#include <memory>
#include <simgrid/Exception.hpp>
+#include <simgrid/s4u/Activity.hpp>
#include <simgrid/s4u/Comm.hpp>
+#include <simgrid/s4u/Disk.hpp>
#include <simgrid/s4u/Exec.hpp>
#include <simgrid/s4u/Io.hpp>
#include <simgrid/s4u/Task.hpp>
#include <simgrid/simix.hpp>
+#include <string>
+#include <xbt/asserts.h>
#include "src/simgrid/module.hpp"
* @brief Return True if the Task can start a new Activity.
* @note The Task is ready if not already doing something and there is at least one execution waiting in queue.
*/
-bool Task::ready_to_run() const
+bool Task::ready_to_run(std::string instance)
{
- return not working_ && queued_firings_ > 0;
+ return running_instances_[instance] < parallelism_degree_[instance] && queued_firings_[instance] > 0;
}
/**
void Task::receive(Task* source)
{
XBT_DEBUG("Task %s received a token from %s", name_.c_str(), source->name_.c_str());
- auto source_count = predecessors_[source];
predecessors_[source]++;
- if (tokens_received_.size() <= queued_firings_ + source_count)
- tokens_received_.emplace_back();
- tokens_received_[queued_firings_ + source_count][source] = source->token_;
- bool enough_tokens = true;
+ tokens_received_[source].push_back(source->token_);
+ bool enough_tokens = true;
for (auto const& [key, val] : predecessors_)
if (val < 1) {
enough_tokens = false;
* Send a token to each of its successors.
* Start a new execution if possible.
*/
-void Task::complete()
+void Task::complete(std::string instance)
{
xbt_assert(Actor::is_maestro());
- working_ = false;
- count_++;
- on_this_completion(this);
- on_completion(this);
- if (current_activity_)
- previous_activity_ = std::move(current_activity_);
- for (auto const& t : successors_)
- t->receive(this);
- if (ready_to_run())
- fire();
+ running_instances_[instance] = running_instances_[instance] - 1;
+ count_[instance] = count_[instance] + 1;
+ if (instance == "collector") {
+ // XBT_INFO("Trigger on completion: %s - %s", get_cname(), instance.c_str());
+ on_this_completion(this);
+ on_completion(this);
+ for (auto const& t : successors_)
+ t->receive(this);
+ } else if (instance == "dispatcher") {
+ auto next_instance = load_balancing_function_();
+ xbt_assert(next_instance != "dispatcher" and next_instance != "collector", "Invalid instance selected: %s",
+ next_instance.c_str());
+ queued_firings_[next_instance] = queued_firings_.at(next_instance) + 1;
+ while (ready_to_run(next_instance))
+ fire(next_instance);
+ } else {
+ queued_firings_["collector"] = queued_firings_["collector"] + 1;
+ while (ready_to_run("collector"))
+ fire("collector");
+ }
+ if (ready_to_run(instance))
+ fire(instance);
+}
+
+/** @param n The new parallelism degree of the Task.
+ * @brief Set the parallelism degree of the Task to inscrease or decrease horizontal scaling.
+ * @note When increasing the degree the function starts new instances if there is queued firings.
+ * When decreasing the degree the function does NOT stop running instances.
+ */
+void Task::set_parallelism_degree(int n, std::string instance)
+{
+ xbt_assert(n > 0, "Parallelism degree must be above 0.");
+ simgrid::kernel::actor::simcall_answered([this, n, &instance] {
+ if (instance == "all") {
+ for (auto& [key, value] : parallelism_degree_) {
+ parallelism_degree_[key] = n;
+ while (ready_to_run(key))
+ fire(key);
+ }
+ } else {
+ parallelism_degree_[instance] = n;
+ while (ready_to_run(instance))
+ fire(instance);
+ }
+ });
+}
+
+void Task::set_internal_bytes(int bytes, std::string instance)
+{
+ simgrid::kernel::actor::simcall_answered([this, bytes, &instance] { internal_bytes_to_send_[instance] = bytes; });
+}
+
+void Task::set_load_balancing_function(std::function<std::string()> func)
+{
+ simgrid::kernel::actor::simcall_answered([this, func] { load_balancing_function_ = func; });
}
/** @param n The number of firings to enqueue.
void Task::enqueue_firings(int n)
{
simgrid::kernel::actor::simcall_answered([this, n] {
- queued_firings_ += n;
- if (ready_to_run())
- fire();
+ queued_firings_["dispatcher"] += n;
+ while (ready_to_run("dispatcher"))
+ fire("dispatcher");
});
}
+/** @param name The new name to set.
+ * @brief Set the name of the Task.
+ */
+void Task::set_name(std::string name)
+{
+ name_ = name;
+}
+
/** @param amount The amount to set.
* @brief Set the amout of work to do.
* @note Amount in flop for ExecTask and in bytes for CommTask.
*/
-void Task::set_amount(double amount)
+void Task::set_amount(double amount, std::string instance)
{
- simgrid::kernel::actor::simcall_answered([this, amount] { amount_ = amount; });
+ simgrid::kernel::actor::simcall_answered([this, amount, &instance] { amount_[instance] = amount; });
}
/** @param token The token to set.
* @brief Set the token to send to successors.
- * @note The token is passed to each successor after the task end, i.e., after the on_end callback.
+ * @note The token is passed to each successor after the task end, i.e., after the on_completion callback.
*/
void Task::set_token(std::shared_ptr<Token> token)
{
simgrid::kernel::actor::simcall_answered([this, token] { token_ = token; });
}
-/** @return Map of tokens received for the next execution.
- * @note If there is no queued execution for this task the map might not exist or be partially empty.
- */
-std::shared_ptr<Token> Task::get_next_token_from(TaskPtr t)
+void Task::deque_token_from(TaskPtr t)
{
- return tokens_received_.front()[t];
+ simgrid::kernel::actor::simcall_answered([this, &t] { tokens_received_.at(t).pop_front(); });
}
-void Task::fire()
+void Task::fire(std::string instance)
{
- on_this_start(this);
- on_start(this);
- working_ = true;
- queued_firings_ = std::max(queued_firings_ - 1, 0);
- if (not tokens_received_.empty())
- tokens_received_.pop_front();
+ if ((int)current_activities_[instance].size() > parallelism_degree_[instance]) {
+ current_activities_[instance].pop_front();
+ }
+ if (instance != "dispatcher" and instance != "collector") {
+ on_this_start(this);
+ on_start(this);
+ }
+ running_instances_[instance]++;
+ queued_firings_[instance] = std::max(queued_firings_[instance] - 1, 0);
}
/** @param successor The Task to add.
});
}
+/**
+ * @brief TODO
+ */
void Task::remove_all_successors()
{
simgrid::kernel::actor::simcall_answered([this] {
});
}
+/**
+ * @brief TODO
+ */
+void Task::add_instances(int n)
+{
+ xbt_assert(n >= 0, "Cannot add a negative number of instances (provided: %d)", n);
+ int instance_count = (int)amount_.size() - 2;
+ for (int i = instance_count; i < n + instance_count; i++) {
+ amount_["instance_" + std::to_string(i)] = amount_.at("instance_0");
+ queued_firings_["instance_" + std::to_string(i)] = 0;
+ running_instances_["instance_" + std::to_string(i)] = 0;
+ count_["instance_" + std::to_string(i)] = 0;
+ parallelism_degree_["instance_" + std::to_string(i)] = parallelism_degree_.at("instance_0");
+ current_activities_["instance_" + std::to_string(i)] = {};
+ internal_bytes_to_send_["instance_" + std::to_string(i)] = internal_bytes_to_send_.at("instance_0");
+ ;
+ }
+}
+
+/**
+ * @brief TODO
+ */
+void Task::remove_instances(int n)
+{
+ int instance_count = (int)amount_.size() - 2;
+ xbt_assert(n >= 0, "Cannot remove a negative number of instances (provided: %d)", n);
+ xbt_assert(instance_count - n > 0, "The number of instances must be above 0 (instances: %d, provided: %d)",
+ instance_count, n);
+ for (int i = instance_count - 1; i >= instance_count - n; i--)
+ xbt_assert(running_instances_.at("instance_" + std::to_string(i)) == 0,
+ "Cannot remove a running instance (instances: %d)", i);
+ for (int i = instance_count - 1; i >= instance_count - n; i--) {
+ amount_.erase("instance_" + std::to_string(i));
+ queued_firings_.erase("instance_" + std::to_string(i));
+ running_instances_.erase("instance_" + std::to_string(i));
+ count_.erase("instance_" + std::to_string(i));
+ parallelism_degree_.erase("instance_" + std::to_string(i));
+ current_activities_.erase("instance_" + std::to_string(i));
+ }
+}
+
/**
* @brief Default constructor.
*/
-ExecTask::ExecTask(const std::string& name) : Task(name) {}
+ExecTask::ExecTask(const std::string& name) : Task(name)
+{
+ set_load_balancing_function([]() { return "instance_0"; });
+}
-/** @ingroup plugin_task
+/**
* @brief Smart Constructor.
*/
ExecTaskPtr ExecTask::init(const std::string& name)
return ExecTaskPtr(new ExecTask(name));
}
-/** @ingroup plugin_task
+/**
* @brief Smart Constructor.
*/
ExecTaskPtr ExecTask::init(const std::string& name, double flops, Host* host)
/**
* @brief Do one execution of the Task.
- * @note Call the on_this_start() func. Set its working status as true.
+ * @note Call the on_this_start() func.
* Init and start the underlying Activity.
*/
-void ExecTask::fire()
+void ExecTask::fire(std::string instance)
{
- Task::fire();
- auto exec = Exec::init()->set_name(get_name())->set_flops_amount(get_amount())->set_host(host_);
- exec->start();
- exec->on_this_completion_cb([this](Exec const&) { this->complete(); });
- set_current_activity(exec);
+ Task::fire(instance);
+ if (instance == "dispatcher" or instance == "collector") {
+ auto exec = Exec::init()
+ ->set_name(get_name() + "_" + instance)
+ ->set_flops_amount(get_amount(instance))
+ ->set_host(host_[instance]);
+ exec->start();
+ exec->on_this_completion_cb([this, instance](Exec const&) { complete(instance); });
+ store_activity(exec, instance);
+ } else {
+ auto exec = Exec::init()->set_name(get_name())->set_flops_amount(get_amount())->set_host(host_[instance]);
+ if (host_["dispatcher"] == host_[instance]) {
+ exec->start();
+ store_activity(exec, instance);
+ } else {
+ auto comm = Comm::sendto_init(host_["dispatcher"], host_[instance])
+ ->set_name(get_name() + "_dispatcher_to_" + instance)
+ ->set_payload_size(get_internal_bytes("dispatcher"));
+ comm->add_successor(exec);
+ comm->start();
+ store_activity(comm, instance);
+ }
+ if (host_[instance] == host_["collector"]) {
+ exec->on_this_completion_cb([this, instance](Exec const&) { complete(instance); });
+ if (host_["dispatcher"] != host_[instance])
+ store_activity(exec, instance);
+ } else {
+ auto comm = Comm::sendto_init(host_[instance], host_["collector"])
+ ->set_name(get_name() + instance + "_to_collector")
+ ->set_payload_size(get_internal_bytes(instance));
+ exec->add_successor(comm);
+ comm->on_this_completion_cb([this, instance](Comm const&) { complete(instance); });
+ comm.detach();
+ }
+ }
}
-/** @ingroup plugin_task
+/**
* @param host The host to set.
* @brief Set a new host.
*/
-ExecTaskPtr ExecTask::set_host(Host* host)
+ExecTaskPtr ExecTask::set_host(Host* host, std::string instance)
{
- kernel::actor::simcall_answered([this, host] { host_ = host; });
+ kernel::actor::simcall_answered([this, host, &instance] {
+ if (instance == "all")
+ for (auto& [key, value] : host_)
+ host_[key] = host;
+ else
+ host_[instance] = host;
+ });
return this;
}
-/** @ingroup plugin_task
+/**
* @param flops The amount of flops to set.
*/
-ExecTaskPtr ExecTask::set_flops(double flops)
+ExecTaskPtr ExecTask::set_flops(double flops, std::string instance)
{
- kernel::actor::simcall_answered([this, flops] { set_amount(flops); });
+ kernel::actor::simcall_answered([this, flops, &instance] { set_amount(flops, instance); });
return this;
}
+/**
+ * @brief TODO
+ */
+void ExecTask::add_instances(int n)
+{
+ Task::add_instances(n);
+ int instance_count = (int)host_.size() - 2;
+ for (int i = instance_count; i < n + instance_count; i++)
+ host_["instance_" + std::to_string(i)] = host_.at("instance_0");
+}
+
+/**
+ * @brief TODO
+ */
+void ExecTask::remove_instances(int n)
+{
+ Task::remove_instances(n);
+ int instance_count = (int)host_.size() - 2;
+ for (int i = instance_count - 1; i >= instance_count - n; i--)
+ host_.erase("instance_" + std::to_string(i));
+}
+
/**
* @brief Default constructor.
*/
-CommTask::CommTask(const std::string& name) : Task(name) {}
+CommTask::CommTask(const std::string& name) : Task(name)
+{
+ set_load_balancing_function([]() { return "instance_0"; });
+}
-/** @ingroup plugin_task
+/**
* @brief Smart constructor.
*/
CommTaskPtr CommTask::init(const std::string& name)
return CommTaskPtr(new CommTask(name));
}
-/** @ingroup plugin_task
+/**
* @brief Smart constructor.
*/
CommTaskPtr CommTask::init(const std::string& name, double bytes, Host* source, Host* destination)
/**
* @brief Do one execution of the Task.
- * @note Call the on_this_start() func. Set its working status as true.
+ * @note Call the on_this_start() func.
* Init and start the underlying Activity.
*/
-void CommTask::fire()
+void CommTask::fire(std::string instance)
{
- Task::fire();
- auto comm = Comm::sendto_init(source_, destination_)->set_name(get_name())->set_payload_size(get_amount());
- comm->start();
- comm->on_this_completion_cb([this](Comm const&) { this->complete(); });
- set_current_activity(comm);
+ Task::fire(instance);
+ if (instance == "dispatcher" or instance == "collector") {
+ auto exec = Exec::init()
+ ->set_name(get_name() + "_" + instance)
+ ->set_flops_amount(get_amount(instance))
+ ->set_host(instance == "dispatcher" ? source_ : destination_);
+ exec->start();
+ exec->on_this_completion_cb([this, instance](Exec const&) { complete(instance); });
+ store_activity(exec, instance);
+ } else {
+ auto comm = Comm::sendto_init(source_, destination_)->set_name(get_name())->set_payload_size(get_amount());
+ comm->start();
+ comm->on_this_completion_cb([this, instance](Comm const&) { complete(instance); });
+ store_activity(comm, instance);
+ }
}
-/** @ingroup plugin_task
+/**
* @param source The host to set.
* @brief Set a new source host.
*/
return this;
}
-/** @ingroup plugin_task
+/**
* @param destination The host to set.
* @brief Set a new destination host.
*/
return this;
}
-/** @ingroup plugin_task
+/**
* @param bytes The amount of bytes to set.
*/
CommTaskPtr CommTask::set_bytes(double bytes)
/**
* @brief Default constructor.
*/
-IoTask::IoTask(const std::string& name) : Task(name) {}
+IoTask::IoTask(const std::string& name) : Task(name)
+{
+ set_load_balancing_function([]() { return "instance_0"; });
+}
-/** @ingroup plugin_task
+/**
* @brief Smart Constructor.
*/
IoTaskPtr IoTask::init(const std::string& name)
return IoTaskPtr(new IoTask(name));
}
-/** @ingroup plugin_task
+/**
* @brief Smart Constructor.
*/
IoTaskPtr IoTask::init(const std::string& name, double bytes, Disk* disk, Io::OpType type)
return init(name)->set_bytes(bytes)->set_disk(disk)->set_op_type(type);
}
-/** @ingroup plugin_task
+/**
* @param disk The disk to set.
* @brief Set a new disk.
*/
return this;
}
-/** @ingroup plugin_task
+/**
* @param bytes The amount of bytes to set.
*/
IoTaskPtr IoTask::set_bytes(double bytes)
return this;
}
-/** @ingroup plugin_task */
+/** */
IoTaskPtr IoTask::set_op_type(Io::OpType type)
{
kernel::actor::simcall_answered([this, type] { type_ = type; });
return this;
}
-void IoTask::fire()
+void IoTask::fire(std::string instance)
{
- Task::fire();
- auto io = Io::init()->set_name(get_name())->set_size(get_amount())->set_disk(disk_)->set_op_type(type_);
- io->start();
- io->on_this_completion_cb([this](Io const&) { this->complete(); });
- set_current_activity(io);
+ Task::fire(instance);
+ if (instance == "dispatcher" or instance == "collector") {
+ auto exec = Exec::init()
+ ->set_name(get_name() + "_" + instance)
+ ->set_flops_amount(get_amount(instance))
+ ->set_host(disk_->get_host());
+ exec->start();
+ exec->on_this_completion_cb([this, instance](Exec const&) { complete(instance); });
+ store_activity(exec, instance);
+ } else {
+ auto io = Io::init()->set_name(get_name())->set_size(get_amount())->set_disk(disk_)->set_op_type(type_);
+ io->start();
+ io->on_this_completion_cb([this, instance](Io const&) { complete(instance); });
+ store_activity(io, instance);
+ }
}
} // namespace simgrid::s4u