void aeif_cond_alpha_multisynapse::State_::get( DictionaryDatum& d ) const { def< double >( d, names::V_m, y_[ V_M ] ); std::vector< double_t >* g_exc = new std::vector< double_t >(); std::vector< double_t >* dg_exc = new std::vector< double_t >(); std::vector< double_t >* g_inh = new std::vector< double_t >(); std::vector< double_t >* dg_inh = new std::vector< double_t >(); for ( size_t i = 0; i < ( ( y_.size() - State_::NUMBER_OF_FIXED_STATES_ELEMENTS ) / State_::NUMBER_OF_STATES_ELEMENTS_PER_RECEPTOR ); ++i ) { g_exc->push_back( y_[ State_::G_EXC + ( State_::NUMBER_OF_STATES_ELEMENTS_PER_RECEPTOR * i ) ] ); dg_exc->push_back( y_[ State_::DG_EXC + ( State_::NUMBER_OF_STATES_ELEMENTS_PER_RECEPTOR * i ) ] ); g_inh->push_back( y_[ State_::G_INH + ( State_::NUMBER_OF_STATES_ELEMENTS_PER_RECEPTOR * i ) ] ); dg_inh->push_back( y_[ State_::DG_INH + ( State_::NUMBER_OF_STATES_ELEMENTS_PER_RECEPTOR * i ) ] ); } ( *d )[ names::g_ex ] = DoubleVectorDatum( g_exc ); ( *d )[ names::dg_ex ] = DoubleVectorDatum( dg_exc ); ( *d )[ names::g_in ] = DoubleVectorDatum( g_inh ); ( *d )[ names::dg_in ] = DoubleVectorDatum( dg_inh ); def< double >( d, names::w, y_[ W ] ); }
void nest::music_cont_in_proxy::get_status( DictionaryDatum& d ) const { P_.get( d ); S_.get( d ); ( *d )[ "data" ] = DoubleVectorDatum( new std::vector< double >( B_.data_ ) ); }
void nest::iaf_chs_2007::Parameters_::get(DictionaryDatum &d) const { def<double>(d, names::V_reset, U_reset_); def<double>(d, names::V_epsp, U_epsp_); def<double>(d, names::tau_epsp, tau_epsp_); def<double>(d, names::tau_reset, tau_reset_); def<double>(d, names::V_noise, U_noise_); (*d)[names::noise] = DoubleVectorDatum(new std::vector<double>(noise_)); }
void nest::spike_generator::Parameters_::get(DictionaryDatum &d) const { const size_t n_spikes = spike_stamps_.size(); const size_t n_offsets = spike_offsets_.size(); assert( ( precise_times_ && n_offsets == n_spikes ) || (!precise_times_ && n_offsets == 0 ) ); std::vector<double_t>* times_ms = new std::vector<double_t>(); times_ms->reserve(n_spikes); for ( size_t n = 0 ; n < n_spikes ; ++n ) { times_ms->push_back(spike_stamps_[n].get_ms()); if ( precise_times_ ) (*times_ms)[n] -= spike_offsets_[n]; } (*d)[names::spike_times] = DoubleVectorDatum(times_ms); (*d)["spike_weights"] = DoubleVectorDatum(new std::vector<double_t>(spike_weights_)); (*d)[names::precise_times] = BoolDatum(precise_times_); (*d)["allow_offgrid_spikes"] = BoolDatum(allow_offgrid_spikes_); (*d)["shift_now_spikes"] = BoolDatum(shift_now_spikes_); }