def test_ExportDevice_options(): """ Test the run and build options of ExportDevice """ # test1 set_device('exporter') grp = NeuronGroup(10, 'eqn = 1:1', method='exact') run(100 * ms) _ = StateMonitor(grp, 'eqn', record=False) with pytest.raises(RuntimeError): run(100 * ms) # test2 device.reinit() with pytest.raises(RuntimeError): device.build() # test3 start_scope() net = Network() set_device('exporter', build_on_run=False) grp = NeuronGroup(10, 'eqn = 1:1', method='exact') net.add(grp) net.run(10 * ms) pogrp = PoissonGroup(10, rates=10 * Hz) net.add(pogrp) net.run(10 * ms) mon = StateMonitor(grp, 'eqn', record=False) net.add(mon) net.run(10 * ms) device.build() device.reinit()
def run_net(tr): # prefs.codegen.target = 'numpy' # prefs.codegen.target = 'cython' set_device('cpp_standalone', directory='./builds/%.4d' % (tr.v_idx), build_on_run=False) print("Started process with id ", str(tr.v_idx)) T = tr.T1 + tr.T2 + tr.T3 namespace = tr.netw.f_to_dict(short_names=True, fast_access=True) namespace['idx'] = tr.v_idx defaultclock.dt = tr.netw.sim.dt GExc = NeuronGroup( N=tr.N_e, model=tr.condlif_sig, threshold=tr.nrnEE_thrshld, reset=tr.nrnEE_reset, #method=tr.neuron_method, namespace=namespace) GInh = NeuronGroup( N=tr.N_i, model=tr.condlif_sig, threshold='V > Vt', reset='V=Vr_i', #method=tr.neuron_method, namespace=namespace) # set initial thresholds fixed, init. potentials uniformly distrib. GExc.sigma, GInh.sigma = tr.sigma_e, tr.sigma_i GExc.Vt, GInh.Vt = tr.Vt_e, tr.Vt_i GExc.V , GInh.V = np.random.uniform(tr.Vr_e/mV, tr.Vt_e/mV, size=tr.N_e)*mV, \ np.random.uniform(tr.Vr_i/mV, tr.Vt_i/mV, size=tr.N_i)*mV print("need to fix?") synEE_pre_mod = mod.synEE_pre synEE_post_mod = mod.synEE_post if tr.PInp_mode == 'pool': PInp = PoissonGroup(tr.NPInp, rates=tr.PInp_rate, namespace=namespace) sPN = Synapses(target=GExc, source=PInp, model=tr.poisson_mod, on_pre='ge_post += a_EPoi', namespace=namespace) sPN_src, sPN_tar = generate_connections(N_tar=tr.N_e, N_src=tr.NPInp, p=tr.p_EPoi) elif tr.PInp_mode == 'indep': PInp = PoissonGroup(tr.N_e, rates=tr.PInp_rate, namespace=namespace) sPN = Synapses(target=GExc, source=PInp, model=tr.poisson_mod, on_pre='ge_post += a_EPoi', namespace=namespace) sPN_src, sPN_tar = range(tr.N_e), range(tr.N_e) sPN.connect(i=sPN_src, j=sPN_tar) if tr.PInp_mode == 'pool': sPNInh = Synapses(target=GInh, source=PInp, model=tr.poisson_mod, on_pre='ge_post += a_EPoi', namespace=namespace) sPNInh_src, sPNInh_tar = generate_connections(N_tar=tr.N_i, N_src=tr.NPInp, p=tr.p_EPoi) elif tr.PInp_mode == 'indep': PInp_inh = PoissonGroup(tr.N_i, rates=tr.PInp_rate, namespace=namespace) sPNInh = Synapses(target=GInh, source=PInp_inh, model=tr.poisson_mod, on_pre='ge_post += a_EPoi', namespace=namespace) sPNInh_src, sPNInh_tar = range(tr.N_i), range(tr.N_i) sPNInh.connect(i=sPNInh_src, j=sPNInh_tar) if tr.stdp_active: synEE_pre_mod = '''%s %s''' % (synEE_pre_mod, mod.synEE_pre_STDP) synEE_post_mod = '''%s %s''' % (synEE_post_mod, mod.synEE_post_STDP) if tr.synEE_rec: synEE_pre_mod = '''%s %s''' % (synEE_pre_mod, mod.synEE_pre_rec) synEE_post_mod = '''%s %s''' % (synEE_post_mod, mod.synEE_post_rec) # E<-E advanced synapse model, rest simple SynEE = Synapses( target=GExc, source=GExc, model=tr.synEE_mod, on_pre=synEE_pre_mod, on_post=synEE_post_mod, #method=tr.synEE_method, namespace=namespace) SynIE = Synapses(target=GInh, source=GExc, on_pre='ge_post += a_ie', namespace=namespace) SynEI = Synapses(target=GExc, source=GInh, on_pre='gi_post += a_ei', namespace=namespace) SynII = Synapses(target=GInh, source=GInh, on_pre='gi_post += a_ii', namespace=namespace) if tr.strct_active: sEE_src, sEE_tar = generate_full_connectivity(tr.N_e, same=True) SynEE.connect(i=sEE_src, j=sEE_tar) SynEE.syn_active = 0 else: srcs_full, tars_full = generate_full_connectivity(tr.N_e, same=True) SynEE.connect(i=srcs_full, j=tars_full) SynEE.syn_active = 0 sIE_src, sIE_tar = generate_connections(tr.N_i, tr.N_e, tr.p_ie) sEI_src, sEI_tar = generate_connections(tr.N_e, tr.N_i, tr.p_ei) sII_src, sII_tar = generate_connections(tr.N_i, tr.N_i, tr.p_ii, same=True) SynIE.connect(i=sIE_src, j=sIE_tar) SynEI.connect(i=sEI_src, j=sEI_tar) SynII.connect(i=sII_src, j=sII_tar) tr.f_add_result('sIE_src', sIE_src) tr.f_add_result('sIE_tar', sIE_tar) tr.f_add_result('sEI_src', sEI_src) tr.f_add_result('sEI_tar', sEI_tar) tr.f_add_result('sII_src', sII_src) tr.f_add_result('sII_tar', sII_tar) SynEE.a = tr.a_ee SynEE.insert_P = tr.insert_P SynEE.p_inactivate = tr.p_inactivate # make synapse active at beginning SynEE.run_regularly(tr.synEE_p_activate, dt=T, when='start', order=-100) # synaptic scaling if tr.netw.config.scl_active: SynEE.summed_updaters['Asum_post']._clock = Clock( dt=tr.dt_synEE_scaling) SynEE.run_regularly(tr.synEE_scaling, dt=tr.dt_synEE_scaling, when='end') # intrinsic plasticity if tr.netw.config.it_active: GExc.h_ip = tr.h_ip GExc.run_regularly(tr.intrinsic_mod, dt=tr.it_dt, when='end') # structural plasticity if tr.netw.config.strct_active: if tr.strct_mode == 'zero': if tr.turnover_rec: strct_mod = '''%s %s''' % (tr.strct_mod, tr.turnover_rec_mod) else: strct_mod = tr.strct_mod SynEE.run_regularly(strct_mod, dt=tr.strct_dt, when='end') elif tr.strct_mode == 'thrs': if tr.turnover_rec: strct_mod_thrs = '''%s %s''' % (tr.strct_mod_thrs, tr.turnover_rec_mod) else: strct_mod_thrs = tr.strct_mod_thrs SynEE.run_regularly(strct_mod_thrs, dt=tr.strct_dt, when='end') # -------------- recording ------------------ #run(tr.sim.preT) GExc_recvars = [] if tr.memtraces_rec: GExc_recvars.append('V') if tr.vttraces_rec: GExc_recvars.append('Vt') if tr.getraces_rec: GExc_recvars.append('ge') if tr.gitraces_rec: GExc_recvars.append('gi') GInh_recvars = GExc_recvars GExc_stat = StateMonitor(GExc, GExc_recvars, record=[0, 1, 2], dt=tr.GExc_stat_dt) GInh_stat = StateMonitor(GInh, GInh_recvars, record=[0, 1, 2], dt=tr.GInh_stat_dt) SynEE_recvars = [] if tr.synee_atraces_rec: SynEE_recvars.append('a') if tr.synee_Apretraces_rec: SynEE_recvars.append('Apre') if tr.synee_Aposttraces_rec: SynEE_recvars.append('Apost') SynEE_stat = StateMonitor(SynEE, SynEE_recvars, record=range(tr.n_synee_traces_rec), when='end', dt=tr.synEE_stat_dt) GExc_spks = SpikeMonitor(GExc) GInh_spks = SpikeMonitor(GInh) PInp_spks = SpikeMonitor(PInp) GExc_rate = PopulationRateMonitor(GExc) GInh_rate = PopulationRateMonitor(GInh) PInp_rate = PopulationRateMonitor(PInp) SynEE_a = StateMonitor(SynEE, ['a', 'syn_active'], record=range(tr.N_e * (tr.N_e - 1)), dt=T / tr.synee_a_nrecpoints, when='end', order=100) if tr.PInp_mode == 'indep': net = Network(GExc, GInh, PInp, sPN, sPNInh, SynEE, SynEI, SynIE, SynII, GExc_stat, GInh_stat, SynEE_stat, SynEE_a, GExc_spks, GInh_spks, PInp_spks, GExc_rate, GInh_rate, PInp_rate, PInp_inh) else: net = Network(GExc, GInh, PInp, sPN, sPNInh, SynEE, SynEI, SynIE, SynII, GExc_stat, GInh_stat, SynEE_stat, SynEE_a, GExc_spks, GInh_spks, PInp_spks, GExc_rate, GInh_rate, PInp_rate) net.run(tr.sim.T1, report='text') # SynEE_a.record_single_timestep() recorders = [ GExc_spks, GInh_spks, PInp_spks, SynEE_stat, GExc_stat, GInh_stat ] rate_recorders = [GExc_rate, GInh_rate, PInp_rate] for rcc in recorders: rcc.active = False net.run(tr.sim.T2, report='text') recorders = [ SynEE_stat, GExc_stat, GInh_stat, GExc_rate, GInh_rate, PInp_rate ] for rcc in recorders: rcc.active = True if tr.spks_rec: GExc_spks.active = True GInh_spks.active = True # PInp_spks.active=True net.run(tr.sim.T3, report='text') device.build(directory='../builds/%.4d' % (tr.v_idx), clean=True) # save monitors as raws in build directory raw_dir = '../builds/%.4d/raw/' % (tr.v_idx) if not os.path.exists(raw_dir): os.makedirs(raw_dir) with open(raw_dir + 'namespace.p', 'wb') as pfile: pickle.dump(namespace, pfile) with open(raw_dir + 'gexc_stat.p', 'wb') as pfile: pickle.dump(GExc_stat.get_states(), pfile) with open(raw_dir + 'ginh_stat.p', 'wb') as pfile: pickle.dump(GInh_stat.get_states(), pfile) with open(raw_dir + 'synee_stat.p', 'wb') as pfile: pickle.dump(SynEE_stat.get_states(), pfile) with open(raw_dir + 'synee_a.p', 'wb') as pfile: pickle.dump(SynEE_a.get_states(), pfile) with open(raw_dir + 'gexc_spks.p', 'wb') as pfile: pickle.dump(GExc_spks.get_states(), pfile) with open(raw_dir + 'ginh_spks.p', 'wb') as pfile: pickle.dump(GInh_spks.get_states(), pfile) with open(raw_dir + 'pinp_spks.p', 'wb') as pfile: pickle.dump(PInp_spks.get_states(), pfile) with open(raw_dir + 'gexc_rate.p', 'wb') as pfile: pickle.dump(GExc_rate.get_states(), pfile) pickle.dump(GExc_rate.smooth_rate(width=25 * ms), pfile) with open(raw_dir + 'ginh_rate.p', 'wb') as pfile: pickle.dump(GInh_rate.get_states(), pfile) pickle.dump(GInh_rate.smooth_rate(width=25 * ms), pfile) with open(raw_dir + 'pinp_rate.p', 'wb') as pfile: pickle.dump(PInp_rate.get_states(), pfile) pickle.dump(PInp_rate.smooth_rate(width=25 * ms), pfile) # ----------------- add raw data ------------------------ fpath = '../builds/%.4d/' % (tr.v_idx) from pathlib import Path Path(fpath + 'turnover').touch() turnover_data = np.genfromtxt(fpath + 'turnover', delimiter=',') os.remove(fpath + 'turnover') with open(raw_dir + 'turnover.p', 'wb') as pfile: pickle.dump(turnover_data, pfile) Path(fpath + 'spk_register').touch() spk_register_data = np.genfromtxt(fpath + 'spk_register', delimiter=',') os.remove(fpath + 'spk_register') with open(raw_dir + 'spk_register.p', 'wb') as pfile: pickle.dump(spk_register_data, pfile)
def run_net(tr): # prefs.codegen.target = 'numpy' # prefs.codegen.target = 'cython' set_device('cpp_standalone', directory='./builds/%.4d' % (tr.v_idx), build_on_run=False) print("Started process with id ", str(tr.v_idx)) namespace = tr.netw.f_to_dict(short_names=True, fast_access=True) namespace['idx'] = tr.v_idx defaultclock.dt = tr.netw.sim.dt GExc = NeuronGroup( N=tr.N_e, model=tr.condlif_sig, threshold=tr.nrnEE_thrshld, reset=tr.nrnEE_reset, #method=tr.neuron_method, namespace=namespace) GInh = NeuronGroup( N=tr.N_i, model=tr.condlif_sig, threshold='V > Vt', reset='V=Vr_i', #method=tr.neuron_method, namespace=namespace) # set initial thresholds fixed, init. potentials uniformly distrib. GExc.sigma, GInh.sigma = tr.sigma_e, tr.sigma_i GExc.Vt, GInh.Vt = tr.Vt_e, tr.Vt_i GExc.V , GInh.V = np.random.uniform(tr.Vr_e/mV, tr.Vt_e/mV, size=tr.N_e)*mV, \ np.random.uniform(tr.Vr_i/mV, tr.Vt_i/mV, size=tr.N_i)*mV synEE_pre_mod = mod.synEE_pre synEE_post_mod = mod.synEE_post if tr.stdp_active: synEE_pre_mod = '''%s %s''' % (synEE_pre_mod, mod.synEE_pre_STDP) synEE_post_mod = '''%s %s''' % (synEE_post_mod, mod.synEE_post_STDP) if tr.synEE_rec: synEE_pre_mod = '''%s %s''' % (synEE_pre_mod, mod.synEE_pre_rec) synEE_post_mod = '''%s %s''' % (synEE_post_mod, mod.synEE_post_rec) # E<-E advanced synapse model, rest simple SynEE = Synapses( target=GExc, source=GExc, model=tr.synEE_mod, on_pre=synEE_pre_mod, on_post=synEE_post_mod, #method=tr.synEE_method, namespace=namespace) SynIE = Synapses(target=GInh, source=GExc, on_pre='ge_post += a_ie', namespace=namespace) SynEI = Synapses(target=GExc, source=GInh, on_pre='gi_post += a_ei', namespace=namespace) SynII = Synapses(target=GInh, source=GInh, on_pre='gi_post += a_ii', namespace=namespace) if tr.strct_active: sEE_src, sEE_tar = generate_full_connectivity(tr.N_e, same=True) SynEE.connect(i=sEE_src, j=sEE_tar) SynEE.syn_active = 0 else: srcs_full, tars_full = generate_full_connectivity(tr.N_e, same=True) SynEE.connect(i=srcs_full, j=tars_full) SynEE.syn_active = 0 sIE_src, sIE_tar = generate_connections(tr.N_i, tr.N_e, tr.p_ie) sEI_src, sEI_tar = generate_connections(tr.N_e, tr.N_i, tr.p_ei) sII_src, sII_tar = generate_connections(tr.N_i, tr.N_i, tr.p_ii, same=True) SynIE.connect(i=sIE_src, j=sIE_tar) SynEI.connect(i=sEI_src, j=sEI_tar) SynII.connect(i=sII_src, j=sII_tar) tr.f_add_result('sIE_src', sIE_src) tr.f_add_result('sIE_tar', sIE_tar) tr.f_add_result('sEI_src', sEI_src) tr.f_add_result('sEI_tar', sEI_tar) tr.f_add_result('sII_src', sII_src) tr.f_add_result('sII_tar', sII_tar) # if tr.strct_active: # SynEE.a = 0 # else: SynEE.a = tr.a_ee SynEE.insert_P = tr.insert_P # make synapse active at beginning #if not tr.strct_active: SynEE.run_regularly(tr.synEE_p_activate, dt=tr.T, when='start', order=-100) # synaptic scaling if tr.netw.config.scl_active: SynEE.summed_updaters['Asum_post']._clock = Clock( dt=tr.dt_synEE_scaling) SynEE.run_regularly(tr.synEE_scaling, dt=tr.dt_synEE_scaling, when='end') # intrinsic plasticity if tr.netw.config.it_active: GExc.h_ip = tr.h_ip GExc.run_regularly(tr.intrinsic_mod, dt=tr.it_dt, when='end') # structural plasticity if tr.netw.config.strct_active: SynEE.run_regularly(tr.strct_mod, dt=tr.strct_dt, when='end') # -------------- recording ------------------ #run(tr.sim.preT) GExc_recvars = [] if tr.memtraces_rec: GExc_recvars.append('V') if tr.vttraces_rec: GExc_recvars.append('Vt') if tr.getraces_rec: GExc_recvars.append('ge') if tr.gitraces_rec: GExc_recvars.append('gi') GInh_recvars = GExc_recvars GExc_stat = StateMonitor(GExc, GExc_recvars, record=[0, 1, 2], dt=tr.GExc_stat_dt) GInh_stat = StateMonitor(GInh, GInh_recvars, record=[0, 1, 2], dt=tr.GInh_stat_dt) SynEE_recvars = [] if tr.synee_atraces_rec: SynEE_recvars.append('a') if tr.synee_Apretraces_rec: SynEE_recvars.append('Apre') if tr.synee_Aposttraces_rec: SynEE_recvars.append('Apost') SynEE_stat = StateMonitor(SynEE, SynEE_recvars, record=range(tr.n_synee_traces_rec), when='end', dt=tr.synEE_stat_dt) GExc_spks = SpikeMonitor(GExc) GInh_spks = SpikeMonitor(GInh) SynEE_a = StateMonitor(SynEE, ['a', 'syn_active'], record=range(tr.N_e * (tr.N_e - 1)), dt=tr.sim.T / 10., when='end', order=100) run(tr.sim.T, report='text') SynEE_a.record_single_timestep() device.build(directory='../builds/%.4d' % (tr.v_idx)) tr.v_standard_result = Brian2MonitorResult tr.f_add_result('GExc_stat', GExc_stat) tr.f_add_result('SynEE_stat', SynEE_stat) print("Saving exc spikes... ", GExc_spks.get_states()['N']) tr.f_add_result('GExc_spks', GExc_spks) tr.f_add_result('GInh_stat', GInh_stat) print("Saving inh spikes... ", GInh_spks.get_states()['N']) tr.f_add_result('GInh_spks', GInh_spks) tr.f_add_result('SynEE_a', SynEE_a) # ----------------- add raw data ------------------------ fpath = '../builds/%.4d/' % (tr.v_idx) from pathlib import Path Path(fpath + 'turnover').touch() turnover_data = np.genfromtxt(fpath + 'turnover', delimiter=',') tr.f_add_result('turnover', turnover_data) os.remove(fpath + 'turnover') Path(fpath + 'spk_register').touch() spk_register_data = np.genfromtxt(fpath + 'spk_register', delimiter=',') tr.f_add_result('spk_register', spk_register_data) os.remove(fpath + 'spk_register')
def run_net(tr): # prefs.codegen.target = 'numpy' # prefs.codegen.target = 'cython' if tr.n_threads > 1: prefs.devices.cpp_standalone.openmp_threads = tr.n_threads set_device('cpp_standalone', directory='./builds/%.4d' % (tr.v_idx), build_on_run=False) print("Started process with id ", str(tr.v_idx)) T = tr.T1 + tr.T2 + tr.T3 + tr.T4 + tr.T5 namespace = tr.netw.f_to_dict(short_names=True, fast_access=True) namespace['idx'] = tr.v_idx defaultclock.dt = tr.netw.sim.dt # collect all network components dependent on configuration # (e.g. poisson vs. memnoise) and add them to the Brian 2 # network object later netw_objects = [] if tr.external_mode == 'memnoise': neuron_model = tr.condlif_memnoise elif tr.external_mode == 'poisson': neuron_model = tr.condlif_poisson GExc = NeuronGroup( N=tr.N_e, model=neuron_model, threshold=tr.nrnEE_thrshld, reset=tr.nrnEE_reset, #method=tr.neuron_method, namespace=namespace) GInh = NeuronGroup( N=tr.N_i, model=neuron_model, threshold='V > Vt', reset='V=Vr_i', #method=tr.neuron_method, namespace=namespace) if tr.external_mode == 'memnoise': GExc.mu, GInh.mu = tr.mu_e, tr.mu_i GExc.sigma, GInh.sigma = tr.sigma_e, tr.sigma_i GExc.Vt, GInh.Vt = tr.Vt_e, tr.Vt_i GExc.V , GInh.V = np.random.uniform(tr.Vr_e/mV, tr.Vt_e/mV, size=tr.N_e)*mV, \ np.random.uniform(tr.Vr_i/mV, tr.Vt_i/mV, size=tr.N_i)*mV netw_objects.extend([GExc, GInh]) synEE_pre_mod = mod.synEE_pre synEE_post_mod = mod.synEE_post if tr.external_mode == 'poisson': if tr.PInp_mode == 'pool': PInp = PoissonGroup(tr.NPInp, rates=tr.PInp_rate, namespace=namespace, name='poissongroup_exc') sPN = Synapses(target=GExc, source=PInp, model=tr.poisson_mod, on_pre='gfwd_post += a_EPoi', namespace=namespace, name='synPInpExc') sPN_src, sPN_tar = generate_N_connections(N_tar=tr.N_e, N_src=tr.NPInp, N=tr.NPInp_1n) elif tr.PInp_mode == 'indep': PInp = PoissonGroup(tr.N_e, rates=tr.PInp_rate, namespace=namespace) sPN = Synapses(target=GExc, source=PInp, model=tr.poisson_mod, on_pre='gfwd_post += a_EPoi', namespace=namespace, name='synPInp_inhInh') sPN_src, sPN_tar = range(tr.N_e), range(tr.N_e) sPN.connect(i=sPN_src, j=sPN_tar) if tr.PInp_mode == 'pool': PInp_inh = PoissonGroup(tr.NPInp_inh, rates=tr.PInp_inh_rate, namespace=namespace, name='poissongroup_inh') sPNInh = Synapses(target=GInh, source=PInp_inh, model=tr.poisson_mod, on_pre='gfwd_post += a_EPoi', namespace=namespace) sPNInh_src, sPNInh_tar = generate_N_connections(N_tar=tr.N_i, N_src=tr.NPInp_inh, N=tr.NPInp_inh_1n) elif tr.PInp_mode == 'indep': PInp_inh = PoissonGroup(tr.N_i, rates=tr.PInp_inh_rate, namespace=namespace) sPNInh = Synapses(target=GInh, source=PInp_inh, model=tr.poisson_mod, on_pre='gfwd_post += a_EPoi', namespace=namespace) sPNInh_src, sPNInh_tar = range(tr.N_i), range(tr.N_i) sPNInh.connect(i=sPNInh_src, j=sPNInh_tar) netw_objects.extend([PInp, sPN, PInp_inh, sPNInh]) if tr.syn_noise: synEE_mod = '''%s %s''' % (tr.synEE_noise, tr.synEE_mod) else: synEE_mod = '''%s %s''' % (tr.synEE_static, tr.synEE_mod) if tr.stdp_active: synEE_pre_mod = '''%s %s''' % (synEE_pre_mod, mod.synEE_pre_STDP) synEE_post_mod = '''%s %s''' % (synEE_post_mod, mod.synEE_post_STDP) if tr.synEE_rec: synEE_pre_mod = '''%s %s''' % (synEE_pre_mod, mod.synEE_pre_rec) synEE_post_mod = '''%s %s''' % (synEE_post_mod, mod.synEE_post_rec) # E<-E advanced synapse model, rest simple SynEE = Synapses(target=GExc, source=GExc, model=synEE_mod, on_pre=synEE_pre_mod, on_post=synEE_post_mod, namespace=namespace, dt=tr.synEE_mod_dt) SynIE = Synapses(target=GInh, source=GExc, on_pre='ge_post += a_ie', namespace=namespace) SynEI = Synapses(target=GExc, source=GInh, on_pre='gi_post += a_ei', namespace=namespace) SynII = Synapses(target=GInh, source=GInh, on_pre='gi_post += a_ii', namespace=namespace) if tr.strct_active: sEE_src, sEE_tar = generate_full_connectivity(tr.N_e, same=True) SynEE.connect(i=sEE_src, j=sEE_tar) SynEE.syn_active = 0 else: srcs_full, tars_full = generate_full_connectivity(tr.N_e, same=True) SynEE.connect(i=srcs_full, j=tars_full) SynEE.syn_active = 0 sIE_src, sIE_tar = generate_connections(tr.N_i, tr.N_e, tr.p_ie) sEI_src, sEI_tar = generate_connections(tr.N_e, tr.N_i, tr.p_ei) sII_src, sII_tar = generate_connections(tr.N_i, tr.N_i, tr.p_ii, same=True) SynIE.connect(i=sIE_src, j=sIE_tar) SynEI.connect(i=sEI_src, j=sEI_tar) SynII.connect(i=sII_src, j=sII_tar) tr.f_add_result('sIE_src', sIE_src) tr.f_add_result('sIE_tar', sIE_tar) tr.f_add_result('sEI_src', sEI_src) tr.f_add_result('sEI_tar', sEI_tar) tr.f_add_result('sII_src', sII_src) tr.f_add_result('sII_tar', sII_tar) if tr.syn_noise: SynEE.syn_sigma = tr.syn_sigma SynEE.insert_P = tr.insert_P SynEE.p_inactivate = tr.p_inactivate SynEE.stdp_active = 1 ATM_vals = np.random.normal(loc=tr.ATotalMax, scale=tr.ATotalMax_sd, size=tr.N_e * (tr.N_e - 1)) assert np.min(ATM_vals) > 0. SynEE.ATotalMax = ATM_vals # make randomly chosen synapses active at beginning rs = np.random.uniform(size=tr.N_e * (tr.N_e - 1)) initial_active = (rs < tr.p_ee).astype('int') initial_a = initial_active * tr.a_ee SynEE.syn_active = initial_active SynEE.a = initial_a # recording of stdp in T4 SynEE.stdp_rec_start = tr.T1 + tr.T2 + tr.T3 SynEE.stdp_rec_max = tr.T1 + tr.T2 + tr.T3 + tr.stdp_rec_T # synaptic scaling if tr.netw.config.scl_active: if tr.syn_scl_rec: SynEE.scl_rec_start = tr.T1 + tr.T2 + tr.T3 SynEE.scl_rec_max = tr.T1 + tr.T2 + tr.T3 + tr.scl_rec_T else: SynEE.scl_rec_start = T + 10 * second SynEE.scl_rec_max = T SynEE.summed_updaters['Asum_post']._clock = Clock( dt=tr.dt_synEE_scaling) synscaling = SynEE.run_regularly(tr.synEE_scaling, dt=tr.dt_synEE_scaling, when='end', name='syn_scaling') # # intrinsic plasticity # if tr.netw.config.it_active: # GExc.h_ip = tr.h_ip # GExc.run_regularly(tr.intrinsic_mod, dt = tr.it_dt, when='end') # structural plasticity if tr.netw.config.strct_active: if tr.strct_mode == 'zero': if tr.turnover_rec: strct_mod = '''%s %s''' % (tr.strct_mod, tr.turnover_rec_mod) else: strct_mod = tr.strct_mod strctplst = SynEE.run_regularly(strct_mod, dt=tr.strct_dt, when='end', name='strct_plst_zero') elif tr.strct_mode == 'thrs': if tr.turnover_rec: strct_mod_thrs = '''%s %s''' % (tr.strct_mod_thrs, tr.turnover_rec_mod) else: strct_mod_thrs = tr.strct_mod_thrs strctplst = SynEE.run_regularly(strct_mod_thrs, dt=tr.strct_dt, when='end', name='strct_plst_thrs') netw_objects.extend([SynEE, SynEI, SynIE, SynII]) # keep track of the number of active synapses sum_target = NeuronGroup(1, 'c : 1 (shared)', dt=tr.csample_dt) sum_model = '''NSyn : 1 (constant) c_post = (1.0*syn_active_pre)/NSyn : 1 (summed)''' sum_connection = Synapses(target=sum_target, source=SynEE, model=sum_model, dt=tr.csample_dt, name='get_active_synapse_count') sum_connection.connect() sum_connection.NSyn = tr.N_e * (tr.N_e - 1) if tr.adjust_insertP: # homeostatically adjust growth rate growth_updater = Synapses(sum_target, SynEE) growth_updater.run_regularly('insert_P_post *= 0.1/c_pre', when='after_groups', dt=tr.csample_dt, name='update_insP') growth_updater.connect(j='0') netw_objects.extend([sum_target, sum_connection, growth_updater]) # -------------- recording ------------------ GExc_recvars = [] if tr.memtraces_rec: GExc_recvars.append('V') if tr.vttraces_rec: GExc_recvars.append('Vt') if tr.getraces_rec: GExc_recvars.append('ge') if tr.gitraces_rec: GExc_recvars.append('gi') if tr.gfwdtraces_rec and tr.external_mode == 'poisson': GExc_recvars.append('gfwd') GInh_recvars = GExc_recvars GExc_stat = StateMonitor(GExc, GExc_recvars, record=[0, 1, 2], dt=tr.GExc_stat_dt) GInh_stat = StateMonitor(GInh, GInh_recvars, record=[0, 1, 2], dt=tr.GInh_stat_dt) SynEE_recvars = [] if tr.synee_atraces_rec: SynEE_recvars.append('a') if tr.synee_activetraces_rec: SynEE_recvars.append('syn_active') if tr.synee_Apretraces_rec: SynEE_recvars.append('Apre') if tr.synee_Aposttraces_rec: SynEE_recvars.append('Apost') SynEE_stat = StateMonitor(SynEE, SynEE_recvars, record=range(tr.n_synee_traces_rec), when='end', dt=tr.synEE_stat_dt) if tr.adjust_insertP: C_stat = StateMonitor(sum_target, 'c', dt=tr.csample_dt, record=[0], when='end') insP_stat = StateMonitor(SynEE, 'insert_P', dt=tr.csample_dt, record=[0], when='end') netw_objects.extend([C_stat, insP_stat]) GExc_spks = SpikeMonitor(GExc) GInh_spks = SpikeMonitor(GInh) GExc_rate = PopulationRateMonitor(GExc) GInh_rate = PopulationRateMonitor(GInh) if tr.external_mode == 'poisson': PInp_spks = SpikeMonitor(PInp) PInp_rate = PopulationRateMonitor(PInp) netw_objects.extend([PInp_spks, PInp_rate]) if tr.synee_a_nrecpoints == 0: SynEE_a_dt = 10 * tr.sim.T2 else: SynEE_a_dt = tr.sim.T2 / tr.synee_a_nrecpoints SynEE_a = StateMonitor(SynEE, ['a', 'syn_active'], record=range(tr.N_e * (tr.N_e - 1)), dt=SynEE_a_dt, when='end', order=100) netw_objects.extend([ GExc_stat, GInh_stat, SynEE_stat, SynEE_a, GExc_spks, GInh_spks, GExc_rate, GInh_rate ]) net = Network(*netw_objects) def set_active(*argv): for net_object in argv: net_object.active = True def set_inactive(*argv): for net_object in argv: net_object.active = False ### Simulation periods # --------- T1 --------- # initial recording period, # all recorders active set_active(GExc_spks, GInh_spks, SynEE_stat, GExc_stat, GInh_stat, GExc_rate, GInh_rate) if tr.external_mode == 'poisson': set_active(PInp_spks, PInp_rate) net.run(tr.sim.T1, report='text', report_period=300 * second, profile=True) # --------- T2 --------- # main simulation period # only active recordings are: # 1) turnover 2) C_stat 3) SynEE_a set_inactive(GExc_spks, GInh_spks, SynEE_stat, GExc_stat, GInh_stat, GExc_rate, GInh_rate) if tr.external_mode == 'poisson': set_inactive(PInp_spks, PInp_rate) net.run(tr.sim.T2, report='text', report_period=300 * second, profile=True) # --------- T3 --------- # second recording period, # all recorders active set_active(GExc_spks, GInh_spks, SynEE_stat, GExc_stat, GInh_stat, GExc_rate, GInh_rate) if tr.external_mode == 'poisson': set_active(PInp_spks, PInp_rate) net.run(tr.sim.T3, report='text', report_period=300 * second, profile=True) # --------- T4 --------- # record STDP and scaling weight changes to file # through the cpp models set_inactive(GExc_spks, GInh_spks, SynEE_stat, GExc_stat, GInh_stat, GExc_rate, GInh_rate) if tr.external_mode == 'poisson': set_inactive(PInp_spks, PInp_rate) net.run(tr.sim.T4, report='text', report_period=300 * second, profile=True) # --------- T5 --------- # freeze network and record Exc spikes # for cross correlations synscaling.active = False strctplst.active = False SynEE.stdp_active = 0 set_active(GExc_spks) net.run(tr.sim.T5, report='text', report_period=300 * second, profile=True) SynEE_a.record_single_timestep() device.build(directory='builds/%.4d' % (tr.v_idx), clean=True, compile=True, run=True, debug=False) # ----------------------------------------- # save monitors as raws in build directory raw_dir = 'builds/%.4d/raw/' % (tr.v_idx) if not os.path.exists(raw_dir): os.makedirs(raw_dir) with open(raw_dir + 'namespace.p', 'wb') as pfile: pickle.dump(namespace, pfile) with open(raw_dir + 'gexc_stat.p', 'wb') as pfile: pickle.dump(GExc_stat.get_states(), pfile) with open(raw_dir + 'ginh_stat.p', 'wb') as pfile: pickle.dump(GInh_stat.get_states(), pfile) with open(raw_dir + 'synee_stat.p', 'wb') as pfile: pickle.dump(SynEE_stat.get_states(), pfile) with open(raw_dir + 'synee_a.p', 'wb') as pfile: SynEE_a_states = SynEE_a.get_states() if tr.crs_crrs_rec: SynEE_a_states['i'] = list(SynEE.i) SynEE_a_states['j'] = list(SynEE.j) pickle.dump(SynEE_a_states, pfile) if tr.adjust_insertP: with open(raw_dir + 'c_stat.p', 'wb') as pfile: pickle.dump(C_stat.get_states(), pfile) with open(raw_dir + 'insP_stat.p', 'wb') as pfile: pickle.dump(insP_stat.get_states(), pfile) with open(raw_dir + 'gexc_spks.p', 'wb') as pfile: pickle.dump(GExc_spks.get_states(), pfile) with open(raw_dir + 'ginh_spks.p', 'wb') as pfile: pickle.dump(GInh_spks.get_states(), pfile) if tr.external_mode == 'poisson': with open(raw_dir + 'pinp_spks.p', 'wb') as pfile: pickle.dump(PInp_spks.get_states(), pfile) with open(raw_dir + 'gexc_rate.p', 'wb') as pfile: pickle.dump(GExc_rate.get_states(), pfile) if tr.rates_rec: pickle.dump(GExc_rate.smooth_rate(width=25 * ms), pfile) with open(raw_dir + 'ginh_rate.p', 'wb') as pfile: pickle.dump(GInh_rate.get_states(), pfile) if tr.rates_rec: pickle.dump(GInh_rate.smooth_rate(width=25 * ms), pfile) if tr.external_mode == 'poisson': with open(raw_dir + 'pinp_rate.p', 'wb') as pfile: pickle.dump(PInp_rate.get_states(), pfile) if tr.rates_rec: pickle.dump(PInp_rate.smooth_rate(width=25 * ms), pfile) # ----------------- add raw data ------------------------ fpath = 'builds/%.4d/' % (tr.v_idx) from pathlib import Path Path(fpath + 'turnover').touch() turnover_data = np.genfromtxt(fpath + 'turnover', delimiter=',') os.remove(fpath + 'turnover') with open(raw_dir + 'turnover.p', 'wb') as pfile: pickle.dump(turnover_data, pfile) Path(fpath + 'spk_register').touch() spk_register_data = np.genfromtxt(fpath + 'spk_register', delimiter=',') os.remove(fpath + 'spk_register') with open(raw_dir + 'spk_register.p', 'wb') as pfile: pickle.dump(spk_register_data, pfile) Path(fpath + 'scaling_deltas').touch() scaling_deltas_data = np.genfromtxt(fpath + 'scaling_deltas', delimiter=',') os.remove(fpath + 'scaling_deltas') with open(raw_dir + 'scaling_deltas.p', 'wb') as pfile: pickle.dump(scaling_deltas_data, pfile) with open(raw_dir + 'profiling_summary.txt', 'w+') as tfile: tfile.write(str(profiling_summary(net))) # --------------- cross-correlations --------------------- if tr.crs_crrs_rec: GExc_spks = GExc_spks.get_states() synee_a = SynEE_a_states wsize = 100 * pq.ms for binsize in [1 * pq.ms, 2 * pq.ms, 5 * pq.ms]: wlen = int(wsize / binsize) ts, idxs = GExc_spks['t'], GExc_spks['i'] idxs = idxs[ts > tr.T1 + tr.T2 + tr.T3 + tr.T4] ts = ts[ts > tr.T1 + tr.T2 + tr.T3 + tr.T4] ts = ts - (tr.T1 + tr.T2 + tr.T3 + tr.T4) sts = [ neo.SpikeTrain(ts[idxs == i] / second * pq.s, t_stop=tr.T5 / second * pq.s) for i in range(tr.N_e) ] crs_crrs, syn_a = [], [] for f, (i, j) in enumerate(zip(synee_a['i'], synee_a['j'])): if synee_a['syn_active'][-1][f] == 1: crs_crr, cbin = cch(BinnedSpikeTrain(sts[i], binsize=binsize), BinnedSpikeTrain(sts[j], binsize=binsize), cross_corr_coef=True, border_correction=True, window=(-1 * wlen, wlen)) crs_crrs.append(list(np.array(crs_crr).T[0])) syn_a.append(synee_a['a'][-1][f]) fname = 'crs_crrs_wsize%dms_binsize%fms_full' % (wsize / pq.ms, binsize / pq.ms) df = { 'cbin': cbin, 'crs_crrs': np.array(crs_crrs), 'syn_a': np.array(syn_a), 'binsize': binsize, 'wsize': wsize, 'wlen': wlen } with open('builds/%.4d/raw/' % (tr.v_idx) + fname + '.p', 'wb') as pfile: pickle.dump(df, pfile) # ----------------- clean up --------------------------- shutil.rmtree('builds/%.4d/results/' % (tr.v_idx)) # ---------------- plot results -------------------------- #os.chdir('./analysis/file_based/') from analysis.overview_fb import overview_figure overview_figure('builds/%.4d' % (tr.v_idx), namespace) from analysis.synw_fb import synw_figure synw_figure('builds/%.4d' % (tr.v_idx), namespace) from analysis.synw_log_fb import synw_log_figure synw_log_figure('builds/%.4d' % (tr.v_idx), namespace)
def test_from_papers_example(): """ Test Izhikevich_2007 example `brian2.readthedocs.io/en/stable/examples/frompapers.Izhikevich_2007.html` """ set_device('markdown', build_on_run=False) # Parameters simulation_duration = 6 * second # Neurons taum = 10*ms Ee = 0*mV vt = -54*mV vr = -60*mV El = -74*mV taue = 5*ms # STDP taupre = 20*ms taupost = taupre gmax = .01 dApre = .01 dApost = -dApre * taupre / taupost * 1.05 dApost *= gmax dApre *= gmax # Dopamine signaling tauc = 1000*ms taud = 200*ms taus = 1*ms epsilon_dopa = 5e-3 # Setting the stage # Stimuli section input_indices = array([0, 1, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0]) input_times = array([500, 550, 1000, 1010, 1500, 1510, 3500, 3550, 4000, 4010, 4500, 4510])*ms input = SpikeGeneratorGroup(2, input_indices, input_times) neurons = NeuronGroup(2, '''dv/dt = (ge * (Ee-vr) + El - v) / taum : volt dge/dt = -ge / taue : 1''', threshold='v>vt', reset='v = vr', method='exact') neurons.v = vr neurons_monitor = SpikeMonitor(neurons) synapse = Synapses(input, neurons, model='''s: volt''', on_pre='v += s') synapse.connect(i=[0, 1], j=[0, 1]) synapse.s = 100. * mV # STDP section synapse_stdp = Synapses(neurons, neurons, model='''mode: 1 dc/dt = -c / tauc : 1 (clock-driven) dd/dt = -d / taud : 1 (clock-driven) ds/dt = mode * c * d / taus : 1 (clock-driven) dApre/dt = -Apre / taupre : 1 (event-driven) dApost/dt = -Apost / taupost : 1 (event-driven)''', on_pre='''ge += s Apre += dApre c = clip(c + mode * Apost, -gmax, gmax) s = clip(s + (1-mode) * Apost, -gmax, gmax) ''', on_post='''Apost += dApost c = clip(c + mode * Apre, -gmax, gmax) s = clip(s + (1-mode) * Apre, -gmax, gmax) ''', method='euler' ) synapse_stdp.connect(i=0, j=1) synapse_stdp.mode = 0 synapse_stdp.s = 1e-10 synapse_stdp.c = 1e-10 synapse_stdp.d = 0 synapse_stdp_monitor = StateMonitor(synapse_stdp, ['s', 'c', 'd'], record=[0]) # Dopamine signaling section dopamine_indices = array([0, 0, 0]) dopamine_times = array([3520, 4020, 4520])*ms dopamine = SpikeGeneratorGroup(1, dopamine_indices, dopamine_times) dopamine_monitor = SpikeMonitor(dopamine) reward = Synapses(dopamine, synapse_stdp, model='''''', on_pre='''d_post += epsilon_dopa''', method='exact') reward.connect() # Simulation # Classical STDP synapse_stdp.mode = 0 run(simulation_duration/2) # Dopamine modulated STDP synapse_stdp.mode = 1 run(simulation_duration/2) device.build() md_str = device.md_text assert _markdown_lint(md_str) device.reinit()
def run_net(tr): # prefs.codegen.target = 'numpy' # prefs.codegen.target = 'cython' if tr.n_threads > 1: prefs.devices.cpp_standalone.openmp_threads = tr.n_threads set_device('cpp_standalone', directory='./builds/%.4d' % (tr.v_idx), build_on_run=False) # set brian 2 and numpy random seeds seed(tr.random_seed) np.random.seed(tr.random_seed + 11) print("Started process with id ", str(tr.v_idx)) T = tr.T1 + tr.T2 + tr.T3 + tr.T4 + tr.T5 namespace = tr.netw.f_to_dict(short_names=True, fast_access=True) namespace['idx'] = tr.v_idx defaultclock.dt = tr.netw.sim.dt # collect all network components dependent on configuration # (e.g. poisson vs. memnoise) and add them to the Brian 2 # network object later netw_objects = [] if tr.external_mode == 'memnoise': neuron_model = tr.condlif_memnoise elif tr.external_mode == 'poisson': raise NotImplementedError #neuron_model = tr.condlif_poisson if tr.syn_cond_mode == 'exp': neuron_model += tr.syn_cond_EE_exp print("Using EE exp mode") elif tr.syn_cond_mode == 'alpha': neuron_model += tr.syn_cond_EE_alpha print("Using EE alpha mode") elif tr.syn_cond_mode == 'biexp': neuron_model += tr.syn_cond_EE_biexp namespace['invpeakEE'] = (tr.tau_e / tr.tau_e_rise) ** \ (tr.tau_e_rise / (tr.tau_e - tr.tau_e_rise)) print("Using EE biexp mode") if tr.syn_cond_mode_EI == 'exp': neuron_model += tr.syn_cond_EI_exp print("Using EI exp mode") elif tr.syn_cond_mode_EI == 'alpha': neuron_model += tr.syn_cond_EI_alpha print("Using EI alpha mode") elif tr.syn_cond_mode_EI == 'biexp': neuron_model += tr.syn_cond_EI_biexp namespace['invpeakEI'] = (tr.tau_i / tr.tau_i_rise) ** \ (tr.tau_i_rise / (tr.tau_i - tr.tau_i_rise)) print("Using EI biexp mode") GExc = NeuronGroup( N=tr.N_e, model=neuron_model, threshold=tr.nrnEE_thrshld, reset=tr.nrnEE_reset, #method=tr.neuron_method, name='GExc', namespace=namespace) GInh = NeuronGroup( N=tr.N_i, model=neuron_model, threshold='V > Vt', reset='V=Vr_i', #method=tr.neuron_method, name='GInh', namespace=namespace) if tr.external_mode == 'memnoise': # GExc.mu, GInh.mu = [0.*mV] + (tr.N_e-1)*[tr.mu_e], tr.mu_i # GExc.sigma, GInh.sigma = [0.*mV] + (tr.N_e-1)*[tr.sigma_e], tr.sigma_i GExc.mu, GInh.mu = tr.mu_e, tr.mu_i GExc.sigma, GInh.sigma = tr.sigma_e, tr.sigma_i GExc.Vt, GInh.Vt = tr.Vt_e, tr.Vt_i GExc.V , GInh.V = np.random.uniform(tr.Vr_e/mV, tr.Vt_e/mV, size=tr.N_e)*mV, \ np.random.uniform(tr.Vr_i/mV, tr.Vt_i/mV, size=tr.N_i)*mV netw_objects.extend([GExc, GInh]) if tr.external_mode == 'poisson': if tr.PInp_mode == 'pool': PInp = PoissonGroup(tr.NPInp, rates=tr.PInp_rate, namespace=namespace, name='poissongroup_exc') sPN = Synapses(target=GExc, source=PInp, model=tr.poisson_mod, on_pre='gfwd_post += a_EPoi', namespace=namespace, name='synPInpExc') sPN_src, sPN_tar = generate_N_connections(N_tar=tr.N_e, N_src=tr.NPInp, N=tr.NPInp_1n) elif tr.PInp_mode == 'indep': PInp = PoissonGroup(tr.N_e, rates=tr.PInp_rate, namespace=namespace) sPN = Synapses(target=GExc, source=PInp, model=tr.poisson_mod, on_pre='gfwd_post += a_EPoi', namespace=namespace, name='synPInp_inhInh') sPN_src, sPN_tar = range(tr.N_e), range(tr.N_e) sPN.connect(i=sPN_src, j=sPN_tar) if tr.PInp_mode == 'pool': PInp_inh = PoissonGroup(tr.NPInp_inh, rates=tr.PInp_inh_rate, namespace=namespace, name='poissongroup_inh') sPNInh = Synapses(target=GInh, source=PInp_inh, model=tr.poisson_mod, on_pre='gfwd_post += a_EPoi', namespace=namespace) sPNInh_src, sPNInh_tar = generate_N_connections(N_tar=tr.N_i, N_src=tr.NPInp_inh, N=tr.NPInp_inh_1n) elif tr.PInp_mode == 'indep': PInp_inh = PoissonGroup(tr.N_i, rates=tr.PInp_inh_rate, namespace=namespace) sPNInh = Synapses(target=GInh, source=PInp_inh, model=tr.poisson_mod, on_pre='gfwd_post += a_EPoi', namespace=namespace) sPNInh_src, sPNInh_tar = range(tr.N_i), range(tr.N_i) sPNInh.connect(i=sPNInh_src, j=sPNInh_tar) netw_objects.extend([PInp, sPN, PInp_inh, sPNInh]) if tr.syn_noise: if tr.syn_noise_type == 'additive': synEE_mod = '''%s %s''' % (tr.synEE_noise_add, tr.synEE_mod) synEI_mod = '''%s %s''' % (tr.synEE_noise_add, tr.synEE_mod) elif tr.syn_noise_type == 'multiplicative': synEE_mod = '''%s %s''' % (tr.synEE_noise_mult, tr.synEE_mod) synEI_mod = '''%s %s''' % (tr.synEE_noise_mult, tr.synEE_mod) else: synEE_mod = '''%s %s''' % (tr.synEE_static, tr.synEE_mod) synEI_mod = '''%s %s''' % (tr.synEE_static, tr.synEE_mod) if tr.scl_active: synEE_mod = '''%s %s''' % (synEE_mod, tr.synEE_scl_mod) synEI_mod = '''%s %s''' % (synEI_mod, tr.synEI_scl_mod) if tr.syn_cond_mode == 'exp': synEE_pre_mod = mod.synEE_pre_exp elif tr.syn_cond_mode == 'alpha': synEE_pre_mod = mod.synEE_pre_alpha elif tr.syn_cond_mode == 'biexp': synEE_pre_mod = mod.synEE_pre_biexp synEE_post_mod = mod.syn_post if tr.stdp_active: synEE_pre_mod = '''%s %s''' % (synEE_pre_mod, mod.syn_pre_STDP) synEE_post_mod = '''%s %s''' % (synEE_post_mod, mod.syn_post_STDP) if tr.synEE_rec: synEE_pre_mod = '''%s %s''' % (synEE_pre_mod, mod.synEE_pre_rec) synEE_post_mod = '''%s %s''' % (synEE_post_mod, mod.synEE_post_rec) # E<-E advanced synapse model SynEE = Synapses(target=GExc, source=GExc, model=synEE_mod, on_pre=synEE_pre_mod, on_post=synEE_post_mod, namespace=namespace, dt=tr.synEE_mod_dt) if tr.istdp_active and tr.istdp_type == 'dbexp': if tr.syn_cond_mode_EI == 'exp': EI_pre_mod = mod.synEI_pre_exp elif tr.syn_cond_mode_EI == 'alpha': EI_pre_mod = mod.synEI_pre_alpha elif tr.syn_cond_mode_EI == 'biexp': EI_pre_mod = mod.synEI_pre_biexp synEI_pre_mod = '''%s %s''' % (EI_pre_mod, mod.syn_pre_STDP) synEI_post_mod = '''%s %s''' % (mod.syn_post, mod.syn_post_STDP) elif tr.istdp_active and tr.istdp_type == 'sym': if tr.syn_cond_mode_EI == 'exp': EI_pre_mod = mod.synEI_pre_sym_exp elif tr.syn_cond_mode_EI == 'alpha': EI_pre_mod = mod.synEI_pre_sym_alpha elif tr.syn_cond_mode_EI == 'biexp': EI_pre_mod = mod.synEI_pre_sym_biexp synEI_pre_mod = '''%s %s''' % (EI_pre_mod, mod.syn_pre_STDP) synEI_post_mod = '''%s %s''' % (mod.synEI_post_sym, mod.syn_post_STDP) if tr.istdp_active and tr.synEI_rec: synEI_pre_mod = '''%s %s''' % (synEI_pre_mod, mod.synEI_pre_rec) synEI_post_mod = '''%s %s''' % (synEI_post_mod, mod.synEI_post_rec) if tr.istdp_active: SynEI = Synapses(target=GExc, source=GInh, model=synEI_mod, on_pre=synEI_pre_mod, on_post=synEI_post_mod, namespace=namespace, dt=tr.synEE_mod_dt) else: model = '''a : 1 syn_active : 1''' SynEI = Synapses(target=GExc, source=GInh, model=model, on_pre='gi_post += a', namespace=namespace) #other simple SynIE = Synapses(target=GInh, source=GExc, on_pre='ge_post += a_ie', namespace=namespace) SynII = Synapses(target=GInh, source=GInh, on_pre='gi_post += a_ii', namespace=namespace) sEE_src, sEE_tar = generate_full_connectivity(tr.N_e, same=True) SynEE.connect(i=sEE_src, j=sEE_tar) SynEE.syn_active = 0 SynEE.taupre, SynEE.taupost = tr.taupre, tr.taupost if tr.istdp_active and tr.istrct_active: print('istrct active') sEI_src, sEI_tar = generate_full_connectivity(Nsrc=tr.N_i, Ntar=tr.N_e, same=False) SynEI.connect(i=sEI_src, j=sEI_tar) SynEI.syn_active = 0 else: print('istrct not active') if tr.weight_mode == 'init': sEI_src, sEI_tar = generate_connections(tr.N_e, tr.N_i, tr.p_ei) # print('Index Zero will not get inhibition') # sEI_src, sEI_tar = np.array(sEI_src), np.array(sEI_tar) # sEI_src, sEI_tar = sEI_src[sEI_tar > 0],sEI_tar[sEI_tar > 0] elif tr.weight_mode == 'load': fpath = os.path.join(tr.basepath, tr.weight_path) with open(fpath + 'synei_a.p', 'rb') as pfile: synei_a_init = pickle.load(pfile) sEI_src, sEI_tar = synei_a_init['i'], synei_a_init['j'] SynEI.connect(i=sEI_src, j=sEI_tar) if tr.istdp_active: SynEI.taupre, SynEI.taupost = tr.taupre_EI, tr.taupost_EI sIE_src, sIE_tar = generate_connections(tr.N_i, tr.N_e, tr.p_ie) sII_src, sII_tar = generate_connections(tr.N_i, tr.N_i, tr.p_ii, same=True) SynIE.connect(i=sIE_src, j=sIE_tar) SynII.connect(i=sII_src, j=sII_tar) tr.f_add_result('sEE_src', sEE_src) tr.f_add_result('sEE_tar', sEE_tar) tr.f_add_result('sIE_src', sIE_src) tr.f_add_result('sIE_tar', sIE_tar) tr.f_add_result('sEI_src', sEI_src) tr.f_add_result('sEI_tar', sEI_tar) tr.f_add_result('sII_src', sII_src) tr.f_add_result('sII_tar', sII_tar) if tr.syn_noise: SynEE.syn_sigma = tr.syn_sigma SynEE.run_regularly('a = clip(a,0,amax)', when='after_groups', name='SynEE_noise_clipper') if tr.syn_noise and tr.istdp_active: SynEI.syn_sigma = tr.syn_sigma SynEI.run_regularly('a = clip(a,0,amax)', when='after_groups', name='SynEI_noise_clipper') SynEE.insert_P = tr.insert_P SynEE.p_inactivate = tr.p_inactivate SynEE.stdp_active = 1 print('Setting maximum EE weight threshold to ', tr.amax) SynEE.amax = tr.amax if tr.istdp_active: SynEI.insert_P = tr.insert_P_ei SynEI.p_inactivate = tr.p_inactivate_ei SynEI.stdp_active = 1 SynEI.amax = tr.amax SynEE.syn_active, SynEE.a = init_synapses('EE', tr) SynEI.syn_active, SynEI.a = init_synapses('EI', tr) # recording of stdp in T4 SynEE.stdp_rec_start = tr.T1 + tr.T2 + tr.T3 SynEE.stdp_rec_max = tr.T1 + tr.T2 + tr.T3 + tr.stdp_rec_T if tr.istdp_active: SynEI.stdp_rec_start = tr.T1 + tr.T2 + tr.T3 SynEI.stdp_rec_max = tr.T1 + tr.T2 + tr.T3 + tr.stdp_rec_T # synaptic scaling if tr.netw.config.scl_active: if tr.syn_scl_rec: SynEE.scl_rec_start = tr.T1 + tr.T2 + tr.T3 SynEE.scl_rec_max = tr.T1 + tr.T2 + tr.T3 + tr.scl_rec_T else: SynEE.scl_rec_start = T + 10 * second SynEE.scl_rec_max = T if tr.sig_ATotalMax == 0.: GExc.ANormTar = tr.ATotalMax else: GExc.ANormTar = np.random.normal(loc=tr.ATotalMax, scale=tr.sig_ATotalMax, size=tr.N_e) SynEE.summed_updaters['AsumEE_post']._clock = Clock( dt=tr.dt_synEE_scaling) synee_scaling = SynEE.run_regularly(tr.synEE_scaling, dt=tr.dt_synEE_scaling, when='end', name='synEE_scaling') if tr.istdp_active and tr.netw.config.iscl_active: if tr.syn_iscl_rec: SynEI.scl_rec_start = tr.T1 + tr.T2 + tr.T3 SynEI.scl_rec_max = tr.T1 + tr.T2 + tr.T3 + tr.scl_rec_T else: SynEI.scl_rec_start = T + 10 * second SynEI.scl_rec_max = T if tr.sig_iATotalMax == 0.: GExc.iANormTar = tr.iATotalMax else: GExc.iANormTar = np.random.normal(loc=tr.iATotalMax, scale=tr.sig_iATotalMax, size=tr.N_e) SynEI.summed_updaters['AsumEI_post']._clock = Clock( dt=tr.dt_synEE_scaling) synei_scaling = SynEI.run_regularly(tr.synEI_scaling, dt=tr.dt_synEE_scaling, when='end', name='synEI_scaling') # # intrinsic plasticity # if tr.netw.config.it_active: # GExc.h_ip = tr.h_ip # GExc.run_regularly(tr.intrinsic_mod, dt = tr.it_dt, when='end') # structural plasticity if tr.netw.config.strct_active: if tr.strct_mode == 'zero': if tr.turnover_rec: strct_mod = '''%s %s''' % (tr.strct_mod, tr.turnover_rec_mod) else: strct_mod = tr.strct_mod strctplst = SynEE.run_regularly(strct_mod, dt=tr.strct_dt, when='end', name='strct_plst_zero') elif tr.strct_mode == 'thrs': if tr.turnover_rec: strct_mod_thrs = '''%s %s''' % (tr.strct_mod_thrs, tr.turnover_rec_mod) else: strct_mod_thrs = tr.strct_mod_thrs strctplst = SynEE.run_regularly(strct_mod_thrs, dt=tr.strct_dt, when='end', name='strct_plst_thrs') if tr.istdp_active and tr.netw.config.istrct_active: if tr.strct_mode == 'zero': if tr.turnover_rec: strct_mod_EI = '''%s %s''' % (tr.strct_mod, tr.turnoverEI_rec_mod) else: strct_mod_EI = tr.strct_mod strctplst_EI = SynEI.run_regularly(strct_mod_EI, dt=tr.strct_dt, when='end', name='strct_plst_EI') elif tr.strct_mode == 'thrs': raise NotImplementedError netw_objects.extend([SynEE, SynEI, SynIE, SynII]) # keep track of the number of active synapses sum_target = NeuronGroup(1, 'c : 1 (shared)', dt=tr.csample_dt) sum_model = '''NSyn : 1 (constant) c_post = (1.0*syn_active_pre)/NSyn : 1 (summed)''' sum_connection = Synapses(target=sum_target, source=SynEE, model=sum_model, dt=tr.csample_dt, name='get_active_synapse_count') sum_connection.connect() sum_connection.NSyn = tr.N_e * (tr.N_e - 1) if tr.adjust_insertP: # homeostatically adjust growth rate growth_updater = Synapses(sum_target, SynEE) growth_updater.run_regularly('insert_P_post *= 0.1/c_pre', when='after_groups', dt=tr.csample_dt, name='update_insP') growth_updater.connect(j='0') netw_objects.extend([sum_target, sum_connection, growth_updater]) if tr.istdp_active and tr.istrct_active: # keep track of the number of active synapses sum_target_EI = NeuronGroup(1, 'c : 1 (shared)', dt=tr.csample_dt) sum_model_EI = '''NSyn : 1 (constant) c_post = (1.0*syn_active_pre)/NSyn : 1 (summed)''' sum_connection_EI = Synapses(target=sum_target_EI, source=SynEI, model=sum_model_EI, dt=tr.csample_dt, name='get_active_synapse_count_EI') sum_connection_EI.connect() sum_connection_EI.NSyn = tr.N_e * tr.N_i if tr.adjust_EI_insertP: # homeostatically adjust growth rate growth_updater_EI = Synapses(sum_target_EI, SynEI) growth_updater_EI.run_regularly('insert_P_post *= 0.1/c_pre', when='after_groups', dt=tr.csample_dt, name='update_insP_EI') growth_updater_EI.connect(j='0') netw_objects.extend( [sum_target_EI, sum_connection_EI, growth_updater_EI]) # -------------- recording ------------------ GExc_recvars = [] if tr.memtraces_rec: GExc_recvars.append('V') if tr.vttraces_rec: GExc_recvars.append('Vt') if tr.getraces_rec: GExc_recvars.append('ge') if tr.gitraces_rec: GExc_recvars.append('gi') if tr.gfwdtraces_rec and tr.external_mode == 'poisson': GExc_recvars.append('gfwd') GInh_recvars = GExc_recvars GExc_stat = StateMonitor(GExc, GExc_recvars, record=list(range(tr.nrec_GExc_stat)), dt=tr.GExc_stat_dt) GInh_stat = StateMonitor(GInh, GInh_recvars, record=list(range(tr.nrec_GInh_stat)), dt=tr.GInh_stat_dt) # SynEE stat SynEE_recvars = [] if tr.synee_atraces_rec: SynEE_recvars.append('a') if tr.synee_activetraces_rec: SynEE_recvars.append('syn_active') if tr.synee_Apretraces_rec: SynEE_recvars.append('Apre') if tr.synee_Aposttraces_rec: SynEE_recvars.append('Apost') SynEE_stat = StateMonitor(SynEE, SynEE_recvars, record=range(tr.n_synee_traces_rec), when='end', dt=tr.synEE_stat_dt) if tr.istdp_active: # SynEI stat SynEI_recvars = [] if tr.synei_atraces_rec: SynEI_recvars.append('a') if tr.synei_activetraces_rec: SynEI_recvars.append('syn_active') if tr.synei_Apretraces_rec: SynEI_recvars.append('Apre') if tr.synei_Aposttraces_rec: SynEI_recvars.append('Apost') SynEI_stat = StateMonitor(SynEI, SynEI_recvars, record=range(tr.n_synei_traces_rec), when='end', dt=tr.synEI_stat_dt) netw_objects.append(SynEI_stat) if tr.adjust_insertP: C_stat = StateMonitor(sum_target, 'c', dt=tr.csample_dt, record=[0], when='end') insP_stat = StateMonitor(SynEE, 'insert_P', dt=tr.csample_dt, record=[0], when='end') netw_objects.extend([C_stat, insP_stat]) if tr.istdp_active and tr.adjust_EI_insertP: C_EI_stat = StateMonitor(sum_target_EI, 'c', dt=tr.csample_dt, record=[0], when='end') insP_EI_stat = StateMonitor(SynEI, 'insert_P', dt=tr.csample_dt, record=[0], when='end') netw_objects.extend([C_EI_stat, insP_EI_stat]) GExc_spks = SpikeMonitor(GExc) GInh_spks = SpikeMonitor(GInh) GExc_rate = PopulationRateMonitor(GExc) GInh_rate = PopulationRateMonitor(GInh) if tr.external_mode == 'poisson': PInp_spks = SpikeMonitor(PInp) PInp_rate = PopulationRateMonitor(PInp) netw_objects.extend([PInp_spks, PInp_rate]) if tr.synee_a_nrecpoints == 0 or tr.sim.T2 == 0 * second: SynEE_a_dt = 2 * (tr.T1 + tr.T2 + tr.T3 + tr.T4 + tr.T5) else: SynEE_a_dt = tr.sim.T2 / tr.synee_a_nrecpoints # make sure that choice of SynEE_a_dt does lead # to execessively many recordings - this can # happen if t1 >> t2. estm_nrecs = int(T / SynEE_a_dt) if estm_nrecs > 3 * tr.synee_a_nrecpoints: print('''Estimated number of EE weight recordings (%d) exceeds desired number (%d), increasing SynEE_a_dt''' % (estm_nrecs, tr.synee_a_nrecpoints)) SynEE_a_dt = T / tr.synee_a_nrecpoints SynEE_a = StateMonitor(SynEE, ['a', 'syn_active'], record=range(tr.N_e * (tr.N_e - 1)), dt=SynEE_a_dt, when='end', order=100) if tr.istrct_active: record_range = range(tr.N_e * tr.N_i) else: record_range = range(len(sEI_src)) if tr.synei_a_nrecpoints > 0 and tr.sim.T2 > 0 * second: SynEI_a_dt = tr.sim.T2 / tr.synei_a_nrecpoints estm_nrecs = int(T / SynEI_a_dt) if estm_nrecs > 3 * tr.synei_a_nrecpoints: print('''Estimated number of EI weight recordings (%d) exceeds desired number (%d), increasing SynEI_a_dt''' % (estm_nrecs, tr.synei_a_nrecpoints)) SynEI_a_dt = T / tr.synei_a_nrecpoints SynEI_a = StateMonitor(SynEI, ['a', 'syn_active'], record=record_range, dt=SynEI_a_dt, when='end', order=100) netw_objects.append(SynEI_a) netw_objects.extend([ GExc_stat, GInh_stat, SynEE_stat, SynEE_a, GExc_spks, GInh_spks, GExc_rate, GInh_rate ]) if (tr.synEEdynrec and (2 * tr.syndynrec_npts * tr.syndynrec_dt < tr.sim.T2)): SynEE_dynrec = StateMonitor(SynEE, ['a'], record=range(tr.N_e * (tr.N_e - 1)), dt=tr.syndynrec_dt, name='SynEE_dynrec', when='end', order=100) SynEE_dynrec.active = False netw_objects.extend([SynEE_dynrec]) if (tr.synEIdynrec and (2 * tr.syndynrec_npts * tr.syndynrec_dt < tr.sim.T2)): SynEI_dynrec = StateMonitor(SynEI, ['a'], record=record_range, dt=tr.syndynrec_dt, name='SynEI_dynrec', when='end', order=100) SynEI_dynrec.active = False netw_objects.extend([SynEI_dynrec]) net = Network(*netw_objects) def set_active(*argv): for net_object in argv: net_object.active = True def set_inactive(*argv): for net_object in argv: net_object.active = False ### Simulation periods # --------- T1 --------- # initial recording period, # all recorders active T1T3_recorders = [ GExc_spks, GInh_spks, SynEE_stat, GExc_stat, GInh_stat, GExc_rate, GInh_rate ] if tr.istdp_active: T1T3_recorders.append(SynEI_stat) set_active(*T1T3_recorders) if tr.external_mode == 'poisson': set_active(PInp_spks, PInp_rate) net.run(tr.sim.T1, report='text', report_period=300 * second, profile=True) # --------- T2 --------- # main simulation period # only active recordings are: # 1) turnover 2) C_stat 3) SynEE_a set_inactive(*T1T3_recorders) if tr.T2_spks_rec: set_active(GExc_spks, GInh_spks) if tr.external_mode == 'poisson': set_inactive(PInp_spks, PInp_rate) run_T2_syndynrec(net, tr, netw_objects) # --------- T3 --------- # second recording period, # all recorders active set_active(*T1T3_recorders) if tr.external_mode == 'poisson': set_active(PInp_spks, PInp_rate) run_T3_split(net, tr) # --------- T4 --------- # record STDP and scaling weight changes to file # through the cpp models set_inactive(*T1T3_recorders) if tr.external_mode == 'poisson': set_inactive(PInp_spks, PInp_rate) run_T4(net, tr) # --------- T5 --------- # freeze network and record Exc spikes # for cross correlations if tr.scl_active: synee_scaling.active = False if tr.istdp_active and tr.netw.config.iscl_active: synei_scaling.active = False if tr.strct_active: strctplst.active = False if tr.istdp_active and tr.istrct_active: strctplst_EI.active = False SynEE.stdp_active = 0 if tr.istdp_active: SynEI.stdp_active = 0 set_active(GExc_rate, GInh_rate) set_active(GExc_spks, GInh_spks) run_T5(net, tr) SynEE_a.record_single_timestep() if tr.synei_a_nrecpoints > 0 and tr.sim.T2 > 0. * second: SynEI_a.record_single_timestep() device.build(directory='builds/%.4d' % (tr.v_idx), clean=True, compile=True, run=True, debug=False) # ----------------------------------------- # save monitors as raws in build directory raw_dir = 'builds/%.4d/raw/' % (tr.v_idx) if not os.path.exists(raw_dir): os.makedirs(raw_dir) with open(raw_dir + 'namespace.p', 'wb') as pfile: pickle.dump(namespace, pfile) with open(raw_dir + 'gexc_stat.p', 'wb') as pfile: pickle.dump(GExc_stat.get_states(), pfile) with open(raw_dir + 'ginh_stat.p', 'wb') as pfile: pickle.dump(GInh_stat.get_states(), pfile) with open(raw_dir + 'synee_stat.p', 'wb') as pfile: pickle.dump(SynEE_stat.get_states(), pfile) if tr.istdp_active: with open(raw_dir + 'synei_stat.p', 'wb') as pfile: pickle.dump(SynEI_stat.get_states(), pfile) if ((tr.synEEdynrec or tr.synEIdynrec) and (2 * tr.syndynrec_npts * tr.syndynrec_dt < tr.sim.T2)): if tr.synEEdynrec: with open(raw_dir + 'syneedynrec.p', 'wb') as pfile: pickle.dump(SynEE_dynrec.get_states(), pfile) if tr.synEIdynrec: with open(raw_dir + 'syneidynrec.p', 'wb') as pfile: pickle.dump(SynEI_dynrec.get_states(), pfile) with open(raw_dir + 'synee_a.p', 'wb') as pfile: SynEE_a_states = SynEE_a.get_states() if tr.crs_crrs_rec: SynEE_a_states['i'] = list(SynEE.i) SynEE_a_states['j'] = list(SynEE.j) pickle.dump(SynEE_a_states, pfile) if tr.synei_a_nrecpoints > 0 and tr.sim.T2 > 0. * second: with open(raw_dir + 'synei_a.p', 'wb') as pfile: SynEI_a_states = SynEI_a.get_states() if tr.crs_crrs_rec: SynEI_a_states['i'] = list(SynEI.i) SynEI_a_states['j'] = list(SynEI.j) pickle.dump(SynEI_a_states, pfile) if tr.adjust_insertP: with open(raw_dir + 'c_stat.p', 'wb') as pfile: pickle.dump(C_stat.get_states(), pfile) with open(raw_dir + 'insP_stat.p', 'wb') as pfile: pickle.dump(insP_stat.get_states(), pfile) if tr.istdp_active and tr.adjust_EI_insertP: with open(raw_dir + 'c_EI_stat.p', 'wb') as pfile: pickle.dump(C_EI_stat.get_states(), pfile) with open(raw_dir + 'insP_EI_stat.p', 'wb') as pfile: pickle.dump(insP_EI_stat.get_states(), pfile) with open(raw_dir + 'gexc_spks.p', 'wb') as pfile: pickle.dump(GExc_spks.get_states(), pfile) with open(raw_dir + 'ginh_spks.p', 'wb') as pfile: pickle.dump(GInh_spks.get_states(), pfile) if tr.external_mode == 'poisson': with open(raw_dir + 'pinp_spks.p', 'wb') as pfile: pickle.dump(PInp_spks.get_states(), pfile) with open(raw_dir + 'gexc_rate.p', 'wb') as pfile: pickle.dump(GExc_rate.get_states(), pfile) if tr.rates_rec: pickle.dump(GExc_rate.smooth_rate(width=25 * ms), pfile) with open(raw_dir + 'ginh_rate.p', 'wb') as pfile: pickle.dump(GInh_rate.get_states(), pfile) if tr.rates_rec: pickle.dump(GInh_rate.smooth_rate(width=25 * ms), pfile) if tr.external_mode == 'poisson': with open(raw_dir + 'pinp_rate.p', 'wb') as pfile: pickle.dump(PInp_rate.get_states(), pfile) if tr.rates_rec: pickle.dump(PInp_rate.smooth_rate(width=25 * ms), pfile) # ----------------- add raw data ------------------------ fpath = 'builds/%.4d/' % (tr.v_idx) from pathlib import Path Path(fpath + 'turnover').touch() turnover_data = np.genfromtxt(fpath + 'turnover', delimiter=',') os.remove(fpath + 'turnover') with open(raw_dir + 'turnover.p', 'wb') as pfile: pickle.dump(turnover_data, pfile) Path(fpath + 'turnover_EI').touch() turnover_EI_data = np.genfromtxt(fpath + 'turnover_EI', delimiter=',') os.remove(fpath + 'turnover_EI') with open(raw_dir + 'turnover_EI.p', 'wb') as pfile: pickle.dump(turnover_EI_data, pfile) Path(fpath + 'spk_register').touch() spk_register_data = np.genfromtxt(fpath + 'spk_register', delimiter=',') os.remove(fpath + 'spk_register') with open(raw_dir + 'spk_register.p', 'wb') as pfile: pickle.dump(spk_register_data, pfile) Path(fpath + 'spk_register_EI').touch() spk_register_EI_data = np.genfromtxt(fpath + 'spk_register_EI', delimiter=',') os.remove(fpath + 'spk_register_EI') with open(raw_dir + 'spk_register_EI.p', 'wb') as pfile: pickle.dump(spk_register_EI_data, pfile) Path(fpath + 'scaling_deltas').touch() scaling_deltas_data = np.genfromtxt(fpath + 'scaling_deltas', delimiter=',') os.remove(fpath + 'scaling_deltas') with open(raw_dir + 'scaling_deltas.p', 'wb') as pfile: pickle.dump(scaling_deltas_data, pfile) Path(fpath + 'scaling_deltas_EI').touch() scaling_deltas_data = np.genfromtxt(fpath + 'scaling_deltas_EI', delimiter=',') os.remove(fpath + 'scaling_deltas_EI') with open(raw_dir + 'scaling_deltas_EI.p', 'wb') as pfile: pickle.dump(scaling_deltas_data, pfile) with open(raw_dir + 'profiling_summary.txt', 'w+') as tfile: tfile.write(str(profiling_summary(net))) # --------------- cross-correlations --------------------- if tr.crs_crrs_rec: GExc_spks = GExc_spks.get_states() synee_a = SynEE_a_states wsize = 100 * pq.ms for binsize in [1 * pq.ms, 2 * pq.ms, 5 * pq.ms]: wlen = int(wsize / binsize) ts, idxs = GExc_spks['t'], GExc_spks['i'] idxs = idxs[ts > tr.T1 + tr.T2 + tr.T3 + tr.T4] ts = ts[ts > tr.T1 + tr.T2 + tr.T3 + tr.T4] ts = ts - (tr.T1 + tr.T2 + tr.T3 + tr.T4) sts = [ neo.SpikeTrain(ts[idxs == i] / second * pq.s, t_stop=tr.T5 / second * pq.s) for i in range(tr.N_e) ] crs_crrs, syn_a = [], [] for f, (i, j) in enumerate(zip(synee_a['i'], synee_a['j'])): if synee_a['syn_active'][-1][f] == 1: crs_crr, cbin = cch(BinnedSpikeTrain(sts[i], binsize=binsize), BinnedSpikeTrain(sts[j], binsize=binsize), cross_corr_coef=True, border_correction=True, window=(-1 * wlen, wlen)) crs_crrs.append(list(np.array(crs_crr).T[0])) syn_a.append(synee_a['a'][-1][f]) fname = 'crs_crrs_wsize%dms_binsize%fms_full' % (wsize / pq.ms, binsize / pq.ms) df = { 'cbin': cbin, 'crs_crrs': np.array(crs_crrs), 'syn_a': np.array(syn_a), 'binsize': binsize, 'wsize': wsize, 'wlen': wlen } with open('builds/%.4d/raw/' % (tr.v_idx) + fname + '.p', 'wb') as pfile: pickle.dump(df, pfile) GInh_spks = GInh_spks.get_states() synei_a = SynEI_a_states wsize = 100 * pq.ms for binsize in [1 * pq.ms, 2 * pq.ms, 5 * pq.ms]: wlen = int(wsize / binsize) ts_E, idxs_E = GExc_spks['t'], GExc_spks['i'] idxs_E = idxs_E[ts_E > tr.T1 + tr.T2 + tr.T3 + tr.T4] ts_E = ts_E[ts_E > tr.T1 + tr.T2 + tr.T3 + tr.T4] ts_E = ts_E - (tr.T1 + tr.T2 + tr.T3 + tr.T4) ts_I, idxs_I = GInh_spks['t'], GInh_spks['i'] idxs_I = idxs_I[ts_I > tr.T1 + tr.T2 + tr.T3 + tr.T4] ts_I = ts_I[ts_I > tr.T1 + tr.T2 + tr.T3 + tr.T4] ts_I = ts_I - (tr.T1 + tr.T2 + tr.T3 + tr.T4) sts_E = [ neo.SpikeTrain(ts_E[idxs_E == i] / second * pq.s, t_stop=tr.T5 / second * pq.s) for i in range(tr.N_e) ] sts_I = [ neo.SpikeTrain(ts_I[idxs_I == i] / second * pq.s, t_stop=tr.T5 / second * pq.s) for i in range(tr.N_i) ] crs_crrs, syn_a = [], [] for f, (i, j) in enumerate(zip(synei_a['i'], synei_a['j'])): if synei_a['syn_active'][-1][f] == 1: crs_crr, cbin = cch(BinnedSpikeTrain(sts_I[i], binsize=binsize), BinnedSpikeTrain(sts_E[j], binsize=binsize), cross_corr_coef=True, border_correction=True, window=(-1 * wlen, wlen)) crs_crrs.append(list(np.array(crs_crr).T[0])) syn_a.append(synei_a['a'][-1][f]) fname = 'EI_crrs_wsize%dms_binsize%fms_full' % (wsize / pq.ms, binsize / pq.ms) df = { 'cbin': cbin, 'crs_crrs': np.array(crs_crrs), 'syn_a': np.array(syn_a), 'binsize': binsize, 'wsize': wsize, 'wlen': wlen } with open('builds/%.4d/raw/' % (tr.v_idx) + fname + '.p', 'wb') as pfile: pickle.dump(df, pfile) # ----------------- clean up --------------------------- shutil.rmtree('builds/%.4d/results/' % (tr.v_idx)) shutil.rmtree('builds/%.4d/static_arrays/' % (tr.v_idx)) shutil.rmtree('builds/%.4d/brianlib/' % (tr.v_idx)) shutil.rmtree('builds/%.4d/code_objects/' % (tr.v_idx)) # ---------------- plot results -------------------------- #os.chdir('./analysis/file_based/') if tr.istdp_active: from src.analysis.overview_winh import overview_figure overview_figure('builds/%.4d' % (tr.v_idx), namespace) else: from src.analysis.overview import overview_figure overview_figure('builds/%.4d' % (tr.v_idx), namespace) from src.analysis.synw_fb import synw_figure synw_figure('builds/%.4d' % (tr.v_idx), namespace) if tr.istdp_active: synw_figure('builds/%.4d' % (tr.v_idx), namespace, connections='EI') from src.analysis.synw_log_fb import synw_log_figure synw_log_figure('builds/%.4d' % (tr.v_idx), namespace) if tr.istdp_active: synw_log_figure('builds/%.4d' % (tr.v_idx), namespace, connections='EI')