#include "simgrid/simix.hpp"
#include "src/plugins/vm/VirtualMachineImpl.hpp"
#include "src/surf/cpu_interface.hpp"
+
+#include <boost/algorithm/string/classification.hpp>
+#include <boost/algorithm/string/split.hpp>
+#include <simgrid/s4u/engine.hpp>
+#include <string>
#include <utility>
+#include <vector>
/** @addtogroup SURF_plugin_energy
follows:
\verbatim
-<host id="HostA" power="100.0Mf" >
- <prop id="watt_per_state" value="100.0:200.0" />
+<host id="HostA" power="100.0Mf" cores="8">
+ <prop id="watt_per_state" value="100.0:120.0:200.0" />
<prop id="watt_off" value="10" />
</host>
\endverbatim
The first property means that when your host is up and running, but without anything to do, it will dissipate 100 Watts.
-If it's fully loaded, it will dissipate 200 Watts. If its load is at 50%, then it will dissipate 150 Watts.
+If only one care is active, it will dissipate 120 Watts. If it's fully loaded, it will dissipate 200 Watts. If its load is at 50%, then it will dissipate 153.33 Watts.
The second property means that when your host is turned off, it will dissipate only 10 Watts (please note that these
values are arbitrary).
\verbatim
<host id="HostB" power="100.0Mf,50.0Mf,20.0Mf" pstate="0" >
- <prop id="watt_per_state" value="95.0:200.0, 93.0:170.0, 90.0:150.0" />
+ <prop id="watt_per_state" value="95.0:120.0:200.0, 93.0:115.0:170.0, 90.0:110.0:150.0" />
<prop id="watt_off" value="10" />
</host>
\endverbatim
It starts at pstate 0 (ie, at 100 Mflop/s). In this case, you have to specify one interval per pstate in the
watt_per_state property.
In this example, the idle consumption is 95 Watts, 93 Watts and 90 Watts in each pstate while the CPU burn consumption
-are at 200 Watts, 170 Watts, and 150 Watts respectively.
+are at 200 Watts, 170 Watts, and 150 Watts respectively. If only one core is active, this machine consumes 120 / 115 / 110 watts.
To change the pstate of a given CPU, use the following functions:
#MSG_host_get_nb_pstates(), simgrid#s4u#Host#setPstate(), #MSG_host_get_power_peak_at().
{
xbt_assert(!power_range_watts_list.empty(), "No power range properties specified for host %s", host->cname());
- /* min_power corresponds to the idle power (cpu load = 0) */
+ /* min_power corresponds to the power consumed when only one core is active */
/* max_power is the power consumed at 100% cpu load */
auto range = power_range_watts_list.at(host->pstate());
double current_power = 0;
if (all_power_values_str == nullptr)
return;
- xbt_dynar_t all_power_values = xbt_str_split(all_power_values_str, ",");
- int pstate_nb = xbt_dynar_length(all_power_values);
+ std::vector<std::string> all_power_values;
+ boost::split(all_power_values, all_power_values_str, boost::is_any_of(","));
- for (int i = 0; i < pstate_nb; i++) {
+ int i = 0;
+ for (auto current_power_values_str : all_power_values) {
/* retrieve the power values associated with the current pstate */
- xbt_dynar_t current_power_values = xbt_str_split(xbt_dynar_get_as(all_power_values, i, char*), ":");
- xbt_assert(xbt_dynar_length(current_power_values) == 3,
- "Power properties incorrectly defined - could not retrieve idle, min and max power values for host %s",
+ std::vector<std::string> current_power_values;
+ boost::split(current_power_values, current_power_values_str, boost::is_any_of(":"));
+ xbt_assert(current_power_values.size() == 3, "Power properties incorrectly defined - "
+ "could not retrieve idle, min and max power values for host %s",
host->cname());
/* min_power corresponds to the idle power (cpu load = 0) */
char* msg_idle = bprintf("Invalid idle value for pstate %d on host %s: %%s", i, host->cname());
char* msg_min = bprintf("Invalid min value for pstate %d on host %s: %%s", i, host->cname());
char* msg_max = bprintf("Invalid max value for pstate %d on host %s: %%s", i, host->cname());
- PowerRange range(xbt_str_parse_double(xbt_dynar_get_as(current_power_values, 0, char*), msg_idle),
- xbt_str_parse_double(xbt_dynar_get_as(current_power_values, 1, char*), msg_min),
- xbt_str_parse_double(xbt_dynar_get_as(current_power_values, 2, char*), msg_max));
+ PowerRange range(xbt_str_parse_double((current_power_values.at(0)).c_str(), msg_idle),
+ xbt_str_parse_double((current_power_values.at(1)).c_str(), msg_min),
+ xbt_str_parse_double((current_power_values.at(2)).c_str(), msg_max));
power_range_watts_list.push_back(range);
xbt_free(msg_idle);
xbt_free(msg_min);
xbt_free(msg_max);
-
- xbt_dynar_free(¤t_power_values);
+ i++;
}
- xbt_dynar_free(&all_power_values);
}
}
}
HostEnergy* host_energy = host.extension<HostEnergy>();
host_energy->update();
- XBT_INFO("Total energy of host %s: %f Joules", host.cname(), host_energy->getConsumedEnergy());
+ XBT_INFO("Energy consumption of host %s: %f Joules", host.cname(), host_energy->getConsumedEnergy());
+}
+
+static void onSimulationEnd()
+{
+ sg_host_t* host_list = sg_host_list();
+ int host_count = sg_host_count();
+ double total_energy = 0.0; // Total energy consumption (whole platform)
+ double used_hosts_energy = 0.0; // Energy consumed by hosts that computed something
+ for (int i = 0; i < host_count; i++) {
+ if (dynamic_cast<simgrid::s4u::VirtualMachine*>(host_list[i]) == nullptr) { // Ignore virtual machines
+
+ bool host_was_used = (host_list[i]->extension<HostEnergy>()->last_updated != 0);
+ double energy = host_list[i]->extension<HostEnergy>()->getConsumedEnergy();
+ total_energy += energy;
+ if (host_was_used)
+ used_hosts_energy += energy;
+ }
+ }
+ XBT_INFO("Total energy consumption: %f Joules (used hosts: %f Joules; unused/idle hosts: %f)",
+ total_energy, used_hosts_energy, total_energy - used_hosts_energy);
+ xbt_free(host_list);
}
/* **************************** Public interface *************************** */
simgrid::s4u::Host::onStateChange.connect(&onHostChange);
simgrid::s4u::Host::onSpeedChange.connect(&onHostChange);
simgrid::s4u::Host::onDestruction.connect(&onHostDestruction);
+ simgrid::s4u::onSimulationEnd.connect(&onSimulationEnd);
simgrid::surf::CpuAction::onStateChange.connect(&onActionStateChange);
}