[simgrid.git] / src / surf / surf_interface.cpp

/* Copyright (c) 2004-2018. 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. */

#include "surf_interface.hpp"
#include "mc/mc.h"
#include "simgrid/s4u/Engine.hpp"
#include "simgrid/sg_config.h"
#include "src/instr/instr_private.hpp" // TRACE_is_enabled(). FIXME: remove by subscribing tracing to the surf signals
#include "src/kernel/lmm/maxmin.hpp"   // Constraint
#include "src/kernel/routing/NetPoint.hpp"
#include "src/surf/HostImpl.hpp"
#include "xbt/utility.hpp"

#include <fstream>
#include <set>
#include <string>
#include <vector>

#ifdef _WIN32
#include <windows.h>
#endif

XBT_LOG_NEW_CATEGORY(surf, "All SURF categories");
XBT_LOG_NEW_DEFAULT_SUBCATEGORY(surf_kernel, surf, "Logging specific to SURF (kernel)");

/*********
 * Utils *
 *********/

std::vector<surf_model_t> * all_existing_models = nullptr; /* to destroy models correctly */

simgrid::trace_mgr::future_evt_set *future_evt_set = nullptr;
std::vector<std::string> surf_path;
std::vector<simgrid::s4u::Host*> host_that_restart;
/**  set of hosts for which one want to be notified if they ever restart. */
std::set<std::string> watched_hosts;
extern std::map<std::string, simgrid::surf::StorageType*> storage_types;

namespace simgrid {
namespace surf {

simgrid::xbt::signal<void()> surfExitCallbacks;
}
}

#include <simgrid/plugins/energy.h> // FIXME: this plug-in should not be linked to the core
#include <simgrid/plugins/load.h>   // FIXME: this plug-in should not be linked to the core

s_surf_model_description_t surf_plugin_description[] = {
    {"Energy", "Cpu energy consumption.", &sg_host_energy_plugin_init},
    {"Load", "Cpu load.", &sg_host_load_plugin_init},
    {nullptr, nullptr, nullptr} /* this array must be nullptr terminated */
};

/* Don't forget to update the option description in smx_config when you change this */
s_surf_model_description_t surf_network_model_description[] = {
    {"LV08", "Realistic network analytic model (slow-start modeled by multiplying latency by 13.01, bandwidth by .97; "
             "bottleneck sharing uses a payload of S=20537 for evaluating RTT). ",
     &surf_network_model_init_LegrandVelho},
    {"Constant", "Simplistic network model where all communication take a constant time (one second). This model "
                 "provides the lowest realism, but is (marginally) faster.",
     &surf_network_model_init_Constant},
    {"SMPI", "Realistic network model specifically tailored for HPC settings (accurate modeling of slow start with "
             "correction factors on three intervals: < 1KiB, < 64 KiB, >= 64 KiB)",
     &surf_network_model_init_SMPI},
    {"IB", "Realistic network model specifically tailored for HPC settings, with Infiniband contention model",
     &surf_network_model_init_IB},
    {"CM02", "Legacy network analytic model (Very similar to LV08, but without corrective factors. The timings of "
             "small messages are thus poorly modeled).",
     &surf_network_model_init_CM02},
    {"NS3", "Network pseudo-model using the NS3 tcp model instead of an analytic model", &surf_network_model_init_NS3},
    {"Reno",
     "Model from Steven H. Low using lagrange_solve instead of lmm_solve (experts only; check the code for more info).",
     &surf_network_model_init_Reno},
    {"Reno2",
     "Model from Steven H. Low using lagrange_solve instead of lmm_solve (experts only; check the code for more info).",
     &surf_network_model_init_Reno2},
    {"Vegas",
     "Model from Steven H. Low using lagrange_solve instead of lmm_solve (experts only; check the code for more info).",
     &surf_network_model_init_Vegas},
    {nullptr, nullptr, nullptr} /* this array must be nullptr terminated */
};

#if ! HAVE_SMPI
void surf_network_model_init_SMPI() {
  xbt_die("Please activate SMPI support in cmake to use the SMPI network model.");
}
void surf_network_model_init_IB() {
  xbt_die("Please activate SMPI support in cmake to use the IB network model.");
}
#endif
#if !SIMGRID_HAVE_NS3
void surf_network_model_init_NS3() {
  xbt_die("Please activate NS3 support in cmake and install the dependencies to use the NS3 network model.");
}
#endif

s_surf_model_description_t surf_cpu_model_description[] = {
  {"Cas01", "Simplistic CPU model (time=size/power).", &surf_cpu_model_init_Cas01},
  {nullptr, nullptr,  nullptr}      /* this array must be nullptr terminated */
};

s_surf_model_description_t surf_host_model_description[] = {
  {"default",   "Default host model. Currently, CPU:Cas01 and network:LV08 (with cross traffic enabled)", &surf_host_model_init_current_default},
  {"compound",  "Host model that is automatically chosen if you change the network and CPU models", &surf_host_model_init_compound},
  {"ptask_L07", "Host model somehow similar to Cas01+CM02 but allowing parallel tasks", &surf_host_model_init_ptask_L07},
  {nullptr, nullptr, nullptr}      /* this array must be nullptr terminated */
};

s_surf_model_description_t surf_optimization_mode_description[] = {
  {"Lazy", "Lazy action management (partial invalidation in lmm + heap in action remaining).", nullptr},
  {"TI",   "Trace integration. Highly optimized mode when using availability traces (only available for the Cas01 CPU model for now).", nullptr},
  {"Full", "Full update of remaining and variables. Slow but may be useful when debugging.", nullptr},
  {nullptr, nullptr, nullptr}      /* this array must be nullptr terminated */
};

s_surf_model_description_t surf_storage_model_description[] = {
  {"default", "Simplistic storage model.", &surf_storage_model_init_default},
  {nullptr, nullptr,  nullptr}      /* this array must be nullptr terminated */
};

double NOW = 0;

double surf_get_clock()
{
  return NOW;
}

#ifdef _WIN32
# define FILE_DELIM "\\"
#else
# define FILE_DELIM "/"         /* FIXME: move to better location */
#endif

std::ifstream* surf_ifsopen(std::string name)
{
  std::ifstream* fs = new std::ifstream();
  xbt_assert(not name.empty());
  if (__surf_is_absolute_file_path(name.c_str())) { /* don't mess with absolute file names */
    fs->open(name.c_str(), std::ifstream::in);
  }

  /* search relative files in the path */
  for (auto const& path_elm : surf_path) {
    std::string buff = path_elm + FILE_DELIM + name;
    fs->open(buff.c_str(), std::ifstream::in);

    if (not fs->fail()) {
      XBT_DEBUG("Found file at %s", buff.c_str());
      return fs;
    }
  }

  return fs;
}

FILE *surf_fopen(const char *name, const char *mode)
{
  FILE *file = nullptr;

  xbt_assert(name);

  if (__surf_is_absolute_file_path(name))       /* don't mess with absolute file names */
    return fopen(name, mode);

  /* search relative files in the path */
  for (auto const& path_elm : surf_path) {
    std::string buff = path_elm + FILE_DELIM + name;
    file             = fopen(buff.c_str(), mode);

    if (file)
      return file;
  }
  return nullptr;
}

/* The __surf_is_absolute_file_path() returns 1 if
 * file_path is a absolute file path, in the other
 * case the function returns 0.
 */
int __surf_is_absolute_file_path(const char *file_path)
{
#ifdef _WIN32
  WIN32_FIND_DATA wfd = { 0 };
  HANDLE hFile = FindFirstFile(file_path, &wfd);

  if (INVALID_HANDLE_VALUE == hFile)
    return 0;

  FindClose(hFile);
  return 1;
#else
  return (file_path[0] == '/');
#endif
}

/** Displays the long description of all registered models, and quit */
void model_help(const char *category, s_surf_model_description_t * table)
{
  printf("Long description of the %s models accepted by this simulator:\n", category);
  for (int i = 0; table[i].name; i++)
    printf("  %s: %s\n", table[i].name, table[i].description);
}

int find_model_description(s_surf_model_description_t* table, std::string name)
{
  for (int i = 0; table[i].name; i++)
    if (name == table[i].name)
      return i;

  if (not table[0].name)
    xbt_die("No model is valid! This is a bug.");

  std::string name_list = std::string(table[0].name);
  for (int i = 1; table[i].name; i++)
    name_list = name_list + ", " + table[i].name;

  xbt_die("Model '%s' is invalid! Valid models are: %s.", name.c_str(), name_list.c_str());
  return -1;
}

void sg_version_check(int lib_version_major, int lib_version_minor, int lib_version_patch)
{
  if ((lib_version_major != SIMGRID_VERSION_MAJOR) || (lib_version_minor != SIMGRID_VERSION_MINOR)) {
    fprintf(stderr, "FATAL ERROR: Your program was compiled with SimGrid version %d.%d.%d, "
                    "and then linked against SimGrid %d.%d.%d. Please fix this.\n",
            lib_version_major, lib_version_minor, lib_version_patch, SIMGRID_VERSION_MAJOR, SIMGRID_VERSION_MINOR,
            SIMGRID_VERSION_PATCH);
    abort();
  }
  if (lib_version_patch != SIMGRID_VERSION_PATCH) {
    if (SIMGRID_VERSION_PATCH >= 90 || lib_version_patch >= 90) {
      fprintf(
          stderr,
          "FATAL ERROR: Your program was compiled with SimGrid version %d.%d.%d, "
          "and then linked against SimGrid %d.%d.%d. \n"
          "One of them is a development version, and should not be mixed with the stable release. Please fix this.\n",
          lib_version_major, lib_version_minor, lib_version_patch, SIMGRID_VERSION_MAJOR, SIMGRID_VERSION_MINOR,
          SIMGRID_VERSION_PATCH);
      abort();
    }
    fprintf(stderr, "Warning: Your program was compiled with SimGrid version %d.%d.%d, "
                    "and then linked against SimGrid %d.%d.%d. Proceeding anyway.\n",
            lib_version_major, lib_version_minor, lib_version_patch, SIMGRID_VERSION_MAJOR, SIMGRID_VERSION_MINOR,
            SIMGRID_VERSION_PATCH);
  }
}

void sg_version_get(int* ver_major, int* ver_minor, int* ver_patch)
{
  *ver_major = SIMGRID_VERSION_MAJOR;
  *ver_minor = SIMGRID_VERSION_MINOR;
  *ver_patch = SIMGRID_VERSION_PATCH;
}

void sg_version()
{
  std::printf("This program was linked against %s (git: %s), found in %s.\n",
              SIMGRID_VERSION_STRING, SIMGRID_GIT_VERSION, SIMGRID_INSTALL_PREFIX);

#if SIMGRID_HAVE_MC
  std::printf("   Model-checking support compiled in.\n");
#else
  std::printf("   Model-checking support disabled at compilation.\n");
#endif

#if SIMGRID_HAVE_NS3
  std::printf("   NS3 support compiled in.\n");
#else
  std::printf("   NS3 support disabled at compilation.\n");
#endif

#if SIMGRID_HAVE_JEDULE
  std::printf("   Jedule support compiled in.\n");
#else
  std::printf("   Jedule support disabled at compilation.\n");
#endif

#if SIMGRID_HAVE_LUA
  std::printf("   Lua support compiled in.\n");
#else
  std::printf("   Lua support disabled at compilation.\n");
#endif

#if SIMGRID_HAVE_MALLOCATOR
  std::printf("   Mallocator support compiled in.\n");
#else
  std::printf("   Mallocator support disabled at compilation.\n");
#endif

  std::printf("\nTo cite SimGrid in a publication, please use:\n"
              "   Henri Casanova, Arnaud Giersch, Arnaud Legrand, Martin Quinson, Frédéric Suter. \n"
              "   Versatile, Scalable, and Accurate Simulation of Distributed Applications and Platforms. \n"
              "   Journal of Parallel and Distributed Computing, Elsevier, 2014, 74 (10), pp.2899-2917.\n");
  std::printf("The pdf file and a BibTeX entry for LaTeX users can be found at http://hal.inria.fr/hal-01017319\n");
}

void surf_init(int *argc, char **argv)
{
  if (USER_HOST_LEVEL != -1) // Already initialized
    return;

  XBT_DEBUG("Create all Libs");
  USER_HOST_LEVEL = simgrid::s4u::Host::extension_create(nullptr);

  xbt_init(argc, argv);
  if (not all_existing_models)
    all_existing_models = new std::vector<simgrid::surf::Model*>();
  if (not future_evt_set)
    future_evt_set = new simgrid::trace_mgr::future_evt_set();

  sg_config_init(argc, argv);

  if (MC_is_active())
    MC_memory_init();
}

void surf_exit()
{
  TRACE_end();                  /* Just in case it was not called by the upper layer (or there is no upper layer) */

  simgrid::s4u::Engine::shutdown();
  sg_link_exit();
  for (auto const& e : storage_types) {
    simgrid::surf::StorageType* stype = e.second;
    delete stype->properties;
    delete stype->model_properties;
    delete stype;
  }
  for (auto const& s : *simgrid::surf::StorageImpl::storagesMap())
    delete s.second;
  delete simgrid::surf::StorageImpl::storagesMap();

  for (auto const& model : *all_existing_models)
    delete model;
  delete all_existing_models;


  if (future_evt_set) {
    delete future_evt_set;
    future_evt_set = nullptr;
  }

  tmgr_finalize();
  sg_platf_exit();

  NOW = 0;                      /* Just in case the user plans to restart the simulation afterward */
}

/*********
 * Model *
 *********/

namespace simgrid {
namespace surf {

Model::Model()
  : maxminSystem_(nullptr)
{
  readyActionSet_ = new ActionList();
  runningActionSet_ = new ActionList();
  failedActionSet_ = new ActionList();
  doneActionSet_ = new ActionList();

  modifiedSet_ = nullptr;
  updateMechanism_ = UM_UNDEFINED;
  selectiveUpdate_ = 0;
}

Model::~Model(){
  delete readyActionSet_;
  delete runningActionSet_;
  delete failedActionSet_;
  delete doneActionSet_;
  delete modifiedSet_;
  delete maxminSystem_;
}

Action* Model::actionHeapPop()
{
  Action* action = actionHeap_.top().second;
  actionHeap_.pop();
  action->clearHeapHandle();
  return action;
}

double Model::nextOccuringEvent(double now)
{
  //FIXME: set the good function once and for all
  if (updateMechanism_ == UM_LAZY)
    return nextOccuringEventLazy(now);
  else if (updateMechanism_ == UM_FULL)
    return nextOccuringEventFull(now);
  else
    xbt_die("Invalid cpu update mechanism!");
}

double Model::nextOccuringEventLazy(double now)
{
  XBT_DEBUG("Before share resources, the size of modified actions set is %zu", modifiedSet_->size());
  lmm_solve(maxminSystem_);
  XBT_DEBUG("After share resources, The size of modified actions set is %zu", modifiedSet_->size());

  while (not modifiedSet_->empty()) {
    Action *action = &(modifiedSet_->front());
    modifiedSet_->pop_front();
    bool max_dur_flag = false;

    if (action->getStateSet() != runningActionSet_)
      continue;

    /* bogus priority, skip it */
    if (action->getPriority() <= 0 || action->getHat() == Action::Type::LATENCY)
      continue;

    action->updateRemainingLazy(now);

    double min = -1;
    double share = action->getVariable()->get_value();

    if (share > 0) {
      double time_to_completion;
      if (action->getRemains() > 0) {
        time_to_completion = action->getRemainsNoUpdate() / share;
      } else {
        time_to_completion = 0.0;
      }
      min = now + time_to_completion; // when the task will complete if nothing changes
    }

    if ((action->getMaxDuration() > NO_MAX_DURATION) &&
        (min <= -1 || action->getStartTime() + action->getMaxDuration() < min)) {
      // when the task will complete anyway because of the deadline if any
      min          = action->getStartTime() + action->getMaxDuration();
      max_dur_flag = true;
    }

    XBT_DEBUG("Action(%p) corresponds to variable %d", action, action->getVariable()->id_int);

    XBT_DEBUG("Action(%p) Start %f. May finish at %f (got a share of %f). Max_duration %f", action,
        action->getStartTime(), min, share,
        action->getMaxDuration());

    if (min > -1) {
      action->heapUpdate(actionHeap_, min, max_dur_flag ? Action::Type::MAX_DURATION : Action::Type::NORMAL);
      XBT_DEBUG("Insert at heap action(%p) min %f now %f", action, min, now);
    } else
      DIE_IMPOSSIBLE;
  }

  //hereafter must have already the min value for this resource model
  if (not actionHeapIsEmpty()) {
    double min = actionHeapTopDate() - now;
    XBT_DEBUG("minimum with the HEAP %f", min);
    return min;
  } else {
    XBT_DEBUG("The HEAP is empty, thus returning -1");
    return -1;
  }
}

double Model::nextOccuringEventFull(double /*now*/) {
  maxminSystem_->solve_fun(maxminSystem_);

  double min = -1;

  for (Action& action : *getRunningActionSet()) {
    double value = action.getVariable()->get_value();
    if (value > 0) {
      if (action.getRemains() > 0)
        value = action.getRemainsNoUpdate() / value;
      else
        value = 0.0;
      if (min < 0 || value < min) {
        min = value;
        XBT_DEBUG("Updating min (value) with %p: %f", &action, min);
      }
    }
    if ((action.getMaxDuration() >= 0) && (min < 0 || action.getMaxDuration() < min)) {
      min = action.getMaxDuration();
      XBT_DEBUG("Updating min (duration) with %p: %f", &action, min);
    }
  }
  XBT_DEBUG("min value : %f", min);

  return min;
}

void Model::updateActionsState(double now, double delta)
{
  if (updateMechanism_ == UM_FULL)
    updateActionsStateFull(now, delta);
  else if (updateMechanism_ == UM_LAZY)
    updateActionsStateLazy(now, delta);
  else
    xbt_die("Invalid cpu update mechanism!");
}

void Model::updateActionsStateLazy(double /*now*/, double /*delta*/)
{
  THROW_UNIMPLEMENTED;
}

void Model::updateActionsStateFull(double /*now*/, double /*delta*/)
{
  THROW_UNIMPLEMENTED;
}

}
}

/************
 * Resource *
 ************/

namespace simgrid {
namespace surf {

Resource::Resource(Model* model, const std::string& name, kernel::lmm::Constraint* constraint)
    : name_(name), model_(model), constraint_(constraint)
{}

Resource::~Resource() = default;

bool Resource::isOn() const {
  return isOn_;
}
bool Resource::isOff() const {
  return not isOn_;
}

void Resource::turnOn()
{
  isOn_ = true;
}

void Resource::turnOff()
{
  isOn_ = false;
}

double Resource::getLoad()
{
  return constraint_->get_usage();
}

Model* Resource::model() const
{
  return model_;
}

const std::string& Resource::getName() const
{
  return name_;
}

const char* Resource::getCname() const
{
  return name_.c_str();
}

bool Resource::operator==(const Resource &other) const {
  return name_ == other.name_;
}

kernel::lmm::Constraint* Resource::constraint() const
{
  return const_cast<kernel::lmm::Constraint*>(constraint_);
}

}
}

/**********
 * Action *
 **********/

namespace simgrid {
namespace surf {

Action::Action(simgrid::surf::Model* model, double cost, bool failed) : Action(model, cost, failed, nullptr)
{
}

Action::Action(simgrid::surf::Model* model, double cost, bool failed, kernel::lmm::Variable* var)
    : remains_(cost), start_(surf_get_clock()), cost_(cost), model_(model), variable_(var)
{
  if (failed)
    stateSet_ = getModel()->getFailedActionSet();
  else
    stateSet_ = getModel()->getRunningActionSet();

  stateSet_->push_back(*this);
}

Action::~Action() {
  xbt_free(category_);
}

void Action::finish(Action::State state)
{
  finishTime_ = surf_get_clock();
  setState(state);
}

Action::State Action::getState() const
{
  if (stateSet_ == model_->getReadyActionSet())
    return Action::State::ready;
  if (stateSet_ == model_->getRunningActionSet())
    return Action::State::running;
  if (stateSet_ == model_->getFailedActionSet())
    return Action::State::failed;
  if (stateSet_ == model_->getDoneActionSet())
    return Action::State::done;
  return Action::State::not_in_the_system;
}

void Action::setState(Action::State state)
{
  simgrid::xbt::intrusive_erase(*stateSet_, *this);
  switch (state) {
  case Action::State::ready:
    stateSet_ = model_->getReadyActionSet();
    break;
  case Action::State::running:
    stateSet_ = model_->getRunningActionSet();
    break;
  case Action::State::failed:
    stateSet_ = model_->getFailedActionSet();
    break;
  case Action::State::done:
    stateSet_ = model_->getDoneActionSet();
    break;
  default:
    stateSet_ = nullptr;
    break;
  }
  if (stateSet_)
    stateSet_->push_back(*this);
}

double Action::getBound() const
{
  return variable_ ? variable_->get_bound() : 0;
}

void Action::setBound(double bound)
{
  XBT_IN("(%p,%g)", this, bound);
  if (variable_)
    getModel()->getMaxminSystem()->update_variable_bound(variable_, bound);

  if (getModel()->getUpdateMechanism() == UM_LAZY && getLastUpdate() != surf_get_clock())
    heapRemove(getModel()->getActionHeap());
  XBT_OUT();
}

void Action::setCategory(const char *category)
{
  category_ = xbt_strdup(category);
}

void Action::ref(){
  refcount_++;
}

void Action::setMaxDuration(double duration)
{
  maxDuration_ = duration;
  if (getModel()->getUpdateMechanism() == UM_LAZY)      // remove action from the heap
    heapRemove(getModel()->getActionHeap());
}

void Action::setSharingWeight(double weight)
{
  XBT_IN("(%p,%g)", this, weight);
  sharingWeight_ = weight;
  getModel()->getMaxminSystem()->update_variable_weight(getVariable(), weight);

  if (getModel()->getUpdateMechanism() == UM_LAZY)
    heapRemove(getModel()->getActionHeap());
  XBT_OUT();
}

void Action::cancel(){
  setState(Action::State::failed);
  if (getModel()->getUpdateMechanism() == UM_LAZY) {
    if (action_lmm_hook.is_linked())
      simgrid::xbt::intrusive_erase(*getModel()->getModifiedSet(), *this);
    heapRemove(getModel()->getActionHeap());
  }
}

int Action::unref(){
  refcount_--;
  if (not refcount_) {
    if (action_hook.is_linked())
      simgrid::xbt::intrusive_erase(*stateSet_, *this);
    if (getVariable())
      getModel()->getMaxminSystem()->variable_free(getVariable());
    if (getModel()->getUpdateMechanism() == UM_LAZY) {
      /* remove from heap */
      heapRemove(getModel()->getActionHeap());
      if (action_lmm_hook.is_linked())
        simgrid::xbt::intrusive_erase(*getModel()->getModifiedSet(), *this);
    }
    delete this;
    return 1;
  }
  return 0;
}

void Action::suspend()
{
  XBT_IN("(%p)", this);
  if (suspended_ != SuspendStates::sleeping) {
    getModel()->getMaxminSystem()->update_variable_weight(getVariable(), 0.0);
    if (getModel()->getUpdateMechanism() == UM_LAZY){
      heapRemove(getModel()->getActionHeap());
      if (getModel()->getUpdateMechanism() == UM_LAZY && stateSet_ == getModel()->getRunningActionSet() &&
          sharingWeight_ > 0) {
        //If we have a lazy model, we need to update the remaining value accordingly
        updateRemainingLazy(surf_get_clock());
      }
    }
    suspended_ = SuspendStates::suspended;
  }
  XBT_OUT();
}

void Action::resume()
{
  XBT_IN("(%p)", this);
  if (suspended_ != SuspendStates::sleeping) {
    getModel()->getMaxminSystem()->update_variable_weight(getVariable(), getPriority());
    suspended_ = SuspendStates::not_suspended;
    if (getModel()->getUpdateMechanism() == UM_LAZY)
      heapRemove(getModel()->getActionHeap());
  }
  XBT_OUT();
}

bool Action::isSuspended()
{
  return suspended_ == SuspendStates::suspended;
}
/* insert action on heap using a given key and a hat (heap_action_type)
 * a hat can be of three types for communications:
 *
 * NORMAL = this is a normal heap entry stating the date to finish transmitting
 * LATENCY = this is a heap entry to warn us when the latency is payed
 * MAX_DURATION =this is a heap entry to warn us when the max_duration limit is reached
 */
void Action::heapInsert(heap_type& heap, double key, Action::Type hat)
{
  hat_ = hat;
  heapHandle_ = heap.emplace(std::make_pair(key, this));
}

void Action::heapRemove(heap_type& heap)
{
  hat_ = Action::Type::NOTSET;
  if (heapHandle_) {
    heap.erase(*heapHandle_);
    clearHeapHandle();
  }
}

void Action::heapUpdate(heap_type& heap, double key, Action::Type hat)
{
  hat_ = hat;
  if (heapHandle_) {
    heap.update(*heapHandle_, std::make_pair(key, this));
  } else {
    heapHandle_ = heap.emplace(std::make_pair(key, this));
  }
}

double Action::getRemains()
{
  XBT_IN("(%p)", this);
  /* update remains before return it */
  if (getModel()->getUpdateMechanism() == UM_LAZY)      /* update remains before return it */
    updateRemainingLazy(surf_get_clock());
  XBT_OUT();
  return remains_;
}

}
}