ATTR_COLD void matrix_solver_t::setup_base(analog_net_t::list_t &nets)
{
log().debug("New solver setup\n");
m_nets.clear();
m_terms.clear();
for (auto & net : nets)
{
m_nets.push_back(net);
m_terms.push_back(palloc(terms_t));
m_rails_temp.push_back(palloc(terms_t));
}
for (std::size_t k = 0; k < nets.size(); k++)
{
log().debug("setting up net\n");
analog_net_t *net = nets[k];
net->m_solver = this;
for (core_terminal_t *p : net->m_core_terms)
{
log().debug("{1} {2} {3}\n", p->name(), net->name(), (int) net->isRailNet());
switch (p->type())
{
case terminal_t::TERMINAL:
switch (p->device().family())
{
case device_t::CAPACITOR:
if (!m_step_devices.contains(&p->device()))
m_step_devices.push_back(&p->device());
break;
case device_t::BJT_EB:
case device_t::DIODE:
case device_t::LVCCS:
case device_t::BJT_SWITCH:
log().debug("found BJT/Diode/LVCCS\n");
if (!m_dynamic_devices.contains(&p->device()))
m_dynamic_devices.push_back(&p->device());
break;
default:
break;
}
{
terminal_t *pterm = dynamic_cast<terminal_t *>(p);
add_term(k, pterm);
}
log().debug("Added terminal\n");
break;
case terminal_t::INPUT:
{
analog_output_t *net_proxy_output = nullptr;
for (auto & input : m_inps)
if (input->m_proxied_net == &p->net().as_analog())
{
net_proxy_output = input;
break;
}
if (net_proxy_output == nullptr)
{
//net_proxy_output = palloc(analog_output_t(*this,
// this->name() + "." + pfmt("m{1}")(m_inps.size())));
net_proxy_output = palloc(analog_output_t);
net_proxy_output->init_object(*this, this->name() + "." + pfmt("m{1}")(m_inps.size()));
m_inps.push_back(net_proxy_output);
net_proxy_output->m_proxied_net = &p->net().as_analog();
}
net_proxy_output->net().register_con(*p);
// FIXME: repeated
net_proxy_output->net().rebuild_list();
log().debug("Added input\n");
}
break;
default:
log().fatal("unhandled element found\n");
break;
}
}
log().debug("added net with {1} populated connections\n", net->m_core_terms.size());
}
/* now setup the matrix */
setup_matrix();
}
ATTR_COLD void matrix_solver_t::setup(analog_net_t::list_t &nets)
{
NL_VERBOSE_OUT(("New solver setup\n"));
m_nets.clear();
for (std::size_t k = 0; k < nets.size(); k++)
{
m_nets.add(nets[k]);
}
for (std::size_t k = 0; k < nets.size(); k++)
{
NL_VERBOSE_OUT(("setting up net\n"));
analog_net_t *net = nets[k];
net->m_solver = this;
for (std::size_t i = 0; i < net->m_core_terms.size(); i++)
{
core_terminal_t *p = net->m_core_terms[i];
NL_VERBOSE_OUT(("%s %s %d\n", p->name().cstr(), net->name().cstr(), (int) net->isRailNet()));
switch (p->type())
{
case terminal_t::TERMINAL:
switch (p->device().family())
{
case device_t::CAPACITOR:
if (!m_step_devices.contains(&p->device()))
m_step_devices.add(&p->device());
break;
case device_t::BJT_EB:
case device_t::DIODE:
case device_t::LVCCS:
case device_t::BJT_SWITCH:
NL_VERBOSE_OUT(("found BJT/Diode/LVCCS\n"));
if (!m_dynamic_devices.contains(&p->device()))
m_dynamic_devices.add(&p->device());
break;
default:
break;
}
{
terminal_t *pterm = dynamic_cast<terminal_t *>(p);
add_term(k, pterm);
}
NL_VERBOSE_OUT(("Added terminal\n"));
break;
case terminal_t::INPUT:
{
analog_output_t *net_proxy_output = NULL;
for (std::size_t i = 0; i < m_inps.size(); i++)
if (m_inps[i]->m_proxied_net == &p->net().as_analog())
{
net_proxy_output = m_inps[i];
break;
}
if (net_proxy_output == NULL)
{
net_proxy_output = palloc(analog_output_t);
net_proxy_output->init_object(*this, this->name() + "." + pstring::sprintf("m%" SIZETFMT, SIZET_PRINTF(m_inps.size())));
m_inps.add(net_proxy_output);
net_proxy_output->m_proxied_net = &p->net().as_analog();
}
net_proxy_output->net().register_con(*p);
// FIXME: repeated
net_proxy_output->net().rebuild_list();
NL_VERBOSE_OUT(("Added input\n"));
}
break;
default:
netlist().error("unhandled element found\n");
break;
}
}
NL_VERBOSE_OUT(("added net with %" SIZETFMT " populated connections\n", net->m_core_terms.size()));
}
}