wrap_coordinates = False): R""" ## Reads initial system state from an XML file Args: filename (str): File to read restart (str): If it exists, read *restart* instead of *filename*. time_step (int): (if specified) Time step number to use instead of the one stored in the XML file wrap_coordinates (bool): Wrap input coordinates back into the box .. deprecated:: 2.0 GSD is the new default file format for HOOMD-blue. It can store everything that an XML file can in an efficient binary format that is easy to access. See :py:class:`hoomd.init.read_gsd`. Examples:: deprecated.init.read_xml(filename="data.xml") deprecated.init.read_xml(filename="init.xml", restart="restart.xml") deprecated.init.read_xml(filename="directory/data.xml") deprecated.init.read_xml(filename="restart.xml", time_step=0) system = deprecated.init.read_xml(filename="data.xml") All particles, bonds, etc... are read from the given XML file, setting the initial condition of the simulation. After this command completes, the system is initialized allowing other commands in hoomd to be run. For restartable jobs, specify the initial condition in *filename* and the restart file in *restart*. init.read_xml will read the restart file if it exists, otherwise it will read *filename*. All values are read in native units, see :ref:`page-units` for more information. If *time_step* is specified, its value will be used as the initial time step of the simulation instead of the one read from the XML file. If *wrap_coordinates* is set to True, input coordinates will be wrapped into the box specified inside the XML file. If it is set to False, out-of-box coordinates will result in an error. """ hoomd.util.print_status_line(); hoomd.context._verify_init(); # check if initialization has already occurred if hoomd.init.is_initialized(): hoomd.context.msg.error("Cannot initialize more than once\n"); raise RuntimeError("Error reading XML file"); filename_to_read = filename; if restart is not None: if os.path.isfile(restart): filename_to_read = restart; # read in the data initializer = _deprecated.HOOMDInitializer(hoomd.context.exec_conf,filename_to_read,wrap_coordinates); snapshot = initializer.getSnapshot() my_domain_decomposition = hoomd.init._create_domain_decomposition(snapshot._global_box); if my_domain_decomposition is not None: hoomd.context.current.system_definition = _hoomd.SystemDefinition(snapshot, hoomd.context.exec_conf, my_domain_decomposition); else: hoomd.context.current.system_definition = _hoomd.SystemDefinition(snapshot, hoomd.context.exec_conf); # initialize the system if time_step is None: hoomd.context.current.system = _hoomd.System(hoomd.context.current.system_definition, initializer.getTimeStep()); else: hoomd.context.current.system = _hoomd.System(hoomd.context.current.system_definition, time_step); hoomd.init._perform_common_init_tasks(); return hoomd.data.system_data(hoomd.context.current.system_definition);
def read_getar(filename, modes={'any': 'any'}): """Initialize a system from a trajectory archive (.tar, .getar, .sqlite) file. Returns a HOOMD `system_data` object. Args: filename (str): Name of the file to read from modes (dict): dictionary of {property: frame} values; see below Getar files are a simple interface on top of archive formats (such as zip and tar) for storing trajectory data efficiently. A more thorough description of the format and a description of a python API to read and write these files is available at `the libgetar documentation <http://libgetar.readthedocs.io>`_. The **modes** argument is a dictionary. The keys of this dictionary should be either property names (see the Supported Property Table below) or tuples of property names. If the key is a tuple of property names, data for those names will be restored from the same frame. Other acceptable keys are "any" to restore any properties which are present from the file, "angle_any" to restore any angle-related properties present, "bond_any", and so forth. The values associated with each key in the dictionary should be "any" (in which case any frame present for the data will be restored, even if the frames are different for two property names in a tuple), "latest" (grab the most recent frame data), "earliest", or a specific timestep value. Example:: # creating file to initialize beforehand using libgetar with gtar.GTAR('init.zip', 'w') as traj: traj.writePath('position.f32.ind', positions) traj.writePath('velocity.f32.ind', velocities) traj.writePath('metadata.json', json.dumps(metadata)) system = hoomd.init.read_getar('init.zip') # using the backup created in the `hoomd.dump.getar.simple` example system = hoomd.init.read_getar('backup.tar') **Supported Property Table** .. tabularcolumns:: |p{0.25 \textwidth}|p{0.1 \textwidth}|p{0.2 \textwidth}|p{0.45 \textwidth}| .. csv-table:: :header: "Name", "Type", "Shape", "Notes" :widths: 1, 1, 1, 5 "angle_type_names", "JSON [String]", "(N_angle_types,)", "list containing the name of each angle type in JSON format" "angle_tag", "unsigned int", "(N_angle, 3)", "array of particle tags for each angle interaction" "angle_type", "unsigned int", "(N_angle,)", "array of angle interaction types" "angular_momentum", "float", "(N, 4)", "per-particle angular momentum quaternion" "body", "int", "(N,)", "particle rigid body index" "bond_type_names", "JSON [String]", "(N_bond_types,)", "list containing the name of each bond type in JSON format" "bond_tag", "unsigned int", "(N_bond, 2)", "array of particle tags for each bond interaction" "bond_type", "unsigned int", "(N_bond,)", "array of bond interaction types" "box", "float", "(6,)", "vector of box lengths (x, y, z, tilt_xy, tilt_xz, tilt_yz); can be high precision" "charge", "float", "(N,)", "particle charge" "diameter", "float", "(N,)", "particle diameter" "dihedral_type_names", "JSON [String]", "(N_dihedral_types,)", "list containing the name of each dihedral type in JSON format" "dihedral_tag", "unsigned int", "(N_dihedral, 4)", "array of particle tags for each dihedral interaction" "dihedral_type", "unsigned int", "(N_dihedral,)", "array of dihedral interaction types" "dimensions", "unsigned int", "1", "number of dimensions of the system" "image", "int", "(N, 3)", "how many times each particle has passed through the periodic boundary conditions" "improper_type_names", "JSON [String]", "(N_improper_types,)", "list containing the name of each improper type in JSON format" "improper_tag", "unsigned int", "(N_improper, 4)", "array of particle tags for each improper interaction" "improper_type", "unsigned int", "(N_improper,)", "array of improper interaction types" "mass", "float", "(N,)", "particle mass" "moment_inertia", "float", "(N, 3)", "moment of inertia of each particle (diagonalized)." "orientation", "float", "(N, 4)", "particle orientation, expressed as a quaternion in the order (real, imag_i, imag_j, imag_k); can be high precision" "position", "float", "(N, 3)", "the position of each particle in the system (can be high precision)" "potential_energy", "float", "(N,)", "per-particle potential energy; can't be used in MPI runs" "type", "unsigned int", "(N,)", "particle numerical type index" "type_names", "JSON [String]", "(N_types,)", "list containing the name of each particle type in JSON format" "velocity", "float", "(N, 3)", "velocity of each particle in the system" """ hoomd.context._verify_init(); # check if initialization has already occurred if is_initialized(): raise RuntimeError("Cannot initialize more than once\n"); newModes = _parse_getar_modes(modes); # read in the data initializer = _hoomd.GetarInitializer(hoomd.context.current.device.cpp_exec_conf, filename); snapshot = initializer.initialize(newModes); # broadcast snapshot metadata so that all ranks have _global_box (the user may have set box only on rank 0) snapshot._broadcast_box(hoomd.context.current.device.cpp_exec_conf); try: box = snapshot._global_box; except AttributeError: box = snapshot.box; my_domain_decomposition = _create_domain_decomposition(box); if my_domain_decomposition is not None: hoomd.context.current.system_definition = _hoomd.SystemDefinition( snapshot, hoomd.context.current.device.cpp_exec_conf, my_domain_decomposition); else: hoomd.context.current.system_definition = _hoomd.SystemDefinition( snapshot, hoomd.context.current.device.cpp_exec_conf); hoomd.context.current.system = _hoomd.System( hoomd.context.current.system_definition, initializer.getTimestep()); _perform_common_init_tasks(); if (hoomd.data.get_snapshot_box(snapshot).dimensions == 2 and any(abs(z) > 1e-5 for z in snapshot.particles.position[:, 2])): raise RuntimeWarning('Initializing a 2D system with some z ' 'components out-of-plane'); return hoomd.data.system_data(hoomd.context.current.system_definition);