trick/trick_source/sim_services/Executive/Executive.cpp

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#include <iostream>
#include <math.h>
#include <sys/stat.h>
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#include "trick/Executive.hh"
#include "trick/ExecutiveException.hh"
#include "trick/TrickConstant.hh"
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Trick::Executive * the_exec ;
Trick::Executive::Executive() {
/** @par Detailed Design: */
the_exec = this ;
advance_sim_time_job = NULL ;
attach_debugger = false ;
curr_job = NULL ;
struct stat st ;
if ( stat("/usr/bin/gdb",&st) == 0 ) {
debugger_command = std::string("/usr/bin/gdb") ;
} else if ( stat("/usr/bin/lldb",&st) == 0 ) {
debugger_command = std::string("/usr/bin/lldb") ;
}
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enable_freeze = false ;
except_return = 0 ;
exec_command = NoCmd ;
async_freeze_command = false ;
freeze_command = false ;
freeze_on_frame_boundary = false ;
restart_called = false ;
initialization_complete = false ;
/** @li Assign default freeze_frame to be 1 second. */
freeze_frame = 1.0 ;
job_call_time_tics = 0 ;
mode = Initialization ;
num_classes = 0 ;
num_sim_objects = 0 ;
rt_nap = true ;
scheduled_start_index = 1000 ;
num_scheduled_job_classes = 0 ;
signal_caused_term = false ;
sim_start = 0.0 ;
/** @li Assign default software frame to be 1 second. */
software_frame = 1.0;
frame_count = 0 ;
stack_trace = true ;
/** @li Assign default terminate time to MAX_LONG_LONG tics. */
terminate_time = TRICK_MAX_LONG_LONG - 1;
time_last_pass_tics = 0 ;
/** @li Assign default time_tic value to be 1 us. */
time_tics = 0 ;
freeze_time_tics = 0 ;
freeze_frame_count = 0 ;
old_time_tic_value = 1000000 ;
time_tic_value = 1000000 ;
// Set the JobData copy of the time_tic_value to the executive value
Trick::JobData::set_time_tic_value(time_tic_value) ;
// These trap flags are set in init_signal_handlers()
trap_sigbus = false ;
trap_sigfpe = false ;
trap_sigsegv = false ;
trap_sigabrt = false ;
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build_date = std::string("unknown") ;
current_version = std::string("unknown") ;
version_date_tag = std::string("unknown") ;
num_all_jobs = 0 ;
all_jobs_for_checkpoint = NULL ;
software_frame_tics = (long long)(software_frame * time_tic_value) ;
next_frame_check_tics = software_frame_tics ;
freeze_frame_tics = (long long)(freeze_frame * time_tic_value) ;
next_freeze_frame_check_tics = freeze_frame_tics ;
freeze_job = NULL ;
advance_sim_time_job = NULL ;
curr_job = NULL ;
/** @li Map non-scheduled job class strings to job queues. */
class_map["default_data"] = num_classes ;
class_to_queue[num_classes++] = &default_data_queue ;
class_map["input_processor"] = num_classes ;
class_to_queue[num_classes++] = &input_processor_queue ;
class_map["initialization"] = num_classes ;
class_to_queue[num_classes++] = &initialization_queue ;
class_map["input_processor_run"] = num_classes ;
class_to_queue[num_classes++] = &input_processor_run_queue ;
class_map["top_of_frame"] = num_classes ;
class_to_queue[num_classes++] = &top_of_frame_queue ;
class_map["end_of_frame"] = num_classes ;
class_to_queue[num_classes++] = &end_of_frame_queue ;
class_map["shutdown"] = num_classes ;
class_to_queue[num_classes++] = &shutdown_queue ;
class_map["freeze_init"] = num_classes ;
class_to_queue[num_classes++] = &freeze_init_queue ;
class_map["freeze_scheduled"] = num_classes ;
class_to_queue[num_classes++] = &freeze_scheduled_queue ;
class_map["freeze_automatic"] = num_classes ;
class_to_queue[num_classes++] = &freeze_scheduled_queue ;
class_map["freeze"] = num_classes ;
class_to_queue[num_classes++] = &freeze_queue ;
class_map["unfreeze"] = num_classes ;
class_to_queue[num_classes++] = &unfreeze_queue ;
class_map["exec_time_tic_changed"] = num_classes ;
class_to_queue[num_classes++] = &time_tic_changed_queue ;
// Initialize all of default signal handlers
init_signal_handlers() ;
}
Trick::Executive::~Executive() {
while ( ! threads.empty() ) {
delete threads.back() ;
threads.pop_back() ;
}
}
int Trick::Executive::get_all_jobs_vector(std::vector<Trick::JobData *> & in_jobs_vector) {
in_jobs_vector = all_jobs_vector ;
return(0) ;
}
bool Trick::Executive::get_attach_debugger() {
return(attach_debugger) ;
}
std::string Trick::Executive::get_current_version() {
return(current_version) ;
}
std::string Trick::Executive::get_debugger_command() {
return(debugger_command) ;
}
SIM_COMMAND Trick::Executive::get_exec_command() {
return(exec_command) ;
}
bool Trick::Executive::get_enable_freeze() {
return(enable_freeze) ;
}
bool Trick::Executive::get_freeze_command() {
return(freeze_command) ;
}
bool Trick::Executive::get_freeze_on_frame_boundary() {
return(freeze_on_frame_boundary) ;
}
double Trick::Executive::get_freeze_frame() {
return(freeze_frame) ;
}
long long Trick::Executive::get_freeze_frame_tics() {
return(freeze_frame_tics) ;
}
SIM_MODE Trick::Executive::get_mode() {
return(mode) ;
}
unsigned int Trick::Executive::get_num_threads() {
return(threads.size()) ;
}
int Trick::Executive::get_old_time_tic_value() {
return(old_time_tic_value) ;
}
bool Trick::Executive::get_rt_nap() {
return(rt_nap) ;
}
int Trick::Executive::get_scheduled_start_index() {
return(scheduled_start_index) ;
}
int Trick::Executive::get_sim_objects(std::vector<Trick::SimObject *> & in_sim_objects) {
in_sim_objects = sim_objects ;
return(0) ;
}
double Trick::Executive::get_software_frame() {
return(software_frame) ;
}
long long Trick::Executive::get_software_frame_tics() {
return(software_frame_tics) ;
}
long long Trick::Executive::get_frame_count() {
return(frame_count) ;
}
long long Trick::Executive::get_freeze_frame_count() {
return(freeze_frame_count) ;
}
Trick::Threads * Trick::Executive::get_thread(unsigned int thread_id) {
if ( thread_id < threads.size() ) {
return threads[thread_id] ;
}
return NULL ;
}
pthread_t Trick::Executive::get_pthread_id(unsigned int thread_id) {
if ( thread_id < threads.size() ) {
return threads[thread_id]->get_pthread_id() ;
}
return 0 ;
}
bool Trick::Executive::get_stack_trace() {
return(stack_trace) ;
}
double Trick::Executive::get_thread_amf_cycle_time(unsigned int thread_id) {
if ( thread_id < threads.size() ) {
return threads[thread_id]->amf_cycle ;
}
return -1.0 ;
}
double Trick::Executive::get_terminate_time() {
return(terminate_time / time_tic_value) ;
}
int Trick::Executive::get_time_tic_value() {
return(time_tic_value) ;
}
long long Trick::Executive::get_freeze_time_tics() {
return(freeze_time_tics) ;
}
bool Trick::Executive::get_trap_sigbus() {
return(trap_sigbus) ;
}
bool Trick::Executive::get_trap_sigfpe() {
return(trap_sigfpe) ;
}
bool Trick::Executive::get_trap_sigsegv() {
return(trap_sigsegv) ;
}
bool Trick::Executive::get_trap_sigabrt() {
return(trap_sigabrt) ;
}
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void Trick::Executive::reset_job_cycle_times() {
unsigned int ii ;
for ( ii = 0 ; ii < all_jobs_vector.size() ; ii++ ) {
Trick::JobData * temp_job = all_jobs_vector[ii] ;
temp_job->calc_cycle_tics() ;
}
return ;
}
void Trick::Executive::reset_job_call_times() {
unsigned int ii ;
for ( ii = 0 ; ii < all_jobs_vector.size() ; ii++ ) {
Trick::JobData * temp_job = all_jobs_vector[ii] ;
temp_job->start_tics = (long long)round((double)temp_job->start_tics / old_time_tic_value * time_tic_value) + time_tics ;
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if ( temp_job->disabled == false and
(!temp_job->system_job_class or !temp_job->job_class_name.compare("system_advance_sim_time")) ) {
if ( ! temp_job->job_class_name.compare("integ_loop")) {
temp_job->next_tics = temp_job->cycle_tics + temp_job->start_tics ;
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} else {
temp_job->next_tics = temp_job->start_tics ;
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}
}
}
return ;
}
int Trick::Executive::set_attach_debugger(bool on_off) {
attach_debugger = on_off ;
return(0) ;
}
int Trick::Executive::set_debugger_command(std::string command) {
debugger_command = command ;
return(0) ;
}
int Trick::Executive::set_exec_command(SIM_COMMAND in_command) {
exec_command = in_command ;
return(0) ;
}
int Trick::Executive::set_enable_freeze(bool on_off) {
enable_freeze = on_off ;
return(0) ;
}
int Trick::Executive::set_freeze_command(bool on_off) {
freeze_command = on_off ;
return(0) ;
}
int Trick::Executive::set_freeze_on_frame_boundary(bool on_off) {
freeze_on_frame_boundary = on_off ;
return(0) ;
}
int Trick::Executive::set_freeze_frame(double in_frame) {
freeze_frame = in_frame ;
freeze_frame_tics = (long long)(freeze_frame * time_tic_value) ;
return(0) ;
}
int Trick::Executive::set_rt_nap(bool on_off) {
rt_nap = on_off ;
return(0) ;
}
int Trick::Executive::set_software_frame(double in_frame) {
software_frame = in_frame ;
software_frame_tics = (long long)(software_frame * time_tic_value) ;
next_frame_check_tics = (long long)((sim_start * time_tic_value) + software_frame_tics) ;
return(0) ;
}
int Trick::Executive::set_stack_trace(bool on_off) {
stack_trace = on_off ;
return(0) ;
}
int Trick::Executive::set_terminate_time(double in_time) {
terminate_time = (long long)(in_time * time_tic_value) ;
return(0) ;
}
int Trick::Executive::set_time(double in_time) {
time_tics = (long long)(in_time * time_tic_value) ;
for (unsigned int ii = 0 ; ii < threads.size() ; ii++ ) {
threads[ii]->curr_time_tics = time_tics ;
}
reset_job_call_times() ;
return(0) ;
}
int Trick::Executive::set_time_tics(long long in_tics) {
time_tics = in_tics ;
reset_job_call_times() ;
return(0) ;
}
int Trick::Executive::set_version_date_tag(std::string tag) {
this->version_date_tag = tag ;
return(0) ;
}
int Trick::Executive::set_build_date(std::string date) {
this->build_date = date ;
return(0) ;
}
int Trick::Executive::set_current_version(std::string version) {
this->current_version = version ;
return(0) ;
}