// Load balancing algorithm
std::string loba_algo("simple");
bool bookkeeping = false;
// Load balancing algorithm
std::string loba_algo("simple");
bool bookkeeping = false;
- // fixme: find better defaults
- cost_func comp_cost("1e9, 0");
- cost_func comm_cost("1, 0");
- double min_iter_duration = 1.0;
+ cost_func comp_cost("1e9, 0"); // fixme: find better defaults
+ cost_func comm_cost("1e6, 0"); // fixme: find better defaults
+ double min_comp_iter_duration = 1.0; // fixme: find better defaults
+ unsigned comp_iter_delay = 0; // fixme: find better defaults
+ double comp_time_delay = 0.0; // fixme: find better defaults
// Named parameters lists
loba_algorithms_type loba_algorithms;
loba_algorithms_type::loba_algorithms_type()
{
NOL_INSERT("fairstrategy", "balance with fair strategy", loba_fairstrategy);
// Named parameters lists
loba_algorithms_type loba_algorithms;
loba_algorithms_type::loba_algorithms_type()
{
NOL_INSERT("fairstrategy", "balance with fair strategy", loba_fairstrategy);
NOL_INSERT("none", "no load-balancing (for testing only)", process);
NOL_INSERT("simple", "balance with least loaded neighbor", loba_simple);
}
NOL_INSERT("none", "no load-balancing (for testing only)", process);
NOL_INSERT("simple", "balance with least loaded neighbor", loba_simple);
}
+template <typename T>
+bool opt_helper::parse_arg(char opt, const char *arg, T& val)
+{
+ std::istringstream str(arg);
+ bool result = (str >> val) && str.eof();
+ if (!result)
+ XBT_ERROR("invalid argument for option '-%c' -- \"%s\"", opt, arg);
+ return result;
+}
+
opt::program_name = argv[0];
opt::program_name.erase(0, 1 + opt::program_name.find_last_of('/'));
opt::program_name = argv[0];
opt::program_name.erase(0, 1 + opt::program_name.find_last_of('/'));
- while ((c = getopt(*argc, argv, "a:bc:C:ehi:I:l:L:N:s:t:T:vV")) != -1) {
+ while ((c = getopt(*argc, argv,
+ "a:bc:C:d:D:ehi:I:l:L:N:s:S:t:T:vV")) != -1) {
- opt::comm_cost = cost_func(optarg);
+ try {
+ opt::comm_cost = cost_func(optarg);
+ } catch (...) {
+ XBT_ERROR("invalid argument for option '-%c' -- \"%s\"", c, optarg);
+ result = false;
+ }
+ break;
+ case 'd':
+ PARSE_ARG(opt::comp_iter_delay);
+ break;
+ case 'D':
+ PARSE_ARG(opt::comp_time_delay);
DESCR("log rate", "%s", h.val_or_string(log_rate, "disabled"));
DESCR("platform file", "\"%s\"", platform_file.c_str());
if (auto_depl::enabled) {
DESCR("log rate", "%s", h.val_or_string(log_rate, "disabled"));
DESCR("platform file", "\"%s\"", platform_file.c_str());
if (auto_depl::enabled) {
DESCR("- topology", "%s", auto_depl::topology.c_str());
DESCR("- number of hosts", "%s", h.val_or_string(auto_depl::nhosts,
"auto"));
DESCR("- topology", "%s", auto_depl::topology.c_str());
DESCR("- number of hosts", "%s", h.val_or_string(auto_depl::nhosts,
"auto"));
}
DESCR("load balancing algorithm", "%s", loba_algo.c_str());
DESCR("bookkeeping", "%s", h.on_off(bookkeeping));
}
DESCR("load balancing algorithm", "%s", loba_algo.c_str());
DESCR("bookkeeping", "%s", h.on_off(bookkeeping));
DESCR("computation cost factors", "[%s]", comp_cost.to_string().c_str());
DESCR("communication cost factors", "[%s]", comm_cost.to_string().c_str());
DESCR("computation cost factors", "[%s]", comp_cost.to_string().c_str());
DESCR("communication cost factors", "[%s]", comm_cost.to_string().c_str());
- DESCR("minimum duration between iterations", "%g", min_iter_duration);
+ DESCR("minimum duration between comp. iterations", "%g", min_comp_iter_duration);
+ DESCR("computations start after lb. iter", "%u", comp_iter_delay);
+ DESCR("computations start after time", "%g", comp_time_delay);
DESCR("maximum number of lb. iterations", "%s",
h.val_or_string(lb_maxiter, "infinity"));
DESCR("maximum number of comp. iterations", "%s",
h.val_or_string(comp_maxiter, "infinity"));
DESCR("time limit", "%s", h.val_or_string(time_limit, "infinity"));
DESCR("exit on close", "%s", h.on_off(exit_on_close));
DESCR("maximum number of lb. iterations", "%s",
h.val_or_string(lb_maxiter, "infinity"));
DESCR("maximum number of comp. iterations", "%s",
h.val_or_string(comp_maxiter, "infinity"));
DESCR("time limit", "%s", h.val_or_string(time_limit, "infinity"));
DESCR("exit on close", "%s", h.on_off(exit_on_close));
<< " [" << opt::loba_algo << "]\n";
if (opt::help_requested > 1)
so_list(opt::loba_algorithms);
<< " [" << opt::loba_algo << "]\n";
if (opt::help_requested > 1)
so_list(opt::loba_algorithms);
- std::clog << o("-b") << "enable bookkeeping (\"virtual load\")\n";
+ std::clog << o("-b") << "toggle bookkeeping (\"virtual load\")"
+ << " [" << opt_helper::on_off(opt::bookkeeping) << "]\n";
+ std::clog << o("-s value")
+ << "minimum duration between lb. iterations"
+ << " [" << opt::min_lb_iter_duration << "]\n";
- std::clog << o("-s value")
- << "minimum duration between iterations"
- << " [" << opt::min_iter_duration << "]\n";
+ std::clog << o("-S value")
+ << "minimum duration between comp. iterations"
+ << " [" << opt::min_comp_iter_duration << "]\n";
+ std::clog << o("-d value")
+ << "start computations after given number of lb iterations"
+ << " [" << opt::comp_iter_delay << "]\n";
+ std::clog << o("-D value")
+ << "start computations after given time"
+ << " [" << opt::comp_time_delay << "]\n";
std::clog << o("-t value")
<< "time limit (simulated time), 0 for infinity"
<< " [" << opt::time_limit << "]\n";
std::clog << o("-t value")
<< "time limit (simulated time), 0 for infinity"
<< " [" << opt::time_limit << "]\n";
<< " depl : messages from auto deployment (inherited from main)\n"
<< " comm : messages from asynchronous pipes\n"
<< " proc : messages from base process class\n"
<< " depl : messages from auto deployment (inherited from main)\n"
<< " comm : messages from asynchronous pipes\n"
<< " proc : messages from base process class\n"