-/* Copyright (c) 2013-2019. The SimGrid Team. All rights reserved. */
+/* Copyright (c) 2013-2022. 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 "cpu_ti.hpp"
+#include "simgrid/kernel/routing/NetZoneImpl.hpp"
+#include "simgrid/s4u/Engine.hpp"
+#include "src/kernel/EngineImpl.hpp"
#include "src/kernel/resource/profile/Event.hpp"
#include "src/kernel/resource/profile/Profile.hpp"
#include "src/surf/surf_interface.hpp"
-#include "surf/surf.hpp"
#include <algorithm>
+#include <memory>
constexpr double EPSILON = 0.000000001;
-XBT_LOG_NEW_DEFAULT_SUBCATEGORY(surf_cpu_ti, surf_cpu, "Logging specific to the SURF CPU TRACE INTEGRATION module");
+XBT_LOG_NEW_DEFAULT_SUBCATEGORY(cpu_ti, res_cpu, "CPU resource, Trace Integration model");
namespace simgrid {
namespace kernel {
CpuTiProfile::CpuTiProfile(const profile::Profile* profile)
{
- double integral = 0;
- double time = 0;
- unsigned nb_points = profile->event_list.size() + 1;
+ double integral = 0;
+ double time = 0;
+ unsigned long nb_points = profile->get_event_list().size() + 1;
time_points_.reserve(nb_points);
integral_.reserve(nb_points);
- for (auto const& val : profile->event_list) {
+ for (auto const& val : profile->get_event_list()) {
time_points_.push_back(time);
integral_.push_back(integral);
time += val.date_;
* @param b End of interval
* @return the integrate value. -1 if an error occurs.
*/
-double CpuTiTmgr::integrate(double a, double b)
+double CpuTiTmgr::integrate(double a, double b) const
{
- if ((a < 0.0) || (a > b)) {
- xbt_die("Error, invalid integration interval [%.2f,%.2f]. "
- "You probably have a task executing with negative computation amount. Check your code.", a, b);
- }
+ xbt_assert(a >= 0.0 && a <= b,
+ "Error, invalid integration interval [%.2f,%.2f]. You probably have a task executing with negative "
+ "computation amount. Check your code.",
+ a, b);
if (fabs(a - b) < EPSILON)
return 0.0;
return (b - a) * value_;
}
- int a_index;
+ double a_index;
if (fabs(ceil(a / last_time_) - a / last_time_) < EPSILON)
- a_index = 1 + static_cast<int>(ceil(a / last_time_));
+ a_index = 1 + ceil(a / last_time_);
else
- a_index = static_cast<int>(ceil(a / last_time_));
+ a_index = ceil(a / last_time_);
+ double b_index = floor(b / last_time_);
- int b_index = static_cast<int>(floor(b / last_time_));
-
- if (a_index > b_index) { /* Same chunk */
- return profile_->integrate_simple(a - (a_index - 1) * last_time_, b - (b_index)*last_time_);
+ if (a_index > b_index) { /* Same chunk */
+ return profile_->integrate_simple(a - (a_index - 1) * last_time_, b - b_index * last_time_);
}
double first_chunk = profile_->integrate_simple(a - (a_index - 1) * last_time_, last_time_);
double middle_chunk = (b_index - a_index) * total_;
- double last_chunk = profile_->integrate_simple(0.0, b - (b_index)*last_time_);
+ double last_chunk = profile_->integrate_simple(0.0, b - b_index * last_time_);
XBT_DEBUG("first_chunk=%.2f middle_chunk=%.2f last_chunk=%.2f\n", first_chunk, middle_chunk, last_chunk);
* @param a Initial point
* @param b Final point
*/
-double CpuTiProfile::integrate_simple(double a, double b)
+double CpuTiProfile::integrate_simple(double a, double b) const
{
return integrate_simple_point(b) - integrate_simple_point(a);
}
* @brief Auxiliary function to compute the integral at point a.
* @param a point
*/
-double CpuTiProfile::integrate_simple_point(double a)
+double CpuTiProfile::integrate_simple_point(double a) const
{
double integral = 0;
- double a_aux = a;
- int ind = binary_search(time_points_, a);
+ double a_aux = a;
+ long ind = binary_search(time_points_, a);
integral += integral_[ind];
- XBT_DEBUG("a %f ind %d integral %f ind + 1 %f ind %f time +1 %f time %f", a, ind, integral, integral_[ind + 1],
+ XBT_DEBUG("a %f ind %ld integral %f ind + 1 %f ind %f time +1 %f time %f", a, ind, integral, integral_[ind + 1],
integral_[ind], time_points_[ind + 1], time_points_[ind]);
double_update(&a_aux, time_points_[ind], sg_maxmin_precision * sg_surf_precision);
if (a_aux > 0)
* @param amount Amount to be executed
* @return End time
*/
-double CpuTiTmgr::solve(double a, double amount)
+double CpuTiTmgr::solve(double a, double amount) const
{
/* Fix very small negative numbers */
if ((a < 0.0) && (a > -EPSILON)) {
}
/* Sanity checks */
- if ((a < 0.0) || (amount < 0.0)) {
- XBT_CRITICAL ("Error, invalid parameters [a = %.2f, amount = %.2f]. "
- "You probably have a task executing with negative computation amount. Check your code.", a, amount);
- xbt_abort();
- }
+ xbt_assert(a >= 0.0 && amount >= 0.0,
+ "Error, invalid parameters [a = %.2f, amount = %.2f]. "
+ "You probably have a task executing with negative computation amount. Check your code.",
+ a, amount);
/* At this point, a and amount are positive */
if (amount < EPSILON)
XBT_DEBUG("amount %f total %f", amount, total_);
/* Reduce the problem to one where amount <= trace_total */
- int quotient = static_cast<int>(floor(amount / total_));
- double reduced_amount = (total_) * ((amount / total_) - floor(amount / total_));
- double reduced_a = a - (last_time_) * static_cast<int>(floor(a / last_time_));
+ double quotient = floor(amount / total_);
+ double reduced_amount = total_ * ((amount / total_) - floor(amount / total_));
+ double reduced_a = a - last_time_ * static_cast<int>(floor(a / last_time_));
- XBT_DEBUG("Quotient: %d reduced_amount: %f reduced_a: %f", quotient, reduced_amount, reduced_a);
+ XBT_DEBUG("Quotient: %g reduced_amount: %f reduced_a: %f", quotient, reduced_amount, reduced_a);
/* Now solve for new_amount which is <= trace_total */
double reduced_b;
}
/* Re-map to the original b and amount */
- return (last_time_) * static_cast<int>(floor(a / last_time_)) + (quotient * last_time_) + reduced_b;
+ return last_time_ * floor(a / last_time_) + (quotient * last_time_) + reduced_b;
}
/**
* @param amount Amount of flops
* @return The date when amount is available.
*/
-double CpuTiProfile::solve_simple(double a, double amount)
+double CpuTiProfile::solve_simple(double a, double amount) const
{
double integral_a = integrate_simple_point(a);
- int ind = binary_search(integral_, integral_a + amount);
+ long ind = binary_search(integral_, integral_a + amount);
double time = time_points_[ind];
time += (integral_a + amount - integral_[ind]) /
((integral_[ind + 1] - integral_[ind]) / (time_points_[ind + 1] - time_points_[ind]));
* @param a Time
* @return CPU speed scale
*/
-double CpuTiTmgr::get_power_scale(double a)
+double CpuTiTmgr::get_power_scale(double a) const
{
- double reduced_a = a - floor(a / last_time_) * last_time_;
- int point = CpuTiProfile::binary_search(profile_->time_points_, reduced_a);
- kernel::profile::DatedValue val = speed_profile_->event_list.at(point);
+ double reduced_a = a - floor(a / last_time_) * last_time_;
+ long point = CpuTiProfile::binary_search(profile_->get_time_points(), reduced_a);
+ profile::DatedValue val = speed_profile_->get_event_list().at(point);
return val.value_;
}
}
/* only one point available, fixed trace */
- if (speed_profile->event_list.size() == 1) {
- value_ = speed_profile->event_list.front().value_;
+ if (speed_profile->get_event_list().size() == 1) {
+ value_ = speed_profile->get_event_list().front().value_;
return;
}
type_ = Type::DYNAMIC;
/* count the total time of trace file */
- for (auto const& val : speed_profile->event_list)
+ for (auto const& val : speed_profile->get_event_list())
total_time += val.date_;
- profile_.reset(new CpuTiProfile(speed_profile));
+ profile_ = std::make_unique<CpuTiProfile>(speed_profile);
last_time_ = total_time;
total_ = profile_->integrate_simple(0, total_time);
* @param a Value to search
* @return Index of point
*/
-int CpuTiProfile::binary_search(const std::vector<double>& array, double a)
+long CpuTiProfile::binary_search(const std::vector<double>& array, double a)
{
if (array[0] > a)
return 0;
* Model *
*********/
-void CpuTiModel::create_pm_vm_models()
+void CpuTiModel::create_pm_models()
{
- xbt_assert(surf_cpu_model_pm == nullptr, "CPU model already initialized. This should not happen.");
- xbt_assert(surf_cpu_model_vm == nullptr, "CPU model already initialized. This should not happen.");
-
- surf_cpu_model_pm = new simgrid::kernel::resource::CpuTiModel();
- surf_cpu_model_vm = new simgrid::kernel::resource::CpuTiModel();
+ auto cpu_model_pm = std::make_shared<CpuTiModel>("Cpu_TI");
+ auto* engine = EngineImpl::get_instance();
+ engine->add_model(cpu_model_pm);
+ engine->get_netzone_root()->set_cpu_pm_model(cpu_model_pm);
}
-CpuTiModel::CpuTiModel() : CpuModel(Model::UpdateAlgo::FULL)
+CpuImpl* CpuTiModel::create_cpu(s4u::Host* host, const std::vector<double>& speed_per_pstate)
{
- all_existing_models.push_back(this);
-}
-
-CpuTiModel::~CpuTiModel()
-{
- surf_cpu_model_pm = nullptr;
-}
-
-kernel::resource::Cpu* CpuTiModel::create_cpu(s4u::Host* host, const std::vector<double>& speed_per_pstate, int core)
-{
- return new CpuTi(this, host, speed_per_pstate, core);
+ return (new CpuTi(host, speed_per_pstate))->set_model(this);
}
double CpuTiModel::next_occurring_event(double now)
while (not get_action_heap().empty() && double_equals(get_action_heap().top_date(), now, sg_surf_precision)) {
auto* action = static_cast<CpuTiAction*>(get_action_heap().pop());
XBT_DEBUG("Action %p: finish", action);
- action->finish(kernel::resource::Action::State::FINISHED);
+ action->finish(Action::State::FINISHED);
/* update remaining amount of all actions */
- action->cpu_->update_remaining_amount(surf_get_clock());
+ action->cpu_->update_remaining_amount(EngineImpl::get_clock());
}
}
/************
* Resource *
************/
-CpuTi::CpuTi(CpuTiModel* model, simgrid::s4u::Host* host, const std::vector<double>& speed_per_pstate, int core)
- : Cpu(model, host, speed_per_pstate, core)
+CpuTi::CpuTi(s4u::Host* host, const std::vector<double>& speed_per_pstate) : CpuImpl(host, speed_per_pstate)
{
- xbt_assert(core == 1, "Multi-core not handled by this model yet");
-
speed_.peak = speed_per_pstate.front();
XBT_DEBUG("CPU create: peak=%f", speed_.peak);
set_modified(false);
delete speed_integrated_trace_;
}
-void CpuTi::set_speed_profile(kernel::profile::Profile* profile)
+
+CpuImpl* CpuTi::set_speed_profile(kernel::profile::Profile* profile)
{
delete speed_integrated_trace_;
speed_integrated_trace_ = new CpuTiTmgr(profile, speed_.scale);
/* add a fake trace event if periodicity == 0 */
- if (profile && profile->event_list.size() > 1) {
- kernel::profile::DatedValue val = profile->event_list.back();
+ if (profile && profile->get_event_list().size() > 1) {
+ kernel::profile::DatedValue val = profile->get_event_list().back();
if (val.date_ < 1e-12) {
- auto* prof = new simgrid::kernel::profile::Profile();
+ auto* prof = new kernel::profile::Profile();
speed_.event = prof->schedule(&profile::future_evt_set, this);
}
}
+ return this;
}
void CpuTi::apply_event(kernel::profile::Event* event, double value)
XBT_DEBUG("Speed changed in trace! New fixed value: %f", value);
/* update remaining of actions and put in modified cpu list */
- update_remaining_amount(surf_get_clock());
+ update_remaining_amount(EngineImpl::get_clock());
set_modified(true);
speed_.scale = value;
tmgr_trace_event_unref(&speed_.event);
- } else if (event == state_event_) {
+ } else if (event == get_state_event()) {
if (value > 0) {
if (not is_on()) {
- XBT_VERB("Restart processes on host %s", get_host()->get_cname());
- get_host()->turn_on();
+ XBT_VERB("Restart actors on host %s", get_iface()->get_cname());
+ get_iface()->turn_on();
}
} else {
- get_host()->turn_off();
- double date = surf_get_clock();
+ get_iface()->turn_off();
+ double date = EngineImpl::get_clock();
/* put all action running on cpu to failed */
for (CpuTiAction& action : action_set_) {
- if (action.get_state() == kernel::resource::Action::State::INITED ||
- action.get_state() == kernel::resource::Action::State::STARTED ||
- action.get_state() == kernel::resource::Action::State::IGNORED) {
+ if (action.get_state() == Action::State::INITED || action.get_state() == Action::State::STARTED ||
+ action.get_state() == Action::State::IGNORED) {
action.set_finish_time(date);
- action.set_state(kernel::resource::Action::State::FAILED);
+ action.set_state(Action::State::FAILED);
get_model()->get_action_heap().remove(&action);
}
}
}
- tmgr_trace_event_unref(&state_event_);
+ unref_state_event();
} else {
xbt_die("Unknown event!\n");
sum_priority_ = 0.0;
for (CpuTiAction const& action : action_set_) {
/* action not running, skip it */
- if (action.get_state_set() != surf_cpu_model_pm->get_started_action_set())
+ if (action.get_state_set() != get_model()->get_started_action_set())
continue;
/* bogus priority, skip it */
}
for (CpuTiAction& action : action_set_) {
- double min_finish = -1;
+ double min_finish = NO_MAX_DURATION;
/* action not running, skip it */
- if (action.get_state_set() != surf_cpu_model_pm->get_started_action_set())
+ if (action.get_state_set() != get_model()->get_started_action_set())
continue;
/* verify if the action is really running on cpu */
}
/* add in action heap */
if (min_finish != NO_MAX_DURATION)
- get_model()->get_action_heap().update(&action, min_finish, kernel::resource::ActionHeap::Type::unset);
+ get_model()->get_action_heap().update(&action, min_finish, ActionHeap::Type::unset);
else
get_model()->get_action_heap().remove(&action);
set_modified(false);
}
-bool CpuTi::is_used()
+bool CpuTi::is_used() const
{
return not action_set_.empty();
}
double CpuTi::get_speed_ratio()
{
- speed_.scale = speed_integrated_trace_->get_power_scale(surf_get_clock());
- return Cpu::get_speed_ratio();
+ speed_.scale = speed_integrated_trace_->get_power_scale(EngineImpl::get_clock());
+ return CpuImpl::get_speed_ratio();
}
/** @brief Update the remaining amount of actions */
last_update_ = now;
}
-kernel::resource::CpuAction* CpuTi::execution_start(double size)
+CpuAction* CpuTi::execution_start(double size, double user_bound)
{
XBT_IN("(%s,%g)", get_cname(), size);
+ xbt_assert(user_bound <= 0, "Invalid user bound (%lf) in CPU TI model", user_bound);
auto* action = new CpuTiAction(this, size);
action_set_.push_back(*action); // Actually start the action
return action;
}
-kernel::resource::CpuAction* CpuTi::sleep(double duration)
+CpuAction* CpuTi::sleep(double duration)
{
if (duration > 0)
duration = std::max(duration, sg_surf_precision);
auto* action = new CpuTiAction(this, 1.0);
action->set_max_duration(duration);
- action->set_suspend_state(kernel::resource::Action::SuspendStates::SLEEPING);
+ action->set_suspend_state(Action::SuspendStates::SLEEPING);
if (duration == NO_MAX_DURATION)
- action->set_state(simgrid::kernel::resource::Action::State::IGNORED);
+ action->set_state(Action::State::IGNORED);
action_set_.push_back(*action);
}
} else {
if (cpu_ti_hook.is_linked())
- simgrid::xbt::intrusive_erase(modified_cpus, *this);
+ xbt::intrusive_erase(modified_cpus, *this);
}
}
{
/* remove from action_set */
if (action_ti_hook.is_linked())
- simgrid::xbt::intrusive_erase(cpu_->action_set_, *this);
+ xbt::intrusive_erase(cpu_->action_set_, *this);
/* remove from heap */
get_model()->get_action_heap().remove(this);
cpu_->set_modified(true);
XBT_OUT();
}
-void CpuTiAction::set_max_duration(double duration)
-{
- double min_finish;
-
- XBT_IN("(%p,%g)", this, duration);
-
- Action::set_max_duration(duration);
-
- if (duration >= 0)
- min_finish = (get_start_time() + get_max_duration()) < get_finish_time() ? (get_start_time() + get_max_duration())
- : get_finish_time();
- else
- min_finish = get_finish_time();
-
- /* add in action heap */
- get_model()->get_action_heap().update(this, min_finish, kernel::resource::ActionHeap::Type::unset);
-
- XBT_OUT();
-}
-
void CpuTiAction::set_sharing_penalty(double sharing_penalty)
{
XBT_IN("(%p,%g)", this, sharing_penalty);
double CpuTiAction::get_remains()
{
XBT_IN("(%p)", this);
- cpu_->update_remaining_amount(surf_get_clock());
+ cpu_->update_remaining_amount(EngineImpl::get_clock());
XBT_OUT();
return get_remains_no_update();
}