quic/test_tools/simulator/simulator.cc - quiche - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "net/third_party/quiche/src/quic/test_tools/simulator/simulator.h"

 #include "net/third_party/quiche/src/quic/core/crypto/quic_random.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_logging.h"

 namespace quic {
 namespace simulator {

 Simulator::Simulator()
     : random_generator_(nullptr),
       alarm_factory_(this, "Default Alarm Manager"),
       run_for_should_stop_(false),
       enable_random_delays_(false) {
   run_for_alarm_.reset(
       alarm_factory_.CreateAlarm(new RunForDelegate(&run_for_should_stop_)));
 }

 Simulator::~Simulator() {
   // Ensure that Actor under run_for_alarm_ is removed before Simulator data
   // structures are destructed.
   run_for_alarm_.reset();
 }

 Simulator::Clock::Clock() : now_(kStartTime) {}

 QuicTime Simulator::Clock::ApproximateNow() const {
   return now_;
 }

 QuicTime Simulator::Clock::Now() const {
   return now_;
 }

 QuicWallTime Simulator::Clock::WallNow() const {
   return QuicWallTime::FromUNIXMicroseconds(
       (now_ - QuicTime::Zero()).ToMicroseconds());
 }

 void Simulator::AddActor(Actor* actor) {
   auto emplace_times_result =
       scheduled_times_.insert(std::make_pair(actor, QuicTime::Infinite()));
   auto emplace_names_result = actor_names_.insert(actor->name());

   // Ensure that the object was actually placed into the map.
   DCHECK(emplace_times_result.second);
   DCHECK(emplace_names_result.second);
 }

 void Simulator::RemoveActor(Actor* actor) {
   auto scheduled_time_it = scheduled_times_.find(actor);
   auto actor_names_it = actor_names_.find(actor->name());
   DCHECK(scheduled_time_it != scheduled_times_.end());
   DCHECK(actor_names_it != actor_names_.end());

   QuicTime scheduled_time = scheduled_time_it->second;
   if (scheduled_time != QuicTime::Infinite()) {
     Unschedule(actor);
   }

   scheduled_times_.erase(scheduled_time_it);
   actor_names_.erase(actor_names_it);
 }

 void Simulator::Schedule(Actor* actor, QuicTime new_time) {
   auto scheduled_time_it = scheduled_times_.find(actor);
   DCHECK(scheduled_time_it != scheduled_times_.end());
   QuicTime scheduled_time = scheduled_time_it->second;

   if (scheduled_time <= new_time) {
     return;
   }

   if (scheduled_time != QuicTime::Infinite()) {
     Unschedule(actor);
   }

   scheduled_time_it->second = new_time;
   schedule_.insert(std::make_pair(new_time, actor));
 }

 void Simulator::Unschedule(Actor* actor) {
   auto scheduled_time_it = scheduled_times_.find(actor);
   DCHECK(scheduled_time_it != scheduled_times_.end());
   QuicTime scheduled_time = scheduled_time_it->second;

   DCHECK(scheduled_time != QuicTime::Infinite());
   auto range = schedule_.equal_range(scheduled_time);
   for (auto it = range.first; it != range.second; ++it) {
     if (it->second == actor) {
       schedule_.erase(it);
       scheduled_time_it->second = QuicTime::Infinite();
       return;
     }
   }
   DCHECK(false);
 }

 const QuicClock* Simulator::GetClock() const {
   return &clock_;
 }

 QuicRandom* Simulator::GetRandomGenerator() {
   if (random_generator_ == nullptr) {
     random_generator_ = QuicRandom::GetInstance();
   }

   return random_generator_;
 }

 QuicBufferAllocator* Simulator::GetStreamSendBufferAllocator() {
   return &buffer_allocator_;
 }

 QuicAlarmFactory* Simulator::GetAlarmFactory() {
   return &alarm_factory_;
 }

 Simulator::RunForDelegate::RunForDelegate(bool* run_for_should_stop)
     : run_for_should_stop_(run_for_should_stop) {}

 void Simulator::RunForDelegate::OnAlarm() {
   *run_for_should_stop_ = true;
 }

 void Simulator::RunFor(QuicTime::Delta time_span) {
   DCHECK(!run_for_alarm_->IsSet());

   // RunFor() ensures that the simulation stops at the exact time specified by
   // scheduling an alarm at that point and using that alarm to abort the
   // simulation.  An alarm is necessary because otherwise it is possible that
   // nothing is scheduled at |end_time|, so the simulation will either go
   // further than requested or stop before reaching |end_time|.
   const QuicTime end_time = clock_.Now() + time_span;
   run_for_alarm_->Set(end_time);
   run_for_should_stop_ = false;
   bool simulation_result = RunUntil([this]() { return run_for_should_stop_; });

   DCHECK(simulation_result);
   DCHECK(clock_.Now() == end_time);
 }

 void Simulator::HandleNextScheduledActor() {
   const auto current_event_it = schedule_.begin();
   QuicTime event_time = current_event_it->first;
   Actor* actor = current_event_it->second;
   QUIC_DVLOG(3) << "At t = " << event_time.ToDebuggingValue() << ", calling "
                 << actor->name();

   Unschedule(actor);

   if (clock_.Now() > event_time) {
     QUIC_BUG << "Error: event registered by [" << actor->name()
              << "] requires travelling back in time.  Current time: "
              << clock_.Now().ToDebuggingValue()
              << ", scheduled time: " << event_time.ToDebuggingValue();
   }
   clock_.now_ = event_time;

   actor->Act();
 }

 }  // namespace simulator
 }  // namespace quic
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "net/third_party/quiche/src/quic/test_tools/simulator/simulator.h"

	#include "net/third_party/quiche/src/quic/core/crypto/quic_random.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_logging.h"

	namespace quic {
	namespace simulator {

	Simulator::Simulator()
	: random_generator_(nullptr),
	alarm_factory_(this, "Default Alarm Manager"),
	run_for_should_stop_(false),
	enable_random_delays_(false) {
	run_for_alarm_.reset(
	alarm_factory_.CreateAlarm(new RunForDelegate(&run_for_should_stop_)));
	}

	Simulator::~Simulator() {
	// Ensure that Actor under run_for_alarm_ is removed before Simulator data
	// structures are destructed.
	run_for_alarm_.reset();
	}

	Simulator::Clock::Clock() : now_(kStartTime) {}

	QuicTime Simulator::Clock::ApproximateNow() const {
	return now_;
	}

	QuicTime Simulator::Clock::Now() const {
	return now_;
	}

	QuicWallTime Simulator::Clock::WallNow() const {
	return QuicWallTime::FromUNIXMicroseconds(
	(now_ - QuicTime::Zero()).ToMicroseconds());
	}

	void Simulator::AddActor(Actor* actor) {
	auto emplace_times_result =
	scheduled_times_.insert(std::make_pair(actor, QuicTime::Infinite()));
	auto emplace_names_result = actor_names_.insert(actor->name());

	// Ensure that the object was actually placed into the map.
	DCHECK(emplace_times_result.second);
	DCHECK(emplace_names_result.second);
	}

	void Simulator::RemoveActor(Actor* actor) {
	auto scheduled_time_it = scheduled_times_.find(actor);
	auto actor_names_it = actor_names_.find(actor->name());
	DCHECK(scheduled_time_it != scheduled_times_.end());
	DCHECK(actor_names_it != actor_names_.end());

	QuicTime scheduled_time = scheduled_time_it->second;
	if (scheduled_time != QuicTime::Infinite()) {
	Unschedule(actor);
	}

	scheduled_times_.erase(scheduled_time_it);
	actor_names_.erase(actor_names_it);
	}

	void Simulator::Schedule(Actor* actor, QuicTime new_time) {
	auto scheduled_time_it = scheduled_times_.find(actor);
	DCHECK(scheduled_time_it != scheduled_times_.end());
	QuicTime scheduled_time = scheduled_time_it->second;

	if (scheduled_time <= new_time) {
	return;
	}

	if (scheduled_time != QuicTime::Infinite()) {
	Unschedule(actor);
	}

	scheduled_time_it->second = new_time;
	schedule_.insert(std::make_pair(new_time, actor));
	}

	void Simulator::Unschedule(Actor* actor) {
	auto scheduled_time_it = scheduled_times_.find(actor);
	DCHECK(scheduled_time_it != scheduled_times_.end());
	QuicTime scheduled_time = scheduled_time_it->second;

	DCHECK(scheduled_time != QuicTime::Infinite());
	auto range = schedule_.equal_range(scheduled_time);
	for (auto it = range.first; it != range.second; ++it) {
	if (it->second == actor) {
	schedule_.erase(it);
	scheduled_time_it->second = QuicTime::Infinite();
	return;
	}
	}
	DCHECK(false);
	}

	const QuicClock* Simulator::GetClock() const {
	return &clock_;
	}

	QuicRandom* Simulator::GetRandomGenerator() {
	if (random_generator_ == nullptr) {
	random_generator_ = QuicRandom::GetInstance();
	}

	return random_generator_;
	}

	QuicBufferAllocator* Simulator::GetStreamSendBufferAllocator() {
	return &buffer_allocator_;
	}

	QuicAlarmFactory* Simulator::GetAlarmFactory() {
	return &alarm_factory_;
	}

	Simulator::RunForDelegate::RunForDelegate(bool* run_for_should_stop)
	: run_for_should_stop_(run_for_should_stop) {}

	void Simulator::RunForDelegate::OnAlarm() {
	*run_for_should_stop_ = true;
	}

	void Simulator::RunFor(QuicTime::Delta time_span) {
	DCHECK(!run_for_alarm_->IsSet());

	// RunFor() ensures that the simulation stops at the exact time specified by
	// scheduling an alarm at that point and using that alarm to abort the
	// simulation. An alarm is necessary because otherwise it is possible that
	// nothing is scheduled at \|end_time\|, so the simulation will either go
	// further than requested or stop before reaching \|end_time\|.
	const QuicTime end_time = clock_.Now() + time_span;
	run_for_alarm_->Set(end_time);
	run_for_should_stop_ = false;
	bool simulation_result = RunUntil([this]() { return run_for_should_stop_; });

	DCHECK(simulation_result);
	DCHECK(clock_.Now() == end_time);
	}

	void Simulator::HandleNextScheduledActor() {
	const auto current_event_it = schedule_.begin();
	QuicTime event_time = current_event_it->first;
	Actor* actor = current_event_it->second;
	QUIC_DVLOG(3) << "At t = " << event_time.ToDebuggingValue() << ", calling "
	<< actor->name();

	Unschedule(actor);

	if (clock_.Now() > event_time) {
	QUIC_BUG << "Error: event registered by [" << actor->name()
	<< "] requires travelling back in time. Current time: "
	<< clock_.Now().ToDebuggingValue()
	<< ", scheduled time: " << event_time.ToDebuggingValue();
	}
	clock_.now_ = event_time;

	actor->Act();
	}

	} // namespace simulator
	} // namespace quic