Example #1
0
/// Testbench for the example GreenConfig
int sc_main(int argc, char *argv[]) {
  
  /// GreenControl Core instance
  gs::ctr::GC_Core       core;

  // GreenConfig Plugin
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin(&cnfdatabase);

  // Configuration with GreenConfig config files
  gs::cnf::ConfigFile_Tool configTool("ConfigFileTool");
  configTool.parseCommandLine(argc, argv); // parses the command line for --configfile
  configTool.config("array_test1.cfg");   // reads in a config file

  ArrayOwnerModule  owner      ("Owner");
  ArrayUserModule   user       ("User");

  //ShowSCObjects::showSCObjects();

  sc_core::sc_report_handler::set_actions(sc_core::SC_ERROR, sc_core::SC_ABORT);
  std::cout << "------ Simulation start ---------" << std::endl;
  sc_core::sc_start();
  std::cout << "------ Simulation stopped ---------" << std::endl;
  
  return EXIT_SUCCESS; 
  
}
Example #2
0
/// Testbench for the GreenControl analysis (GreenAV) example
int sc_main(int argc, char *argv[]) {
  
  // GreenControl Core instance
  gs::ctr::GC_Core       core;

  // GreenConfig Plugin
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin(&cnfdatabase);

  // GreenAV Plugin
  gs::av::GAV_Plugin analysisPlugin("AnalysisPlugin"); // Leave out the plugin completely to show that the simulation does not crash (but does not analyze of course)
  
  AVnewStatCalc             tool("AVnewStatCalc");
  AVnewStatCalcFormulaTest  formulaTest("AVnewStatCalcFormulaTest");

  // Add user defined calculation functions to Calculator class
  // This function will be usable by any Calculator<int> and Calculator_bit<int>
  gs::av::Calculator<int>::addFunc(&average,"average"); 
  // This function will be usable by any Calculator<double> and Calculator_bit<double>
  gs::av::Calculator<double>::addFunc(&Surrounding_Class::divide_by_three,"div3"); 

  std::cout << "-------------------- SIMULATION START -----------------------" << std::endl;

  sc_core::sc_start();
  
  std::cout << "-------------------- SIMULATION ENDED -----------------------" << std::endl;
  
  //ShowSCObjects::showSCObjects();

  return EXIT_SUCCESS; 
  
}
Example #3
0
/// main
int sc_main(int argc, char* argv[])
{

  /// GreenControl Core instance
  gs::ctr::GC_Core       core("ControlCore");
  // GreenConfig Plugin
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin("ConfigPlugin", &cnfdatabase);

  
  SlaveMem s1("Slave1",3);
  s1.setAddress(0x4000,0x400F);
  //Slave s2("Slave2",3); // zweiter Parameter: ACK-Delay in Taktzyklen
  //s2.setAddress(0x5000,0x500F);

  Master m1("M1");
  m1.init_port.target_addr = 0x4000;
  
  m1.init_port(s1.target_port);
  sc_core::sc_start();

  std::cout << std::endl << "Simulation stopped"<<std::endl;
  
  return 0;
}
Example #4
0
int sc_main(int argc, char** argv) {
  //sc_core::sc_report_handler::set_actions(sc_core::SC_ERROR, sc_core::SC_ABORT);  // make a breakpoint in SystemC file sc_stop_here.cpp
  //sc_core::sc_report_handler::set_actions(sc_core::SC_WARNING, sc_core::SC_ABORT);  // make a breakpoint in SystemC file sc_stop_here.cpp

  // Configure warnings about accesses to write protected register bits:
  sc_core::sc_report_handler::set_actions("/GreenSocs/GreenReg/write_protected/unequal_current", sc_core::SC_DISPLAY);
  sc_core::sc_report_handler::set_actions("/GreenSocs/GreenReg/write_protected/unequal_zero", sc_core::SC_DO_NOTHING);
  sc_core::sc_report_handler::set_actions("/GreenSocs/GreenReg/write_protected/bit_range_access", sc_core::SC_DISPLAY);
  sc_core::sc_report_handler::set_actions("/GreenSocs/GreenReg/write_protected/bit_access", sc_core::SC_DISPLAY);
  
  int opt = 0;
  if (argc!=2) {helpMsg;}
  else {
    opt = atoi(argv[1]);
    std::cout << "You gave " << opt << "\n";
    if ((opt!=1) && (opt!=2) && (opt!=3) && (opt!=4)) helpMsg;
  }
  /// GreenControl and GreenConfig
  gs::ctr::GC_Core core("ControlCore");
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin(&cnfdatabase);

  newMod nmod("newMod", opt);

  std::cout << "\nEntering sc_start : simulation starting\n";	
  sc_core::sc_start();		// (1000, SC_NS);						// Start the simulation
  std::cout << "Exited sc_start : simulation finished\n\n";	

  return( 0);
}
Example #5
0
/// main
int sc_main(int argc, char* argv[])
{

  //sc_report_handler::set_actions(SC_ERROR, SC_ABORT); 

  /// GreenControl Core instance
  gs::ctr::GC_Core core;
  // GreenConfig Plugin
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin(&cnfdatabase);

  
  SlaveMemBidir s1("Slave1",3);
  s1.setAddress(0x4000,0x400F);

  BidirModule m1("M1");
  m1.bidir_port.target_addr = 0x4000;
  

  // connect initiators and targets

  m1.bidir_port(s1.target_port);

  //ShowSCObjects::showSCObjects();

  sc_core::sc_start();

  std::cout << std::endl << "Simulation stopped"<<std::endl;
  
  return 0;
}
Example #6
0
/// main
int sc_main(int, char**)
{
//  sc_report_handler::set_actions(SC_ERROR, SC_ABORT); 
  
#ifdef USE_GPSOCKET
  /// GreenControl Core instance
  gs::ctr::GC_Core       core("ControlCore");
  // GreenConfig Plugin
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin("ConfigPlugin", &cnfdatabase);
#endif

  sillysort m("sillysort");
  simplememory s("simplememory");

  m.init_port(s.target_port);

  sc_core::sc_start(-1);

  return 0;
}
Example #7
0
/// main
int sc_main(int, char**)
{
//  sc_report_handler::set_actions(SC_ERROR, SC_ABORT); 
  
#ifdef USE_GPSOCKET
  /// GreenControl Core instance
  gs::ctr::GC_Core core();
  // GreenConfig Plugin
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin(&cnfdatabase);
#endif

  gs::gp::SimpleBusProtocol<32> p("Protocol", 10);
  gs::gp::fixedPriorityScheduler s("Scheduler");
  gs::gp::GenericRouter<32> r("Router");

  r.protocol_port(p);
  p.router_port(r);
  p.scheduler_port(s);

  sillysort m("sillysort");

  simplememory s1("simplememory1");
  s1.target_port.base_addr = 0x0;
  s1.target_port.high_addr = 0x10;

  simplememory s2("simplememory2");
  s2.target_port.base_addr = 0x11;
  s2.target_port.high_addr = 0xFFFF;

  m.init_port(r.target_socket);
  r.init_socket(s1.target_port);
  r.init_socket(s2.target_port);

 // m.init_port(s.target_port);

  sc_core::sc_start();

  return 0;
}
Example #8
0
/// main
int sc_main(int argc, char* argv[])
{

  /// GreenControl Core instance
  gs::ctr::GC_Core       core("ControlCore");
  // GreenConfig Plugin
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin("ConfigPlugin", &cnfdatabase);

  
  SlaveMem s1("Slave1",3);
  s1.setAddress(0x4000,0x4FFF);

  Master m1("M1");
  m1.init_port.target_addr = 0x4000;

  /*
  // Use generic router
  gs::gp::SimpleBusProtocol<32> p("Protocol", sc_core::sc_time(10, sc_core::SC_NS));
  gs::gp::fixedPriorityScheduler s("Scheduler");
  gs::gp::GenericRouter<32> r("Router");
  r.protocol_port(p);
  p.router_port(r);
  p.scheduler_port(s);
  // connect initiators and targets to the generic router ///////////////////
  m1.init_port(r.target_socket);
  r.init_socket(s1.target_port);
   */
  
  // direct connect without router
  m1.init_port(s1.target_port);
  
  sc_core::sc_start();

  std::cout << std::endl << "Simulation stopped"<<std::endl;
  
  return 0;
}
Example #9
0
/// main
int sc_main(int argc, char* argv[])
{

  /// GreenControl Core instance
  gs::ctr::GC_Core       core("ControlCore");
  // GreenConfig Plugin
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin("ConfigPlugin", &cnfdatabase);

  
  TestSlave sl("Slave",3);
  sl.setAddress(0x4000,0x400F);

  TestMaster ma("Master");
  ma.init_port.target_addr = 0x4000;
  
  ma.init_port(sl.target_port);
  sc_core::sc_start();

  std::cout << std::endl << "Simulation stopped"<<std::endl;
  
  return 0;
}
Example #10
0
int sc_main(int argc, char** argv){

  bool provoke_bind_error=false;
  if (argc>1){
    if (std::string(argv[1])=="provoke_bind_error")
      provoke_bind_error=true;
  }

#ifdef USE_GS_MONITOR
  /// GreenControl Core instance
  gs::ctr::GC_Core       core("ControlCore");
  
  // GreenConfig Plugin
  gs::cnf::ConfigDatabase cnfdatabase("ConfigDatabase");
  gs::cnf::ConfigPlugin configPlugin(&cnfdatabase);  
  gs::av::GAV_Plugin analysisPlugin("AnalysisPlugin", gs::av::STDOUT_OUT);    
#endif
  

  
  simple_b_gs_secure_adapter* a;
  if (!provoke_bind_error) a=new simple_b_gs_secure_adapter("A");
  simple_b_gs_master m("M");
  simple_b_gs_slave  s0("S0",true, false);
  simple_b_gs_slave_hier  s1("S1", false, true);
  ExplicitLTTarget   s2("S2");

  simple_b_gs_secure_slave  s3("S3");

#ifdef USE_GS_MONITOR  
  gs::socket::monitor<>* mon1=0, *mon2=0, *mon3=0, *mon4=0, *mon5=0;
  
  mon1=gs::socket::connect_with_monitor<32, tlm::tlm_base_protocol_types>(m.socket0, s0.socket);
  mon2=gs::socket::connect_with_monitor<32, tlm::tlm_base_protocol_types>(m.socket1, s1.socket);
  mon3=gs::socket::connect_with_monitor<32, tlm::tlm_base_protocol_types>(m.socket2, s2.socket);
#else
  m.socket0(s0.socket);
  m.socket1(s1.socket);
  m.socket2(s2.socket);
#endif
  
  if (provoke_bind_error)
    m.socket3(s3.socket);
  else{
#ifdef USE_GS_MONITOR  
    mon4=gs::socket::connect_with_monitor<32, tlm::tlm_base_protocol_types>(m.socket3, a->t_socket);
    mon5=gs::socket::connect_with_monitor<32, tlm::tlm_base_protocol_types>(a->i_socket, s3.socket);
#else
    m.socket3(a->t_socket);
    a->i_socket(s3.socket);
#endif
  }

#ifdef USE_GS_MONITOR
#define TEXT_OUT(mon) \
  if (mon) \
    gs::av::GAV_Api::getApiInstance(NULL)->add_to_default_output(\
      gs::av::TXT_FILE_OUT, \
      gs::cnf::GCnf_Api::getApiInstance(NULL)->getPar(mon->get_param().getName()))
  
  TEXT_OUT(mon1);
  TEXT_OUT(mon2);
  TEXT_OUT(mon3);
  TEXT_OUT(mon4);
  TEXT_OUT(mon5);

#undef TEXT(OUT)
#endif
  
  sc_core::sc_start();
#ifdef USE_GS_MONITOR  
  delete mon1;
  delete mon2;
  delete mon3;
  delete mon4;
  delete mon5;
#endif  
  return 0;
}