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- #!/usr/bin/env python3
- """
- Main script for creating scaled versions of NeuroML network and simulating it.
- This parses population and connectivity information exported from circuit.py to
- create a NeuroML representation of the network.
- File: nml_main.py
- Copyright 2023 Ankur Sinha
- """
- import argparse
- import bisect
- import copy
- import inspect
- import logging
- import math
- import pathlib
- import random
- import sys
- import textwrap
- import time
- import typing
- import h5py
- import lems.api as lems
- import neuroml
- import numpy
- import pandas
- import progressbar
- from neuroml.loaders import read_neuroml2_file
- from neuroml.utils import component_factory
- from neuroml.writers import NeuroMLHdf5Writer
- from pyneuroml.lems.LEMSSimulation import LEMSSimulation
- from pyneuroml.neuron.nrn_export_utils import get_segment_group_name
- from pyneuroml.nsgr import run_on_nsg
- from pyneuroml.plot.Plot import generate_plot
- from pyneuroml.plot.PlotMorphology import plot_2D
- from pyneuroml.plot.PlotMorphologyVispy import plot_interactive_3D
- from pyneuroml.pynml import (
- generate_sim_scripts_in_folder,
- reload_saved_data,
- run_lems_with,
- write_neuroml2_file,
- )
- from pyneuroml.utils import rotate_cell
- from pyneuroml.utils.units import convert_to_units, get_value_in_si
- logger = logging.getLogger(__name__)
- logger.setLevel(logging.INFO)
- # https://stackoverflow.com/questions/3410976/how-to-round-a-number-to-significant-figures-in-python
- # currently unused
- def round_to_sig(x):
- one_less = round(x, int(math.floor(math.log10(abs(x))))) / 10
- return round(x + one_less, int(math.floor(math.log10(abs(one_less)))))
- class HL23Net(object):
- """HL23 network"""
- def __init__(
- self,
- scale: float = 0.01,
- connections: bool = True,
- network_input: str = "background",
- stimulus: bool = True,
- biophysics: bool = True,
- tonic_inhibition: bool = True,
- new_cells: bool = True,
- max_memory: str = "8G",
- hdf5=True,
- rotate_cells=False,
- ):
- """Init
- :param scale: network scale
- :type scale: float
- :param connections: toggle creation of network connections
- :type connections: bool
- :param network_input: select input to provide to cells
- - "background": for OU background input
- - "step": for a constant step current
- - "none": for no input
- :type network_input: str
- :param stimulus: toggle addition of stimulus to cells for stim protocol
- :type stimulus: bool
- :param biophysics: toggle addition of biophysics to cells (otherwise
- the cells only include morphology)
- :type biophysics: bool
- :param tonic_inhibition: toggle addition of tonic inhibition to cells
- note: requires biophysics to be enabled
- :type tonic_inhibition: bool
- :param new_cells: toggle regeneration of rotated cells, otherwise
- existing rotated cells are used
- :type new_cells: bool
- :param max_memory: max memory for JVM when running pyneuroml
- :type max_memory: str
- :param hdf5: toggle exporting to HDF5 format
- :type hdf5: bool
- :param rotate_cells: generate rotated cells, useful for visualization
- but does not affect the spiking simulation (will affect LPF, but
- we're not generating those here)
- :type rotate_cells: bool
- """
- object.__init__(self)
- self.network_scale = scale
- self.connections = connections
- self.network_input = network_input
- self.stimulus = stimulus
- self.biophysics = biophysics
- self.tonic_inhibition = tonic_inhibition
- self.new_cells = new_cells
- self.max_memory = max_memory
- self.hdf5 = hdf5
- self.rotate_cells = rotate_cells
- # data dumped from the simulation
- try:
- self.cell_data = h5py.File(
- "../L23Net/Circuit_output/cell_positions_and_rotations.h5", "r"
- )
- self.connectivity_data = h5py.File(
- "../L23Net/Circuit_output/synapse_connections.h5", "r"
- )
- self.circuit_params = pandas.read_excel(
- "../L23Net/Circuit_param.xls", sheet_name=None, index_col=0
- )
- # default synaptic parameters: are read from exported H5 files for
- # creation of synapses (above)
- self.circuit_params["syn_params"] = {
- "none": {
- "tau_r_AMPA": 0,
- "tau_d_AMPA": 0,
- "tau_r_NMDA": 0,
- "tau_d_NMDA": 0,
- "e": 0,
- "Dep": 0,
- "Fac": 0,
- "Use": 0,
- "u0": 0,
- "gmax": 0,
- }
- }
- # confirmed from self.cell_data.keys()
- self.cell_types = [i for i in self.circuit_params["conn_probs"].axes[0]]
- except FileNotFoundError:
- print("Files not found")
- self.create = False
- self.pop_colors = {
- "HL23PV": "0 0 1",
- "HL23PYR": "1 0 0",
- "HL23SST": "0 1 0",
- "HL23VIP": "0.5 0.5 0.5",
- }
- self.simulation_id = f"HL23Sim_{self.network_scale}"
- if self.rotate_cells is True:
- self.lems_simulation_file = (
- f"LEMS_HL23_{self.network_scale}_Sim.rotated.xml"
- )
- else:
- self.lems_simulation_file = f"LEMS_HL23_{self.network_scale}_Sim.xml"
- self.netdoc = None
- self.network_id = "HL23Network"
- if self.rotate_cells is True:
- self.netdoc_file_name = f"HL23Net_{self.network_scale}.rotated.net.nml"
- else:
- self.netdoc_file_name = f"HL23Net_{self.network_scale}.net.nml"
- if self.hdf5 is True:
- self.netdoc_file_name += ".h5"
- self.lems_components_file_name = f"lems_components_{self.network_scale}.xml"
- self.stim_start = "200ms"
- self.sim_length = "1000ms"
- self.sim_end = convert_to_units(
- f"{get_value_in_si(self.stim_start) + get_value_in_si(self.sim_length)} s",
- "ms",
- )
- self.dt = "0.025ms"
- self.seed = 4587
- def create_network(self):
- # set the scale of the network
- if self.create is False:
- print("Not creating network")
- return
- start = time.time()
- print(f"Creating network with scale {self.network_scale}")
- self.netdoc = component_factory(neuroml.NeuroMLDocument, id="HL23Network")
- self.network = self.netdoc.add(
- neuroml.Network,
- id=self.network_id,
- temperature="34.0 degC",
- notes=f"L23 network at {self.network_scale} scale",
- validate=False,
- )
- # synapse types
- # LEMS component definitions will be included in simulation file later
- self.lems_components = lems.Model()
- self.lems_components.add(lems.Include("CaDynamics_E2_NML2.nml"))
- self.lems_components.add(lems.Include("synapses/ProbAMPANMDA.synapse.nml"))
- self.lems_components.add(lems.Include("synapses/ProbUDF.synapse.nml"))
- if self.tonic_inhibition:
- self.lems_components.add(lems.Include("channels/Tonic.nml"))
- # add all the channel definitions to
- channel_files = pathlib.Path("channels").glob("**/*.channel.nml")
- for afile in channel_files:
- logger.debug(f"Including {afile}")
- self.lems_components.add(lems.Include(str(afile)))
- self.create_cells()
- if self.connections is True:
- self.create_connections()
- if self.network_input == "background":
- self.add_background_input()
- elif self.network_input == "step":
- self.add_step_current()
- elif self.network_input == "none":
- pass
- else:
- print(f"Invalid network_input value: {self.network_input}, not adding any")
- pass
- if self.stimulus is True:
- self.add_stimulus()
- print(self.netdoc.summary())
- self.netdoc.validate(recursive=True)
- print(f"Writing {self.lems_components_file_name} ")
- self.lems_components.export_to_file(self.lems_components_file_name)
- print(f"Writing {self.netdoc_file_name} ")
- if self.hdf5:
- NeuroMLHdf5Writer.write(
- self.netdoc, self.netdoc_file_name, embed_xml=False, compress=True
- )
- else:
- write_neuroml2_file(self.netdoc, self.netdoc_file_name, validate=False)
- end = time.time()
- print(f"Creating network took: {(end - start)} seconds.")
- def create_cells(self):
- """Create cells and add them to the network.
- Each rotated cell is a new component in NeuroML, and since each
- population can only have one component attached to it when cells are
- rotated, each cell will belong to a different single celled population.
- However, for simulations where one isn't looking at LFPs etc., one does
- not need to rotate the cells. So, one cell component will be used to
- create a single population of each cell type.
- """
- start = time.time()
- print("Creating cells")
- # make a directory for storing rotated cells
- # we include these cells in the network document to ensure that the network
- # document doesn't get too large
- self.temp_cell_dir = "rotated_cells"
- cellfilesdir = pathlib.Path(self.temp_cell_dir)
- cellfilesdir.mkdir(exist_ok=True)
- # keep track of cell gids for our connections later, required for scaled down
- # versions when not all cells are included
- self.nml_cell = {} # type: typing.Dict[str, neuroml.Cell]
- self.cell_list = {} # type: typing.Dict[str, int]
- self.cell_list_by_type = {}
- for ctype in self.cell_types:
- self.cell_list_by_type[ctype] = []
- # create the cell populations
- for ctype in self.cell_types:
- celldataset = self.cell_data[ctype]
- # ['gid', 'x', 'y', 'z', 'x_rot', 'y_rot', 'z_rot']
- logger.debug(f"table headers are: {celldataset.dtype.fields.keys()}")
- self.nml_cell[ctype] = neuroml.loaders.read_neuroml2_file(
- f"{ctype}.cell.nml"
- ).cells[0] # type: neuroml.Cell
- # replace biophys with empty object
- if self.biophysics is False:
- self.nml_cell[
- ctype
- ].biophysical_properties = neuroml.BiophysicalProperties(id="biophys")
- self.nml_cell[ctype].biophysical_properties.add(
- neuroml.MembraneProperties
- )
- self.nml_cell[ctype].biophysical_properties.add(
- neuroml.IntracellularProperties
- )
- # include the cell to ensure the ion channel files are included
- # self.netdoc.add(neuroml.IncludeType, href=f"{ctype}.cell.nml")
- # If we don't rotate cells, we only need one population per cell
- # type.
- # Make a copy anyway because we're modifying the original cell
- if self.rotate_cells is False:
- unrotated_cell = copy.deepcopy(self.nml_cell[ctype])
- unrotated_cell.id = unrotated_cell.id + "_sim"
- unrotated_cell_file = (
- f"{self.temp_cell_dir}/{unrotated_cell.id}.cell.nml"
- )
- unrotated_cell_doc = component_factory(
- neuroml.NeuroMLDocument, id=f"{unrotated_cell.id}_doc"
- )
- unrotated_cell_doc.add(unrotated_cell)
- if self.biophysics is True:
- self.__add_tonic_inhibition(
- ctype, unrotated_cell, unrotated_cell_doc
- )
- write_neuroml2_file(
- unrotated_cell_doc, unrotated_cell_file, validate=False
- )
- self.netdoc.add(neuroml.IncludeType, href=unrotated_cell_file)
- pop = self.network.add(
- neuroml.Population,
- id=f"{ctype}_pop",
- type="populationList",
- component=unrotated_cell.id,
- )
- pop.add(neuroml.Property(tag="color", value=self.pop_colors[ctype]))
- pop.add(neuroml.Property(tag="region", value="L23"))
- i = 0
- step = int(1 / self.network_scale)
- maxcell = len(celldataset)
- # put in minimum 2 cells of each type
- if step >= maxcell:
- step = 1
- maxcell = 2
- for j in range(0, maxcell, step):
- acell = celldataset[j]
- gid = acell[0]
- x = acell[1]
- y = acell[2]
- z = acell[3]
- xrot = acell[4]
- yrot = acell[5]
- zrot = acell[6]
- if self.rotate_cells is True:
- rotated_cell = None
- rotated_cell_file = (
- f"{self.temp_cell_dir}/{self.nml_cell[ctype].id}_{gid}.cell.nml"
- )
- rotated_cell_id = self.nml_cell[ctype].id + f"_{gid}"
- if (
- self.new_cells is False
- and pathlib.Path(rotated_cell_file).exists()
- ):
- print(f"{rotated_cell_file} already exists, not overwriting.")
- print("Set new_cells=True to regenerate all rotated cell files")
- else:
- rotated_cell = rotate_cell(
- self.nml_cell[ctype],
- xrot,
- yrot,
- zrot,
- order="xyz",
- relative_to_soma=True,
- )
- rotated_cell.id = rotated_cell_id
- rotated_cell_doc = component_factory(
- neuroml.NeuroMLDocument, id=f"{rotated_cell_id}_doc"
- )
- if self.biophysics is True:
- self.__add_tonic_inhibition(
- ctype, rotated_cell, rotated_cell_doc
- )
- rotated_cell_doc.add(rotated_cell)
- write_neuroml2_file(
- rotated_cell_doc, rotated_cell_file, validate=False
- )
- self.netdoc.add(neuroml.IncludeType, href=rotated_cell_file)
- pop = self.network.add(
- neuroml.Population,
- id=f"{ctype}_pop_{gid}",
- type="populationList",
- component=rotated_cell_id,
- )
- pop.add(neuroml.Property(tag="color", value=self.pop_colors[ctype]))
- pop.add(neuroml.Property(tag="region", value="L23"))
- pop.add(
- neuroml.Instance, id=0, location=neuroml.Location(x=x, y=y, z=z)
- )
- # track what gids we're including in our network
- # used later when creating connections
- self.cell_list[gid] = 0
- else:
- pop.add(
- neuroml.Instance, id=i, location=neuroml.Location(x=x, y=y, z=z)
- )
- self.cell_list[gid] = i
- i += 1
- # currently unused
- self.cell_list_by_type[ctype].append(gid)
- print(self.netdoc.summary())
- self.netdoc.validate(recursive=True)
- end = time.time()
- print(f"Creating cells took: {(end - start)} seconds")
- def __add_tonic_inhibition(self, ctype, cell, cell_doc):
- """Add tonic inhibition to provided cell
- :param ctype: cell type
- :type ctype: str
- :param cell: cell object to add to
- :type cell: neuroml.Cell
- :param cell_doc: cell doc object
- :type cell_doc: neuroml.NeuroMLDocument
- """
- if self.tonic_inhibition is True:
- # add gaba tonic inhibition to cells
- # definition file is included in the network, so we don't
- # re-include it here.
- if ctype == "HL23PYR" or ctype == "HL23SST":
- cell.add_channel_density(
- nml_cell_doc=cell_doc,
- cd_id="TonicInhibition",
- ion_channel="TonicPavlov2009",
- cond_density="0.000938 S_per_cm2",
- erev="-75 mV",
- group_id="all_minus_myelin",
- ion="non_specific",
- ion_chan_def_file="",
- )
- elif ctype == "HL23PV" or ctype == "HL23VIP":
- cell.add_channel_density(
- nml_cell_doc=cell_doc,
- cd_id="TonicInhibition",
- ion_channel="TonicPavlov2009",
- cond_density="0.000938 S_per_cm2",
- erev="-75 mV",
- group_id="all",
- ion="non_specific",
- ion_chan_def_file="",
- )
- def create_connections(self):
- start = time.time()
- print("Creating connections")
- # count how many connections we have in total
- conn_count = 0
- # create dicts to hold values for caching: prevents us from having to
- # get this info again and again
- ordered_segments = {}
- cumulative_lengths = {}
- for atype in self.cell_types:
- ordered_segments[f"{atype}"] = {}
- cumulative_lengths[f"{atype}"] = {}
- # create connections
- for pretype in self.cell_types:
- for posttype in self.cell_types:
- conndataset = self.connectivity_data[f"{pretype}:{posttype}"]
- # string
- mechanism = self.connectivity_data[f"synparams/{pretype}:{posttype}"][
- "mechanism"
- ][()].decode("utf-8")
- # all ints/floats
- if "UDF" in mechanism:
- tau_r = self.connectivity_data[f"synparams/{pretype}:{posttype}"][
- "tau_r"
- ][()]
- tau_d = self.connectivity_data[f"synparams/{pretype}:{posttype}"][
- "tau_d"
- ][()]
- elif "AMPANMDA" in mechanism:
- tau_r_AMPA = self.connectivity_data[
- f"synparams/{pretype}:{posttype}"
- ]["tau_r_AMPA"][()]
- tau_r_NMDA = self.connectivity_data[
- f"synparams/{pretype}:{posttype}"
- ]["tau_r_NMDA"][()]
- tau_d_AMPA = self.connectivity_data[
- f"synparams/{pretype}:{posttype}"
- ]["tau_d_AMPA"][()]
- tau_d_NMDA = self.connectivity_data[
- f"synparams/{pretype}:{posttype}"
- ]["tau_d_NMDA"][()]
- else:
- raise ValueError(f"Unknown mechanism found: {mechanism}")
- # common to both synapses
- Use = self.connectivity_data[f"synparams/{pretype}:{posttype}"]["Use"][
- ()
- ]
- Dep = self.connectivity_data[f"synparams/{pretype}:{posttype}"]["Dep"][
- ()
- ]
- Fac = self.connectivity_data[f"synparams/{pretype}:{posttype}"]["Fac"][
- ()
- ]
- gbase = self.connectivity_data[f"synparams/{pretype}:{posttype}"][
- "gmax"
- ][()]
- u0 = self.connectivity_data[f"synparams/{pretype}:{posttype}"]["u0"][()]
- erev = self.connectivity_data[f"synparams/{pretype}:{posttype}"]["e"][
- ()
- ]
- print(
- f"Creating synapse component: {pretype} -> {posttype}: {pretype}_{posttype}_{mechanism}."
- )
- if "UDF" in mechanism:
- syn = lems.Component(
- id_=f"{pretype}_{posttype}_{mechanism}",
- type_=f"{mechanism}",
- tau_r=f"{tau_r} ms",
- tau_d=f"{tau_d} ms",
- Use=Use,
- Dep=f"{Dep} ms",
- Fac=f"{Fac} ms",
- gbase=f"{gbase} uS",
- u0=u0,
- erev=f"{erev} mV",
- )
- elif "AMPANMDA" in mechanism:
- syn = lems.Component(
- id_=f"{pretype}_{posttype}_{mechanism}",
- type_=f"{mechanism}",
- tau_r_AMPA=f"{tau_r_AMPA} ms",
- tau_d_AMPA=f"{tau_d_AMPA} ms",
- tau_r_NMDA=f"{tau_r_NMDA} ms",
- tau_d_NMDA=f"{tau_d_NMDA} ms",
- Use=Use,
- Dep=f"{Dep} ms",
- Fac=f"{Fac} ms",
- gbase=f"{gbase} uS",
- u0=u0,
- erev=f"{erev} mV",
- mg="1 mM",
- weight_factor_NMDA="1",
- )
- self.lems_components.add(syn)
- anml_cell = self.nml_cell[f"{posttype}"] # type: neuroml.Cell
- syn_count = 0
- cur_precell = None
- cur_postcell = None
- print(
- f"Creating connections: {pretype} -> {posttype} (~{int(conndataset.shape[0])} with scale of {self.network_scale})."
- )
- # if we're not rotating cells, we only need one project between
- # the single populations of different cell types
- if self.rotate_cells is False:
- proj = component_factory(
- neuroml.Projection,
- id=f"proj_{pretype}_{posttype}",
- presynaptic_population=f"{pretype}_pop",
- postsynaptic_population=f"{posttype}_pop",
- synapse=f"{pretype}_{posttype}_{mechanism}",
- ) # type: neuroml.Projection
- # show a progress bar so we have some idea of what's going on
- max_value_possible = int(conndataset.shape[0])
- # rounded = round_to_sig(approx_max_value)
- bar = progressbar.ProgressBar(
- max_val=max_value_possible, poll_interval=30
- )
- bar_count = 0
- for conn in conndataset:
- precell = conn[0]
- postcell = conn[1]
- weight = conn[2]
- delay = conn[3]
- section = conn[4]
- sectionx = conn[5]
- # if both cells are not in our population, skip this connection
- if (
- precell not in self.cell_list.keys()
- or postcell not in self.cell_list.keys()
- ):
- logger.debug(
- f"{precell} or {postcell} are not included in the network. Skipping"
- )
- continue
- bar.update(bar_count)
- bar_count += 1
- section = (section.decode("utf-8")).split(".")[1]
- neuroml_seggrp_id = get_segment_group_name(section)
- # use info if it's cached, otherwise get new info and cache
- # it
- try:
- ord_segs = ordered_segments[f"{posttype}"][neuroml_seggrp_id]
- cumul_lengths = cumulative_lengths[f"{posttype}"][
- neuroml_seggrp_id
- ]
- except KeyError:
- [
- ord_segs,
- cumul_lengths,
- ] = anml_cell.get_ordered_segments_in_groups(
- group_list=[neuroml_seggrp_id],
- include_cumulative_lengths=True,
- )
- ordered_segments[f"{posttype}"][neuroml_seggrp_id] = ord_segs
- cumulative_lengths[f"{posttype}"][neuroml_seggrp_id] = (
- cumul_lengths
- )
- list_ord_segs = ord_segs[neuroml_seggrp_id]
- list_cumul_lengths = cumul_lengths[neuroml_seggrp_id]
- total_len = list_cumul_lengths[-1]
- section_loc = total_len * sectionx
- ind = bisect.bisect_left(list_cumul_lengths, section_loc)
- post_seg = list_ord_segs[ind]
- # if it's the first segment, with ind 0, [ind - 1] is not its
- # parent segment
- if ind != 0:
- frac_along = (section_loc - list_cumul_lengths[ind - 1]) / (
- list_cumul_lengths[ind] - list_cumul_lengths[ind - 1]
- )
- logger.debug(
- f"frac_along: ({section_loc} - {list_cumul_lengths[ind - 1]}) / ({list_cumul_lengths[ind]} - {list_cumul_lengths[ind - 1]}) = {frac_along}"
- )
- else:
- frac_along = section_loc / list_cumul_lengths[ind]
- logger.debug(
- f"frac_along: ({section_loc} / {list_cumul_lengths[ind]}) = {frac_along}"
- )
- # for zero length segments
- if frac_along == -float("inf"):
- frac_along = 1
- conn_count += 1
- logger.debug(
- f"{conn_count}: {pretype}:{precell} -> {posttype}:{postcell} {neuroml_seggrp_id}: segment {post_seg.id} ({list_cumul_lengths[ind - 1]} - {list_cumul_lengths[ind]}) at {frac_along} with mechanism {mechanism}"
- )
- # a new projection is only required when the pre or post cell
- # change
- if self.rotate_cells is True:
- if precell != cur_precell or postcell != cur_postcell:
- proj = self.network.add(
- neuroml.Projection,
- id=f"proj_{precell}_{postcell}",
- presynaptic_population=f"{pretype}_pop_{precell}",
- postsynaptic_population=f"{posttype}_pop_{postcell}",
- synapse=f"{pretype}_{posttype}_{mechanism}",
- )
- cur_precell = precell
- cur_postcell = postcell
- syn_count = 0
- try:
- proj.add(
- neuroml.ConnectionWD,
- id=syn_count,
- pre_cell_id=f"../{pretype}_pop_{precell}/0/{pretype}_{precell}",
- pre_segment_id=0,
- post_cell_id=f"../{posttype}_pop_{postcell}/0/{posttype}_{postcell}",
- post_segment_id=post_seg.id,
- post_fraction_along=frac_along,
- weight=str(float(weight) / self.network_scale),
- delay=f"{delay} ms",
- )
- except ValueError as e:
- print(f"list of cumulative lengths: {list_cumul_lengths}")
- print(
- f"frac_along: ({section_loc} - {list_cumul_lengths[ind - 1]}) / ({list_cumul_lengths[ind]} - {list_cumul_lengths[ind - 1]}) = {frac_along}"
- )
- raise e
- else:
- try:
- proj.add(
- neuroml.ConnectionWD,
- id=syn_count,
- pre_cell_id=f"../{pretype}_pop/{self.cell_list[precell]}/{pretype}_sim",
- pre_segment_id=0,
- post_cell_id=f"../{posttype}_pop/{self.cell_list[postcell]}/{posttype}_sim",
- post_segment_id=post_seg.id,
- post_fraction_along=frac_along,
- weight=str(float(weight) / self.network_scale),
- delay=f"{delay} ms",
- )
- except ValueError as e:
- print(f"list of cumulative lengths: {list_cumul_lengths}")
- print(
- f"frac_along: ({section_loc} - {list_cumul_lengths[ind - 1]}) / ({list_cumul_lengths[ind]} - {list_cumul_lengths[ind - 1]}) = {frac_along}"
- )
- raise e
- syn_count += 1
- bar.finish()
- # Only add projection to network if there's at least one
- # connection in it.
- # Not required with rotated cells because projection creation
- # and connection creation go hand in hand
- if self.rotate_cells is False:
- if len(proj.connection_wds) > 0:
- self.network.add(proj)
- end = time.time()
- print(f"Creating connections took: {(end - start)} seconds.")
- def add_background_input(self):
- """Add background input to cells."""
- start = time.time()
- # Component Type definition
- self.lems_components.add(lems.Include("synapses/Gfluct.nml"))
- # base excitatory conductances (from paper, given here in uS)
- cell_type_ge0 = {
- "HL23PYR": 0.000028,
- "HL23PV": 0.00028,
- "HL23SST": 0.00003,
- "HL23VIP": 0.000066,
- }
- # store input locations per cell type and create input components for
- # each cell type also, since all cells are indentical
- # values: { 'rel distance' : [(seg id, frac along)] }
- cell_type_input_locations = {} # type: typing.Dict[str, typing.Dict[float, typing.Tuple[int, float]]]
- for cell_type, cell in self.nml_cell.items():
- cell_type_input_locations[cell_type] = {}
- extremeties = cell.get_extremeties()
- try:
- basal_segs = cell.get_all_segments_in_group("basal_dendrite_group")
- except Exception:
- # PV cell doesn't have basal, only a dendrite group
- basal_segs = cell.get_all_segments_in_group("dendrite_group")
- # input points on basal dendrites
- longest_basal_branch_length = 0
- for segid, distance in extremeties.items():
- if distance > longest_basal_branch_length and segid in basal_segs:
- longest_basal_branch_length = distance
- half_way_basal = longest_basal_branch_length / 2
- segs_basal = cell.get_segments_at_distance(half_way_basal)
- # create input component for 0.5
- g_e0 = cell_type_ge0[cell_type] * math.exp(0.5)
- gfluct_component = lems.Component(
- id_=f"Gfluct_{cell_type}_0_5",
- type_="Gfluct",
- start=self.stim_start,
- stop=self.sim_end,
- dt=self.dt,
- E_e="0mV",
- E_i="-80mV",
- g_e0=f"{g_e0} uS",
- g_i0="0pS",
- tau_e="65ms",
- tau_i="20ms",
- std_e=f"{g_e0} uS",
- std_i="0pS",
- )
- self.lems_components.add(gfluct_component)
- # get segments to place input at
- cell_type_input_locations[cell_type][0.5] = []
- for seg, frac_along in segs_basal.items():
- if seg in basal_segs:
- cell_type_input_locations[cell_type][0.5].append((seg, frac_along))
- # additional for pyr apical cells
- pyr_cell = self.nml_cell["HL23PYR"]
- extremeties = pyr_cell.get_extremeties()
- longest_apical_branch_length = 0
- pyr_apical_segs = pyr_cell.get_all_segments_in_group("apical_dendrite_group")
- for segid, distance in extremeties.items():
- if distance > longest_apical_branch_length and segid in pyr_apical_segs:
- longest_apical_branch_length = distance
- apical_input_distances = [0.1, 0.3, 0.5, 0.7, 0.9]
- for d in apical_input_distances:
- # create the input component
- g_e0 = cell_type_ge0[cell_type] * math.exp(d)
- # create input component for use at each distance point
- gfluct_component = lems.Component(
- id_=f"Gfluct_HL23PYR_{str(d).replace('.', '_')}",
- type_="Gfluct",
- start=self.stim_start,
- stop=self.sim_end,
- dt=self.dt,
- E_e="0mV",
- E_i="-80mV",
- g_e0=f"{g_e0} uS",
- g_i0="0pS",
- tau_e="65ms",
- tau_i="20ms",
- std_e=f"{g_e0} uS",
- std_i="0pS",
- )
- self.lems_components.add(gfluct_component)
- # get segments to place at
- segs_apical = pyr_cell.get_segments_at_distance(
- d * longest_apical_branch_length
- )
- for seg, frac_along in segs_apical.items():
- if seg in pyr_apical_segs:
- try:
- cell_type_input_locations["HL23PYR"][d].append(
- (seg, frac_along)
- )
- except KeyError:
- cell_type_input_locations["HL23PYR"][d] = []
- cell_type_input_locations["HL23PYR"][d].append(
- (seg, frac_along)
- )
- # create a new input list for each population, and each location
- # because input list takes a component as an argument, and a different
- # component is required for each location
- input_list_ctr = 0
- input_ctr = 0
- for pop in self.network.populations:
- # cell name
- cell_type = pop.component.split("_")[0]
- input_segs = cell_type_input_locations[cell_type]
- for rel_dist, seginfos in input_segs.items():
- # one input list per population per component
- inputlist = self.network.add(
- "InputList",
- id=f"Gfluct_{input_list_ctr}",
- component=f"Gfluct_{cell_type}_{str(rel_dist).replace('.', '_')}",
- populations=pop.id,
- validate=False,
- )
- input_list_ctr += 1
- for seg, frac_along in seginfos:
- if self.rotate_cells is True:
- inputlist.add(
- "Input",
- id=f"{input_ctr}",
- target=f"../{pop.id}/0/{pop.component}",
- destination="synapses",
- segment_id=seg,
- fraction_along=frac_along,
- )
- input_ctr += 1
- else:
- for inst in pop.instances:
- inputlist.add(
- "Input",
- id=f"{input_ctr}",
- target=f"../{pop.id}/{inst.id}/{pop.component}",
- destination="synapses",
- segment_id=seg,
- fraction_along=frac_along,
- )
- input_ctr += 1
- end = time.time()
- print(f"Adding background input took: {(end - start)} seconds.")
- # TODO: incomplete, to be done after bg input implementation
- def add_stimulus(self):
- """Add additional stimulus to cells."""
- logger.setLevel(logging.DEBUG)
- print("Adding stimuli")
- # cell_nums = [self.circuit_params['SING_CELL_PARAM'].at['cell_num', name] for name in self.cell_types]
- # from circuit.py
- input_ctr = 0
- for acell_type in self.cell_types:
- # iterate over rows
- for row in self.circuit_params["STIM_PARAM"].axes[0]:
- # initialise parameters
- num_cells = 0 # number of cells to provide input to
- start_index = 0 # unused, is set to 0
- num_stim = 0 # number of spikes
- interval = 0 # spike interval
- start_time = 0 # spikes start time
- delay = 0 # spikes delay
- delay_range = 0 # spikes delay range
- loc_num = 0 # number of locations on cell to provide spike to
- loc = "all" # what locations to provide spikes to
- gmax = 0.0 # gmax
- stim_type = "" # type of synapse for stimulus
- syn_params = "" # parameters of synapse
- for col in self.circuit_params["STIM_PARAM"].axes[1]:
- # found the cell row
- if (
- "cell_name" == col
- and self.circuit_params["STIM_PARAM"].at[row, col] == acell_type
- ):
- num_cells = int(
- self.circuit_params["STIM_PARAM"].at[row, "num_cells"]
- * self.network_scale
- )
- start_index = self.circuit_params["STIM_PARAM"].at[
- row, "start_index"
- ]
- num_stim = self.circuit_params["STIM_PARAM"].at[row, "num_stim"]
- interval = self.circuit_params["STIM_PARAM"].at[row, "interval"]
- # currently unused: NeuroML does not have a
- # SpikeGenerator that allows setting a start time
- start_time = self.circuit_params["STIM_PARAM"].at[
- row, "start_time"
- ]
- delay = self.circuit_params["STIM_PARAM"].at[row, "delay"]
- delay_range = self.circuit_params["STIM_PARAM"].at[
- row, "delay_range"
- ]
- loc_num = self.circuit_params["STIM_PARAM"].at[row, "loc_num"]
- # loc: unused: "dend", which corresponds to all
- # dendritic segments
- loc = self.circuit_params["STIM_PARAM"].at[row, "loc"]
- gmax = self.circuit_params["STIM_PARAM"].at[row, "gmax"]
- stim_type = self.circuit_params["STIM_PARAM"].at[
- row, "stim_type"
- ]
- syn_params = self.circuit_params["STIM_PARAM"].at[
- row, "syn_params"
- ]
- # load the single template cell, since choosing sections does
- # not depend on rotation
- a_nml_cell = self.nml_cell[acell_type] # type: neuroml.Cell
- # loc is always "dend"
- logger.debug(f"loc: {loc}")
- dendritic_segments_ids = a_nml_cell.get_all_segments_in_group(
- "dendrite_group"
- )
- # dendritic_segments = [nml_cell.get_segment(seg) for seg in dendritic_segments_ids]
- segment_areas = numpy.array(
- [
- a_nml_cell.get_segment_surface_area(seg)
- for seg in dendritic_segments_ids
- ]
- )
- segment_areas = segment_areas / segment_areas.sum()
- cells = self.cell_list_by_type[acell_type]
- ctr = 0
- # if it's too small a model, at least give one cell input
- if num_cells == 0:
- num_cells = 1
- while ctr <= num_cells:
- cell_id = f"{acell_type}_{cells[ctr]}"
- pop_id = f"{acell_type}_pop_{cells[ctr]}"
- # get segments
- input_segments = numpy.random.choice(
- dendritic_segments_ids,
- size=loc_num,
- replace=False,
- p=segment_areas,
- )
- for aseg in input_segments:
- print(
- f"Adding sg_{input_ctr}: i_{input_ctr}/{input_ctr} to {pop_id}/{cell_id}/{aseg}"
- )
- # currently SpikeGenerator does not allow a start time, so
- # this is unused
- time_delay = 0
- while time_delay <= 0:
- time_delay = numpy.random.uniform(
- low=delay, high=delay + delay_range
- )
- gen = self.netdoc.add(
- neuroml.SpikeGenerator,
- id=f"sg_{input_ctr}",
- period=f"{interval} ms",
- )
- input_list = self.network.add(
- neuroml.InputList,
- id=f"i_{input_ctr}",
- component=gen.id,
- populations=pop_id,
- )
- input_list.add(
- neuroml.Input,
- id=f"{input_ctr}",
- target=f"../{pop_id}/0/{cell_id}",
- destination="synapses",
- segment_id=aseg,
- )
- input_ctr += 1
- ctr += 1
- break
- logger.setLevel(logging.INFO)
- def visualize_network(self, min_cells=5):
- """Generate morph plots"""
- print(
- f"Visualising network at scale {self.network_scale} with {min_cells} in full"
- )
- # if the network has been constructed, copy over the populations and
- # include the cells
- if self.netdoc is not None:
- nml_file = neuroml.NeuroMLDocument(id="network_copy")
- nml_file.add(neuroml.Network, id="dummy_network")
- # copy over populations
- nml_file.networks[0].populations = self.netdoc.networks[0].populations
- nml_file.includes = self.netdoc.includes
- # include cells
- for inc in self.nml_file.includes:
- incfile = read_neuroml2_file(inc.href)
- for cell in incfile.cells:
- nml_file.add(cell)
- else:
- # otherwise read the file in once so it's not read in repeatedly
- print(f"Reading {self.netdoc_file_name}")
- nml_file = read_neuroml2_file(self.netdoc_file_name)
- PYR_cells = []
- SST_cells = []
- PV_cells = []
- VIP_cells = []
- PYR_point_cells = []
- SST_point_cells = []
- PV_point_cells = []
- VIP_point_cells = []
- # because each cell is in a separate population
- print("Picking point cells")
- for inc in nml_file.includes:
- cell = inc.href.split("/")[1].replace(".cell.nml", "")
- if "PYR" in cell:
- PYR_cells.append(cell)
- if "PV" in cell:
- PV_cells.append(cell)
- if "VIP" in cell:
- VIP_cells.append(cell)
- if "SST" in cell:
- SST_cells.append(cell)
- print(f"Got {len(PYR_cells)} PYR cells")
- print(f"Got {len(SST_cells)} SST cells")
- print(f"Got {len(PV_cells)} PV cells")
- print(f"Got {len(VIP_cells)} VIP cells")
- # at least plot min_cells cells of each type, and all the rest as points
- if (len(PYR_cells) - min_cells) > 0:
- PYR_point_cells = random.sample(PYR_cells, len(PYR_cells) - min_cells)
- if (len(SST_cells) - min_cells) > 0:
- SST_point_cells = random.sample(SST_cells, len(SST_cells) - min_cells)
- if (len(PV_cells) - min_cells) > 0:
- PV_point_cells = random.sample(PV_cells, len(PV_cells) - min_cells)
- if (len(VIP_cells) - min_cells) > 0:
- VIP_point_cells = random.sample(VIP_cells, len(VIP_cells) - min_cells)
- print(
- f"Picked {len(PYR_point_cells) + len(SST_point_cells) + len(PV_point_cells) + len(VIP_point_cells)} point cells"
- )
- """
- print("Removing axons from PYR cells")
- for ac in nml_file.cells:
- if ac.id not in PYR_point_cells:
- axons = ac.get_all_segments_in_group(ac.get_segment_group("axon_group"))
- for s in ac.morphology.segments:
- if s.id in axons:
- ac.morphology.segments.remove(s)
- """
- """
- for plane in ["xy", "yz", "zx"]:
- print(f"Plotting {plane} with {point_fraction} fraction as point cells")
- plot_2D(
- nml_file=nml_file,
- plane2d=plane,
- min_width=1,
- nogui=True,
- title="",
- plot_type="constant",
- save_to_file=f"{self.netdoc_file_name.replace('.nml', '')}.{plane}.png",
- plot_spec={
- "point_cells": PYR_point_cells + SST_point_cells + VIP_point_cells + PV_point_cells
- }
- )
- print(f"Plotting {plane} with all cells as point cells")
- plot_2D(
- nml_file=nml_file,
- plane2d=plane,
- min_width=1,
- nogui=True,
- title="",
- plot_type="constant",
- save_to_file=f"{self.netdoc_file_name.replace('.nml', '')}.{plane}.allpoints.png",
- plot_spec={
- "point_fraction": 1.0
- }
- )
- print(f"Plotting {plane} with a single cells of each type in detail")
- plot_2D(
- nml_file=nml_file,
- plane2d=plane,
- min_width=1,
- nogui=True,
- title="",
- plot_type="constant",
- save_to_file=f"{self.netdoc_file_name.replace('.nml', '')}.{plane}.points.png",
- plot_spec={
- "point_cells": PYR_cells[1:] + SST_cells[1:] + VIP_cells[1:] + PV_cells[1:]
- }
- )
- """
- plot_interactive_3D(
- self.netdoc_file_name,
- plot_type="detailed",
- plot_spec={
- "point_cells": PYR_point_cells
- + SST_point_cells
- + VIP_point_cells
- + PV_point_cells
- },
- min_width=1.0,
- precision=(0, 200),
- )
- def create_simulation(self, dt=None, seed=123, record_data=True):
- """Create simulation, record data.
- :param dt: override dt value (in ms)
- :type dt: str
- :param seed: seed
- :type seed: int
- :param record_data: toggle whether data should be recorded
- :type record_data: bool
- """
- start = time.time()
- if dt is None:
- dt = self.dt
- if seed is None:
- seed = self.seed
- simulation = LEMSSimulation(
- sim_id=self.simulation_id,
- duration=float(self.sim_length.replace("ms", "")),
- dt=float(dt.replace("ms", "")),
- simulation_seed=seed,
- )
- simulation.assign_simulation_target(self.network_id)
- simulation.include_neuroml2_file(f"HL23Net_{self.network_scale}.net.nml")
- simulation.include_lems_file(self.lems_components_file_name)
- if record_data is True:
- simulation.create_output_file(
- "output1", f"HL23Net_{self.network_scale}.v.dat"
- )
- print(f"Saving data to: HL23Net_{self.network_scale}.v.dat")
- for apop in self.network.populations:
- for inst in apop.instances:
- simulation.add_column_to_output_file(
- "output1",
- f"{apop.id}_{inst.id}",
- f"{apop.id}/{inst.id}/{apop.component}/0/v",
- )
- simulation.save_to_file(self.lems_simulation_file)
- print(f"Saved simulation to {self.lems_simulation_file}")
- end = time.time()
- print(f"Creating simulation took: {(end - start)} seconds.")
- def run_sim(
- self,
- engine: str = "jneuroml_neuron",
- cluster: typing.Union[str, bool] = False,
- **kwargs,
- ):
- """Run the sim
- :param engine: engine to use (jneuroml_neuron/jneuroml_netpyne)
- :type engine: str
- :param cluster: toggle submitting to nsg or qsub
- Use "nsg_dry" for a dry NSG run (won't submit)
- Use "qsub" to generate a qsub script instead
- :type cluster: bool or str
- :param **kwargs: other engine + nsg specific args
- """
- if cluster is False:
- print(f"Running simulation: {self.lems_simulation_file}")
- run_lems_with(
- engine,
- self.lems_simulation_file,
- max_memory=self.max_memory,
- nogui=True,
- show_plot_already=False,
- **kwargs,
- )
- elif cluster == "qsub":
- print(f"Generating files but not running: {self.lems_simulation_file}")
- # TODO: create in a different folder like NSG
- tdir = generate_sim_scripts_in_folder(
- engine=engine,
- lems_file_name=self.lems_simulation_file,
- root_dir=".",
- max_memory=self.max_memory,
- nogui=True,
- show_plot_already=False,
- **kwargs,
- )
- # remove trailing backslash
- if tdir[-1] == "/":
- tdir = tdir[:-1]
- qsub_fn = f"{tdir}/{tdir}_generated/{self.lems_simulation_file}.sh"
- netpyne_simfile = self.lems_simulation_file.replace(".xml", "_netpyne.py")
- print(f"Generating qsub script for use on cluster: {qsub_fn}")
- with open(qsub_fn, "w") as f:
- print(
- inspect.cleandoc(
- textwrap.dedent(
- f"""
- #!/bin/bash -l
- #$ -pe mpi 1024
- #$ -l mem=4G
- #$ -l h_rt=6:00:00
- #$ -cwd
- #$ -m be
- source ~/.venv/bin/activate
- nrnivmodl
- gerun python3 {netpyne_simfile} -nogui
- """
- )
- ),
- file=f,
- )
- elif cluster == "nsg_dry":
- print(
- f"Preparing to run on NSG (but not submitting): {self.lems_simulation_file}"
- )
- run_on_nsg(
- engine,
- self.lems_simulation_file,
- dry_run=True,
- max_memory=self.max_memory,
- **kwargs,
- )
- elif cluster == "nsg":
- print(f"Running simulation on NSG: {self.lems_simulation_file}")
- run_on_nsg(
- engine, self.lems_simulation_file, max_memory=self.max_memory, **kwargs
- )
- print("Press Ctrl C to interrupt the waiting process")
- print(
- "You can use `nsg_job -l` to check the status of the job and download the simulation reults"
- )
- def plot_v_graphs(self):
- """Plot membrane potential graphs"""
- data = reload_saved_data(
- self.lems_simulation_file,
- plot=True,
- show_plot_already=True,
- reload_events=False,
- )
- """
- logger.debug(data.keys())
- xvals = [data["t"]]
- yvals = list(data.values())[1:]
- logger.debug(len(xvals * len(yvals)))
- logger.debug(yvals)
- labels = [a.split("/")[0] for a in data.keys()][1:]
- generate_plot(
- xvalues=xvals * len(yvals),
- yvalues=yvals,
- title="Membrane potentials",
- labels=labels,
- xaxis="time (ms)",
- yaxis="v (mV)",
- cols_in_legend_box=2,
- save_figure_to=f"{self.lems_simulation_file.replace('.xml', '')}_v.png",
- )
- """
- def add_step_current(self):
- """Add a constant step current to all cells.
- Useful for testing the cells to ensure they produce correct behaviour,
- in an unconnected network, for example
- """
- print("Adding step current to each cell")
- # a single pulse generator
- pg = self.netdoc.add(
- neuroml.PulseGenerator,
- id="pg_0",
- delay="100ms",
- duration=self.sim_length,
- amplitude="0.2nA",
- )
- for pop in self.network.populations:
- self.network.add(neuroml.ExplicitInput, target=f"{pop.id}[0]", input=pg.id)
- if __name__ == "__main__":
- parser = argparse.ArgumentParser(
- prog="NeuroML_YaoEtAl2022",
- description="Generate and simulate NeuroML version of Yao et al 2022",
- )
- # general options
- general_args = parser.add_argument_group("General options")
- general_args.add_argument(
- "-s",
- "--scale",
- action="store",
- help="Scale of network",
- default="1",
- required=True,
- type=float,
- )
- general_args.add_argument(
- "-n",
- "--new_cells",
- action="store_true",
- help="Toggle creation of new cells or re-use of existing ones",
- default=False,
- )
- general_args.add_argument(
- "-b",
- "--biophysics",
- action="store_true",
- help="Toggle inclusion of biophysics",
- default=True,
- )
- general_args.add_argument(
- "-t",
- "--tonic_inhibition",
- action="store_true",
- help="Toggle tonic inhibition in the network",
- default=True,
- )
- general_args.add_argument(
- "-c",
- "--connections",
- action="store_true",
- help="Toggle creation of network connections",
- default=True,
- )
- general_args.add_argument(
- "-i",
- "--network_input",
- action="store",
- help="Type of input to give to network",
- choices=["background", "step", "none"],
- default="background",
- )
- general_args.add_argument(
- "-l",
- "--stimulus",
- action="store_true",
- help="Toggle external stimulus",
- default=False,
- )
- general_args.add_argument(
- "--hdf5",
- action="store_true",
- help="Toggle exporting as HDF5",
- )
- general_args.add_argument(
- "-r",
- "--rotate_cells",
- action="store_true",
- help="Toggle rotation of cells: not required for simulation since placements of cells in space does not affect it",
- default=False,
- )
- # actions
- action_args = parser.add_argument_group("Actions")
- action_args.add_argument(
- "--create_network",
- action="store_true",
- help="Toggle creation of new network",
- default=False,
- )
- action_args.add_argument(
- "--create_simulation",
- action="store_true",
- help="Toggle creation of new simulation",
- default=False,
- )
- action_args.add_argument(
- "--visualize_network",
- action="store",
- metavar="<min number of cells to visualise with full morphology>",
- help="Visualise network with provided minimum number of cells",
- type=int,
- default=25,
- )
- run_parser = action_args.add_mutually_exclusive_group()
- run_parser.add_argument(
- "--simulate_neuron",
- action="store_true",
- help="Simulation using single threaded NEURON simulation",
- )
- run_parser.add_argument(
- "--simulate_netpyne_nsg",
- action="store_true",
- help="Generate configuration to run using NetPyNE on NSG",
- )
- run_parser.add_argument(
- "--simulate_netpyne_qsub",
- action="store_true",
- help="Generate configuration to run using NetPyNE on a cluster using qsub",
- )
- # NSG options
- nsg_args = parser.add_argument_group("NSG options")
- # parse
- nsg_args.add_argument(
- "--number_cores", action="store", default="64", help="Number of cores requested"
- )
- nsg_args.add_argument(
- "--number_of_nodes", action="store", default="8", help="Number of nodes"
- )
- nsg_args.add_argument(
- "--tasks_per_node",
- action="store",
- default="64",
- help="Number of tasks per node (cores * number nodes?)",
- )
- nsg_args.add_argument(
- "--memory_per_node",
- action="store",
- default="240",
- help="Memory requested per node in GB",
- )
- nsg_args.add_argument(
- "--runtime", action="store", default="5", help="Run time requested in hours"
- )
- nsg_args.add_argument(
- "--environment",
- action="store",
- default="OSBv2_EXPANSE_0_7_3",
- help="Environment to request",
- )
- args = parser.parse_args()
- model = HL23Net(
- scale=args.scale,
- new_cells=args.new_cells,
- biophysics=args.biophysics,
- tonic_inhibition=args.tonic_inhibition,
- connections=args.connections,
- network_input=args.network_input,
- stimulus=args.stimulus,
- hdf5=args.hdf5,
- rotate_cells=args.rotate_cells,
- )
- if args.create_network:
- model.create_network()
- if args.create_simulation:
- model.create_simulation()
- if args.visualize_network:
- model.visualize_network(min_cells=args.visualize_network)
- # simulation
- if args.simulate_neuron:
- model.run_sim(engine="jneuroml_neuron", cluster=False, skip_run=False)
- elif args.simulate_netpyne_nsg:
- model.run_sim(
- engine="jneuroml_netpyne",
- cluster="nsg",
- nsg_sim_config={
- "number_cores_": args.number_cores,
- "tasks_per_node_": args.tasks_per_node,
- "number_nodes_": args.number_nodes,
- "number_gbmemorypernode_": args.memory_per_node,
- "runtime_": args.runtime,
- "toolId": args.environment,
- "nrnivmodl_o_": "1",
- "cmdlineopts_": "-nogui",
- },
- nogui=True,
- )
- elif args.simulate_netpyne_qsub:
- model.run_sim(engine="jneuroml_netpyne", cluster="qsub")
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