// performs the rl update at a state
void rl_perform_update( agent *my_agent, double op_value, bool op_rl, Symbol *goal, bool update_efr )
{
bool using_gaps = ( my_agent->rl_params->temporal_extension->get_value() == soar_module::on );
if ( !using_gaps || op_rl )
{
rl_data *data = goal->id.rl_info;
if ( !data->prev_op_rl_rules->empty() )
{
rl_et_map::iterator iter;
double alpha = my_agent->rl_params->learning_rate->get_value();
double lambda = my_agent->rl_params->et_decay_rate->get_value();
double gamma = my_agent->rl_params->discount_rate->get_value();
double tolerance = my_agent->rl_params->et_tolerance->get_value();
double theta = my_agent->rl_params->meta_learning_rate->get_value();
// if temporal_discount is off, don't discount for gaps
unsigned int effective_age = data->hrl_age + 1;
if (my_agent->rl_params->temporal_discount->get_value() == soar_module::on) {
effective_age += data->gap_age;
}
double discount = pow( gamma, static_cast< double >( effective_age ) );
// notify of gap closure
if ( data->gap_age && using_gaps && my_agent->sysparams[ TRACE_RL_SYSPARAM ] )
{
char buf[256];
SNPRINTF( buf, 254, "gap ended (%c%llu)", goal->id.name_letter, static_cast<long long unsigned>(goal->id.name_number) );
print( my_agent, buf );
xml_generate_warning( my_agent, buf );
}
// Iterate through eligibility_traces, decay traces. If less than TOLERANCE, remove from map.
if ( lambda == 0 )
{
if ( !data->eligibility_traces->empty() )
{
data->eligibility_traces->clear();
}
}
else
{
for ( iter = data->eligibility_traces->begin(); iter != data->eligibility_traces->end(); )
{
iter->second *= lambda;
iter->second *= discount;
if ( iter->second < tolerance )
{
data->eligibility_traces->erase( iter++ );
}
else
{
++iter;
}
}
}
// Update trace for just fired prods
double sum_old_ecr = 0.0;
double sum_old_efr = 0.0;
if ( !data->prev_op_rl_rules->empty() )
{
double trace_increment = ( 1.0 / static_cast<double>( data->prev_op_rl_rules->size() ) );
rl_rule_list::iterator p;
for ( p=data->prev_op_rl_rules->begin(); p!=data->prev_op_rl_rules->end(); p++ )
{
sum_old_ecr += (*p)->rl_ecr;
sum_old_efr += (*p)->rl_efr;
iter = data->eligibility_traces->find( (*p) );
if ( iter != data->eligibility_traces->end() )
{
iter->second += trace_increment;
}
else
{
(*data->eligibility_traces)[ (*p) ] = trace_increment;
}
}
}
// For each prod with a trace, perform update
{
double old_ecr, old_efr;
double delta_ecr, delta_efr;
double new_combined, new_ecr, new_efr;
double delta_t = (data->reward + discount * op_value) - (sum_old_ecr + sum_old_efr);
for ( iter = data->eligibility_traces->begin(); iter != data->eligibility_traces->end(); iter++ )
{
production *prod = iter->first;
// get old vals
old_ecr = prod->rl_ecr;
old_efr = prod->rl_efr;
// Adjust alpha based on decay policy
// Miller 11/14/2011
double adjusted_alpha;
switch (my_agent->rl_params->decay_mode->get_value())
{
case rl_param_container::exponential_decay:
adjusted_alpha = 1.0 / (prod->rl_update_count + 1.0);
break;
case rl_param_container::logarithmic_decay:
adjusted_alpha = 1.0 / (log(prod->rl_update_count + 1.0) + 1.0);
break;
case rl_param_container::delta_bar_delta_decay:
{
// Note that in this case, x_i = 1.0 for all productions that are being updated.
// Those values have been included here for consistency with the algorithm as described in the delta bar delta paper.
prod->rl_delta_bar_delta_beta = prod->rl_delta_bar_delta_beta + theta * delta_t * 1.0 * prod->rl_delta_bar_delta_h;
adjusted_alpha = exp(prod->rl_delta_bar_delta_beta);
double decay_term = 1.0 - adjusted_alpha * 1.0 * 1.0;
if (decay_term < 0.0) decay_term = 0.0;
prod->rl_delta_bar_delta_h = prod->rl_delta_bar_delta_h * decay_term + adjusted_alpha * delta_t * 1.0;
break;
}
case rl_param_container::normal_decay:
default:
adjusted_alpha = alpha;
break;
}
// calculate updates
delta_ecr = ( adjusted_alpha * iter->second * ( data->reward - sum_old_ecr ) );
if ( update_efr )
{
delta_efr = ( adjusted_alpha * iter->second * ( ( discount * op_value ) - sum_old_efr ) );
}
else
{
delta_efr = 0.0;
}
// calculate new vals
new_ecr = ( old_ecr + delta_ecr );
new_efr = ( old_efr + delta_efr );
new_combined = ( new_ecr + new_efr );
// print as necessary
if ( my_agent->sysparams[ TRACE_RL_SYSPARAM ] )
{
std::ostringstream ss;
ss << "RL update " << prod->name->sc.name << " "
<< old_ecr << " " << old_efr << " " << old_ecr + old_efr << " -> "
<< new_ecr << " " << new_efr << " " << new_combined ;
std::string temp_str( ss.str() );
print( my_agent, "%s\n", temp_str.c_str() );
xml_generate_message( my_agent, temp_str.c_str() );
// Log update to file if the log file has been set
std::string log_path = my_agent->rl_params->update_log_path->get_value();
if (!log_path.empty()) {
std::ofstream file(log_path.c_str(), std::ios_base::app);
file << ss.str() << std::endl;
file.close();
}
}
// Change value of rule
symbol_remove_ref( my_agent, rhs_value_to_symbol( prod->action_list->referent ) );
prod->action_list->referent = symbol_to_rhs_value( make_float_constant( my_agent, new_combined ) );
prod->rl_update_count += 1;
prod->rl_ecr = new_ecr;
prod->rl_efr = new_efr;
// change documentation
if ( my_agent->rl_params->meta->get_value() == soar_module::on )
{
if ( prod->documentation )
{
free_memory_block_for_string( my_agent, prod->documentation );
}
std::stringstream doc_ss;
const std::vector<std::pair<std::string, param_accessor<double> *> > &documentation_params = my_agent->rl_params->get_documentation_params();
for (std::vector<std::pair<std::string, param_accessor<double> *> >::const_iterator doc_params_it = documentation_params.begin();
doc_params_it != documentation_params.end(); ++doc_params_it) {
doc_ss << doc_params_it->first << "=" << doc_params_it->second->get_param(prod) << ";";
}
prod->documentation = make_memory_block_for_string(my_agent, doc_ss.str().c_str());
/*
std::string rlupdates( "rlupdates=" );
std::string val;
to_string( static_cast< uint64_t >( prod->rl_update_count ), val );
rlupdates.append( val );
prod->documentation = make_memory_block_for_string( my_agent, rlupdates.c_str() );
*/
}
// Change value of preferences generated by current instantiations of this rule
if ( prod->instantiations )
{
for ( instantiation *inst = prod->instantiations; inst; inst = inst->next )
{
for ( preference *pref = inst->preferences_generated; pref; pref = pref->inst_next )
{
symbol_remove_ref( my_agent, pref->referent );
pref->referent = make_float_constant( my_agent, new_combined );
}
}
}
}
}
}
data->gap_age = 0;
data->hrl_age = 0;
data->reward = 0.0;
}
}
void wma_go( agent* my_agent, wma_go_action go_action )
{
// update history for all touched elements
if ( go_action == wma_histories )
{
my_agent->wma_timers->history->start();
wma_update_decay_histories( my_agent );
my_agent->wma_timers->history->stop();
}
// check forgetting queue
else if ( go_action == wma_forgetting )
{
wma_param_container::forgetting_choices forgetting = my_agent->wma_params->forgetting->get_value();
if ( forgetting != wma_param_container::disabled )
{
my_agent->wma_timers->forgetting->start();
bool forgot_something = false;
if ( forgetting == wma_param_container::naive )
{
forgot_something = wma_forgetting_naive_sweep( my_agent );
}
else
{
forgot_something = wma_forgetting_update_p_queue( my_agent );
}
if ( forgot_something )
{
if ( my_agent->sysparams[ TRACE_WM_CHANGES_SYSPARAM ] )
{
const char *msg = "\n\nWMA: BEGIN FORGOTTEN WME LIST\n\n";
print( my_agent, const_cast<char *>( msg ) );
xml_generate_message( my_agent, const_cast<char *>( msg ) );
}
uint64_t wm_removal_diff = my_agent->wme_removal_count;
{
do_working_memory_phase( my_agent );
}
wm_removal_diff = ( my_agent->wme_removal_count - wm_removal_diff );
if ( wm_removal_diff > 0 )
{
my_agent->wma_stats->forgotten_wmes->set_value( my_agent->wma_stats->forgotten_wmes->get_value() + static_cast< int64_t >( wm_removal_diff ) );
}
if ( my_agent->sysparams[ TRACE_WM_CHANGES_SYSPARAM ] )
{
const char *msg = "\nWMA: END FORGOTTEN WME LIST\n\n";
print( my_agent, const_cast<char *>( msg ) );
xml_generate_message( my_agent, const_cast<char *>( msg ) );
}
}
my_agent->wma_timers->forgetting->stop();
}
}
}
