X-Git-Url: http://info.iut-bm.univ-fcomte.fr/pub/gitweb/simgrid.git/blobdiff_plain/f53de8e7017c7b01248f73cd38ac1d88bee5cc67..3b68ec95a7648e14307f1d31699c14532cfd86ee:/src/surf/plugins/host_energy.cpp

diff --git a/src/surf/plugins/host_energy.cpp b/src/surf/plugins/host_energy.cpp
index a604f3c4a8..97befbd3c6 100644
--- a/src/surf/plugins/host_energy.cpp
+++ b/src/surf/plugins/host_energy.cpp
@@ -1,4 +1,4 @@
-/* Copyright (c) 2010, 2012-2016. The SimGrid Team. All rights reserved.    */
+/* Copyright (c) 2010-2017. The SimGrid Team. All rights reserved.          */
 
 /* This program is free software; you can redistribute it and/or modify it
  * under the terms of the license (GNU LGPL) which comes with this package. */
@@ -8,54 +8,103 @@
 #include "src/plugins/vm/VirtualMachineImpl.hpp"
 #include "src/surf/cpu_interface.hpp"
 
+#include "simgrid/s4u/Engine.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
+/** @addtogroup plugin_energy
+
+This is the energy plugin, enabling to account not only for computation time, but also for the dissipated energy in the
+simulated platform.
+To activate this plugin, first call sg_host_energy_plugin_init() before your #MSG_init(), and then use
+MSG_host_get_consumed_energy() to retrieve the consumption of a given host.
+
+When the host is on, this energy consumption naturally depends on both the current CPU load and the host energy profile.
+According to our measurements, the consumption is somehow linear in the amount of cores at full speed, with an
+abnormality when all the cores are idle. The full details are in
+<a href="https://hal.inria.fr/hal-01523608">our scientific paper</a> on that topic.
 
+As a result, our energy model takes 4 parameters:
 
-This is the energy plugin, enabling to account not only for computation time,
-but also for the dissipated energy in the simulated platform.
+  - \b Idle: instantaneous consumption (in Watt) when your host is up and running, but without anything to do.
+  - \b OneCore: instantaneous consumption (in Watt) when only one core is active, at 100%.
+  - \b AllCores: instantaneous consumption (in Watt) when all cores of the host are at 100%.
+  - \b Off: instantaneous consumption (in Watt) when the host is turned off.
 
-The energy consumption of a CPU depends directly of its current load. Specify that consumption in your platform file as
-follows:
+Here is an example of XML declaration:
 
-\verbatim
-<host id="HostA" power="100.0Mf" cores="8">
+\code{.xml}
+<host id="HostA" power="100.0Mf" cores="4">
     <prop id="watt_per_state" value="100.0:120.0:200.0" />
     <prop id="watt_off" value="10" />
 </host>
-\endverbatim
+\endcode
+
+This example gives the following parameters: \b Off is 10 Watts; \b Idle is 100 Watts; \b OneCore is 120 Watts and \b
+AllCores is 200 Watts.
+This is enough to compute the consumption as a function of the amount of loaded cores:
+
+<table>
+<tr><th>#Cores loaded</th><th>Consumption</th><th>Explanation</th></tr>
+<tr><td>0</td><td> 100 Watts</td><td>Idle value</td></tr>
+<tr><td>1</td><td> 120 Watts</td><td>OneCore value</td></tr>
+<tr><td>2</td><td> 147 Watts</td><td>linear extrapolation between OneCore and AllCores</td></tr>
+<tr><td>3</td><td> 173 Watts</td><td>linear extrapolation between OneCore and AllCores</td></tr>
+<tr><td>4</td><td> 200 Watts</td><td>AllCores value</td></tr>
+</table>
+
+### What if a given core is only at load 50%?
+
+This is impossible in SimGrid because we recompute everything each time that the CPU starts or stops doing something.
+So if a core is at load 50% over a period, it means that it is at load 100% half of the time and at load 0% the rest of
+the time, and our model holds.
+
+### What if the host has only one core?
+
+In this case, the parameters \b OneCore and \b AllCores are obviously the same.
+Actually, SimGrid expect an energetic profile formatted as 'Idle:Running' for mono-cores hosts.
+If you insist on passing 3 parameters in this case, then you must have the same value for \b OneCore and \b AllCores.
+
+\code{.xml}
+<host id="HostC" power="100.0Mf" cores="1">
+    <prop id="watt_per_state" value="95.0:200.0" /> <!-- we may have used '95:200:200' instead -->
+    <prop id="watt_off" value="10" />
+</host>
+\endcode
 
-The first property means that when your host is up and running, but without anything to do, it will dissipate 100 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).
+### How does DVFS interact with the host energy model?
 
-If your CPU is using pstates, then you can provide one consumption interval per pstate.
+If your host has several DVFS levels (several pstates), then you should give the energetic profile of each pstate level:
 
-\verbatim
-<host id="HostB" power="100.0Mf,50.0Mf,20.0Mf" pstate="0" >
+\code{.xml}
+<host id="HostC" power="100.0Mf,50.0Mf,20.0Mf" cores="4">
     <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
+\endcode
 
-That host has 3 levels of performance with the following performance: 100 Mflop/s, 50 Mflop/s or 20 Mflop/s.
-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. If only one core is active, this machine consumes 120 / 115 / 110 watts.
+This encodes the following values
+<table>
+<tr><th>pstate</th><th>Performance</th><th>Idle</th><th>OneCore</th><th>AllCores</th></tr>
+<tr><td>0</td><td>100 Mflop/s</td><td>95 Watts</td><td>120 Watts</td><td>200 Watts</td></tr>
+<tr><td>1</td><td>50 Mflop/s</td><td>93 Watts</td><td>115 Watts</td><td>170 Watts</td></tr>
+<tr><td>2</td><td>20 Mflop/s</td><td>90 Watts</td><td>110 Watts</td><td>150 Watts</td></tr>
+</table>
 
 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().
 
-To simulate the energy-related elements, first call the simgrid#energy#sg_energy_plugin_init() before your #MSG_init(),
-and then use the following function to retrieve the consumption of a given host: MSG_host_get_consumed_energy().
+### How accurate are these models?
+
+This model cannot be more accurate than your instantiation: with the default values, your result will not be accurate at
+all. You can still get accurate energy prediction, provided that you carefully instantiate the model.
+The first step is to ensure that your timing prediction match perfectly. But this is only the first step of the path,
+and you really want to read <a href="https://hal.inria.fr/hal-01523608">this paper</a> to see all what you need to do
+before you can get accurate energy predictions.
  */
 
 XBT_LOG_NEW_DEFAULT_SUBCATEGORY(surf_energy, surf, "Logging specific to the SURF energy plugin");
@@ -91,11 +140,11 @@ private:
   std::vector<PowerRange>
       power_range_watts_list; /*< List of (min_power,max_power) pairs corresponding to each cpu pstate */
 
-  /* We need to keep track of what pstate has been used, as we will sometimes
-   * be notified only *after* a pstate has been used (but we need to update the energy consumption
-   * with the old pstate!)
+  /* We need to keep track of what pstate has been used, as we will sometimes be notified only *after* a pstate has been
+   * used (but we need to update the energy consumption with the old pstate!)
    */
   int pstate = 0;
+  const int pstate_off = -1;
 
 public:
   double watts_off    = 0.0; /*< Consumption when the machine is turned off (shutdown) */
@@ -105,61 +154,79 @@ public:
 
 simgrid::xbt::Extension<simgrid::s4u::Host, HostEnergy> HostEnergy::EXTENSION_ID;
 
-/* Computes the consumption so far.  Called lazily on need. */
+/* Computes the consumption so far. Called lazily on need. */
 void HostEnergy::update()
 {
   double start_time  = this->last_updated;
   double finish_time = surf_get_clock();
-  double cpu_load;
-  double current_speed = host->pimpl_cpu->getPstateSpeedCurrent();
-  if (current_speed <= 0)
-    // Some users declare a pstate of speed 0 flops (e.g., to model boot time).
-    // We consider that the machine is then fully loaded. That's arbitrary but it avoids a NaN
-    cpu_load = 1;
-  else
-    cpu_load = lmm_constraint_get_usage(host->pimpl_cpu->constraint()) / current_speed;
-
-  /** Divide by the number of cores here **/
-  cpu_load /= host->pimpl_cpu->coreCount();
-
-  if (cpu_load > 1) // A machine with a load > 1 consumes as much as a fully loaded machine, not more
-    cpu_load = 1;
-
-  /* The problem with this model is that the load is always 0 or 1, never something less.
-   * Another possibility could be to model the total energy as
-   *
-   *   X/(X+Y)*W_idle + Y/(X+Y)*W_burn
-   *
-   * where X is the amount of idling cores, and Y the amount of computing cores.
-   */
+  double current_speed = host->getSpeed();
+
+  if (start_time < finish_time) {
+    double cpu_load;
+    // We may have start == finish if the past consumption was updated since the simcall was started
+    // for example if 2 actors requested to update the same host's consumption in a given scheduling round.
+    //
+    // Even in this case, we need to save the pstate for the next call (after this big if),
+    // which may have changed since that recent update.
+
+    if (current_speed <= 0)
+      // Some users declare a pstate of speed 0 flops (e.g., to model boot time).
+      // We consider that the machine is then fully loaded. That's arbitrary but it avoids a NaN
+      cpu_load = 1;
+    else
+      cpu_load = lmm_constraint_get_usage(host->pimpl_cpu->constraint()) / current_speed;
+
+    /** Divide by the number of cores here **/
+    cpu_load /= host->pimpl_cpu->coreCount();
+
+    if (cpu_load > 1) // A machine with a load > 1 consumes as much as a fully loaded machine, not more
+      cpu_load = 1;
+
+    /* The problem with this model is that the load is always 0 or 1, never something less.
+     * Another possibility could be to model the total energy as
+     *
+     *   X/(X+Y)*W_idle + Y/(X+Y)*W_burn
+     *
+     * where X is the amount of idling cores, and Y the amount of computing cores.
+     */
+
+    double previous_energy = this->total_energy;
 
-  double previous_energy = this->total_energy;
+    double instantaneous_consumption;
+    if (this->pstate == pstate_off) // The host was off at the beginning of this time interval
+      instantaneous_consumption = this->watts_off;
+    else
+      instantaneous_consumption = this->getCurrentWattsValue(cpu_load);
+
+    double energy_this_step = instantaneous_consumption * (finish_time - start_time);
+
+    // TODO Trace: Trace energy_this_step from start_time to finish_time in host->name()
 
-  double instantaneous_consumption;
-  if (host->isOff())
-    instantaneous_consumption = this->watts_off;
-  else
-    instantaneous_consumption = this->getCurrentWattsValue(cpu_load);
+    this->total_energy = previous_energy + energy_this_step;
+    this->last_updated = finish_time;
 
-  double energy_this_step = instantaneous_consumption * (finish_time - start_time);
+    XBT_DEBUG("[update_energy of %s] period=[%.2f-%.2f]; current power peak=%.0E flop/s; consumption change: %.2f J -> "
+              "%.2f J",
+              host->getCname(), start_time, finish_time, host->pimpl_cpu->speed_.peak, previous_energy,
+              energy_this_step);
+  }
 
-  this->total_energy = previous_energy + energy_this_step;
-  this->last_updated = finish_time;
-  this->pstate       = host->pstate();
-  XBT_DEBUG(
-      "[update_energy of %s] period=[%.2f-%.2f]; current power peak=%.0E flop/s; consumption change: %.2f J -> %.2f J",
-      host->cname(), start_time, finish_time, host->pimpl_cpu->speed_.peak, previous_energy, energy_this_step);
+  /* Save data for the upcoming time interval: whether it's on/off and the pstate if it's on */
+  this->pstate = host->isOn() ? host->getPstate() : pstate_off;
 }
 
 HostEnergy::HostEnergy(simgrid::s4u::Host* ptr) : host(ptr), last_updated(surf_get_clock())
 {
   initWattsRangeList();
 
-  const char* off_power_str = host->property("watt_off");
+  const char* off_power_str = host->getProperty("watt_off");
   if (off_power_str != nullptr) {
-    char* msg       = bprintf("Invalid value for property watt_off of host %s: %%s", host->cname());
-    this->watts_off = xbt_str_parse_double(off_power_str, msg);
-    xbt_free(msg);
+    try {
+      this->watts_off = std::stod(std::string(off_power_str));
+    } catch (std::invalid_argument& ia) {
+      throw std::invalid_argument(std::string("Invalid value for property watt_off of host ") + host->getCname() +
+                                  ": " + off_power_str);
+    }
   }
   /* watts_off is 0 by default */
 }
@@ -168,20 +235,20 @@ HostEnergy::~HostEnergy() = default;
 
 double HostEnergy::getWattMinAt(int pstate)
 {
-  xbt_assert(!power_range_watts_list.empty(), "No power range properties specified for host %s", host->cname());
+  xbt_assert(not power_range_watts_list.empty(), "No power range properties specified for host %s", host->getCname());
   return power_range_watts_list[pstate].min;
 }
 
 double HostEnergy::getWattMaxAt(int pstate)
 {
-  xbt_assert(!power_range_watts_list.empty(), "No power range properties specified for host %s", host->cname());
+  xbt_assert(not power_range_watts_list.empty(), "No power range properties specified for host %s", host->getCname());
   return power_range_watts_list[pstate].max;
 }
 
 /** @brief Computes the power consumed by the host according to the current pstate and processor load */
 double HostEnergy::getCurrentWattsValue(double cpu_load)
 {
-  xbt_assert(!power_range_watts_list.empty(), "No power range properties specified for host %s", host->cname());
+  xbt_assert(not power_range_watts_list.empty(), "No power range properties specified for host %s", host->getCname());
 
   /* min_power corresponds to the power consumed when only one core is active */
   /* max_power is the power consumed at 100% cpu load       */
@@ -206,7 +273,7 @@ double HostEnergy::getCurrentWattsValue(double cpu_load)
      * (maxCpuLoad is by definition 1)
      */
     double power_slope;
-    int coreCount         = host->coreCount();
+    int coreCount         = host->getCoreCount();
     double coreReciprocal = static_cast<double>(1) / static_cast<double>(coreCount);
     if (coreCount > 1)
       power_slope = (max_power - min_power) / (1 - coreReciprocal);
@@ -234,27 +301,47 @@ double HostEnergy::getConsumedEnergy()
 
 void HostEnergy::initWattsRangeList()
 {
-  const char* all_power_values_str = host->property("watt_per_state");
+  const char* all_power_values_str = host->getProperty("watt_per_state");
   if (all_power_values_str == nullptr)
     return;
 
   std::vector<std::string> all_power_values;
   boost::split(all_power_values, all_power_values_str, boost::is_any_of(","));
+  XBT_DEBUG("%s: profile: %s, cores: %d", host->getCname(), all_power_values_str, host->getCoreCount());
 
   int i = 0;
   for (auto current_power_values_str : all_power_values) {
     /* retrieve the power values associated with the current pstate */
     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());
+    if (host->getCoreCount() == 1) {
+      xbt_assert(current_power_values.size() == 2 || current_power_values.size() == 3,
+                 "Power properties incorrectly defined for host %s."
+                 "It should be 'Idle:FullSpeed' power values because you have one core only.",
+                 host->getCname());
+      if (current_power_values.size() == 2) {
+        // In this case, 1core == AllCores
+        current_power_values.push_back(current_power_values.at(1));
+      } else { // size == 3
+        xbt_assert((current_power_values.at(1)) == (current_power_values.at(2)),
+                   "Power properties incorrectly defined for host %s.\n"
+                   "The energy profile of mono-cores should be formatted as 'Idle:FullSpeed' only.\n"
+                   "If you go for a 'Idle:OneCore:AllCores' power profile on mono-cores, then OneCore and AllCores "
+                   "must be equal.",
+                   host->getCname());
+      }
+    } else {
+      xbt_assert(current_power_values.size() == 3,
+                 "Power properties incorrectly defined for host %s."
+                 "It should be 'Idle:OneCore:AllCores' power values because you have more than one core.",
+                 host->getCname());
+    }
 
     /* min_power corresponds to the idle power (cpu load = 0) */
     /* max_power is the power consumed at 100% cpu load       */
-    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());
+    char* msg_idle = bprintf("Invalid idle value for pstate %d on host %s: %%s", i, host->getCname());
+    char* msg_min  = bprintf("Invalid OneCore value for pstate %d on host %s: %%s", i, host->getCname());
+    char* msg_max  = bprintf("Invalid AllCores value for pstate %d on host %s: %%s", i, host->getCname());
     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));
@@ -275,6 +362,9 @@ static void onCreation(simgrid::s4u::Host& host)
 {
   if (dynamic_cast<simgrid::s4u::VirtualMachine*>(&host)) // Ignore virtual machines
     return;
+
+  //TODO Trace: set to zero the energy variable associated to host->name()
+
   host.extension_set(new HostEnergy(&host));
 }
 
@@ -282,19 +372,19 @@ static void onActionStateChange(simgrid::surf::CpuAction* action, simgrid::surf:
 {
   for (simgrid::surf::Cpu* cpu : action->cpus()) {
     simgrid::s4u::Host* host = cpu->getHost();
-    if (host == nullptr)
-      continue;
+    if (host != nullptr) {
 
-    // If it's a VM, take the corresponding PM
-    simgrid::s4u::VirtualMachine* vm = dynamic_cast<simgrid::s4u::VirtualMachine*>(host);
-    if (vm) // If it's a VM, take the corresponding PM
-      host = vm->pimpl_vm_->getPm();
+      // If it's a VM, take the corresponding PM
+      simgrid::s4u::VirtualMachine* vm = dynamic_cast<simgrid::s4u::VirtualMachine*>(host);
+      if (vm) // If it's a VM, take the corresponding PM
+        host = vm->pimpl_vm_->getPm();
 
-    // Get the host_energy extension for the relevant host
-    HostEnergy* host_energy = host->extension<HostEnergy>();
+      // Get the host_energy extension for the relevant host
+      HostEnergy* host_energy = host->extension<HostEnergy>();
 
-    if (host_energy->last_updated < surf_get_clock())
-      host_energy->update();
+      if (host_energy->last_updated < surf_get_clock())
+        host_energy->update();
+    }
   }
 }
 
@@ -317,7 +407,7 @@ static void onHostDestruction(simgrid::s4u::Host& host)
 
   HostEnergy* host_energy = host.extension<HostEnergy>();
   host_energy->update();
-  XBT_INFO("Energy consumption of host %s: %f Joules", host.cname(), host_energy->getConsumedEnergy());
+  XBT_INFO("Energy consumption of host %s: %f Joules", host.getCname(), host_energy->getConsumedEnergy());
 }
 
 static void onSimulationEnd()
@@ -344,7 +434,7 @@ static void onSimulationEnd()
 /* **************************** Public interface *************************** */
 SG_BEGIN_DECL()
 
-/** \ingroup SURF_plugin_energy
+/** \ingroup plugin_energy
  * \brief Enable host energy plugin
  * \details Enable energy plugin to get joules consumption of each cpu. Call this function before #MSG_init().
  */
@@ -363,9 +453,29 @@ void sg_host_energy_plugin_init()
   simgrid::surf::CpuAction::onStateChange.connect(&onActionStateChange);
 }
 
-/** @brief Returns the total energy consumed by the host so far (in Joules)
+/** @ingroup plugin_energy
+ *  @brief updates the consumption of all hosts
+ *
+ * After this call, sg_host_get_consumed_energy() will not interrupt your process
+ * (until after the next clock update).
+ */
+void sg_host_energy_update_all()
+{
+  simgrid::simix::kernelImmediate([]() {
+    std::vector<simgrid::s4u::Host*> list;
+    simgrid::s4u::Engine::getInstance()->getHostList(&list);
+    for (auto host : list)
+      if (dynamic_cast<simgrid::s4u::VirtualMachine*>(host) == nullptr) // Ignore virtual machines
+        host->extension<HostEnergy>()->update();
+  });
+}
+
+/** @ingroup plugin_energy
+ *  @brief Returns the total energy consumed by the host so far (in Joules)
  *
- *  See also @ref SURF_plugin_energy.
+ *  Please note that since the consumption is lazily updated, it may require a simcall to update it.
+ *  The result is that the actor requesting this value will be interrupted,
+ *  the value will be updated in kernel mode before returning the control to the requesting actor.
  */
 double sg_host_get_consumed_energy(sg_host_t host)
 {
@@ -374,14 +484,18 @@ double sg_host_get_consumed_energy(sg_host_t host)
   return host->extension<HostEnergy>()->getConsumedEnergy();
 }
 
-/** @brief Get the amount of watt dissipated at the given pstate when the host is idling */
+/** @ingroup plugin_energy
+ *  @brief Get the amount of watt dissipated at the given pstate when the host is idling
+ */
 double sg_host_get_wattmin_at(sg_host_t host, int pstate)
 {
   xbt_assert(HostEnergy::EXTENSION_ID.valid(),
              "The Energy plugin is not active. Please call sg_energy_plugin_init() during initialization.");
   return host->extension<HostEnergy>()->getWattMinAt(pstate);
 }
-/** @brief  Returns the amount of watt dissipated at the given pstate when the host burns CPU at 100% */
+/** @ingroup plugin_energy
+ *  @brief  Returns the amount of watt dissipated at the given pstate when the host burns CPU at 100%
+ */
 double sg_host_get_wattmax_at(sg_host_t host, int pstate)
 {
   xbt_assert(HostEnergy::EXTENSION_ID.valid(),
@@ -389,4 +503,15 @@ double sg_host_get_wattmax_at(sg_host_t host, int pstate)
   return host->extension<HostEnergy>()->getWattMaxAt(pstate);
 }
 
+/** @ingroup plugin_energy
+ *  @brief Returns the current consumption of the host
+ */
+double sg_host_get_current_consumption(sg_host_t host)
+{
+  xbt_assert(HostEnergy::EXTENSION_ID.valid(),
+             "The Energy plugin is not active. Please call sg_energy_plugin_init() during initialization.");
+  double cpu_load = lmm_constraint_get_usage(host->pimpl_cpu->constraint()) / host->getSpeed();
+  return host->extension<HostEnergy>()->getCurrentWattsValue(cpu_load);
+}
+
 SG_END_DECL()