quic/test_tools/simulator/link.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 "quic/test_tools/simulator/link.h"

 #include "absl/strings/str_cat.h"
 #include "absl/strings/str_format.h"
 #include "quic/test_tools/simulator/simulator.h"

 namespace quic {
 namespace simulator {

 // Parameters for random noise delay.
 const uint64_t kMaxRandomDelayUs = 10;

 OneWayLink::OneWayLink(Simulator* simulator,
                        std::string name,
                        UnconstrainedPortInterface* sink,
                        QuicBandwidth bandwidth,
                        QuicTime::Delta propagation_delay)
     : Actor(simulator, name),
       sink_(sink),
       bandwidth_(bandwidth),
       propagation_delay_(propagation_delay),
       next_write_at_(QuicTime::Zero()) {}

 OneWayLink::~OneWayLink() {}

 OneWayLink::QueuedPacket::QueuedPacket(std::unique_ptr<Packet> packet,
                                        QuicTime dequeue_time)
     : packet(std::move(packet)), dequeue_time(dequeue_time) {}

 OneWayLink::QueuedPacket::QueuedPacket(QueuedPacket&& other) = default;

 OneWayLink::QueuedPacket::~QueuedPacket() {}

 void OneWayLink::AcceptPacket(std::unique_ptr<Packet> packet) {
   QUICHE_DCHECK(TimeUntilAvailable().IsZero());
   QuicTime::Delta transfer_time = bandwidth_.TransferTime(packet->size);
   next_write_at_ = clock_->Now() + transfer_time;

   packets_in_transit_.emplace_back(
       std::move(packet),
       // Ensure that packets are delivered in order.
       std::max(
           next_write_at_ + propagation_delay_ + GetRandomDelay(transfer_time),
           packets_in_transit_.empty()
               ? QuicTime::Zero()
               : packets_in_transit_.back().dequeue_time));
   ScheduleNextPacketDeparture();
 }

 QuicTime::Delta OneWayLink::TimeUntilAvailable() {
   const QuicTime now = clock_->Now();
   if (next_write_at_ <= now) {
     return QuicTime::Delta::Zero();
   }

   return next_write_at_ - now;
 }

 void OneWayLink::Act() {
   QUICHE_DCHECK(!packets_in_transit_.empty());
   QUICHE_DCHECK(packets_in_transit_.front().dequeue_time >= clock_->Now());

   sink_->AcceptPacket(std::move(packets_in_transit_.front().packet));
   packets_in_transit_.pop_front();

   ScheduleNextPacketDeparture();
 }

 void OneWayLink::ScheduleNextPacketDeparture() {
   if (packets_in_transit_.empty()) {
     return;
   }

   Schedule(packets_in_transit_.front().dequeue_time);
 }

 QuicTime::Delta OneWayLink::GetRandomDelay(QuicTime::Delta transfer_time) {
   if (!simulator_->enable_random_delays()) {
     return QuicTime::Delta::Zero();
   }

   QuicTime::Delta delta = QuicTime::Delta::FromMicroseconds(
       simulator_->GetRandomGenerator()->RandUint64() % (kMaxRandomDelayUs + 1));
   // Have an upper bound on the delay to ensure packets do not go out of order.
   delta = std::min(delta, transfer_time * 0.5);
   return delta;
 }

 SymmetricLink::SymmetricLink(Simulator* simulator,
                              std::string name,
                              UnconstrainedPortInterface* sink_a,
                              UnconstrainedPortInterface* sink_b,
                              QuicBandwidth bandwidth,
                              QuicTime::Delta propagation_delay)
     : a_to_b_link_(simulator,
                    absl::StrCat(name, " (A-to-B)"),
                    sink_b,
                    bandwidth,
                    propagation_delay),
       b_to_a_link_(simulator,
                    absl::StrCat(name, " (B-to-A)"),
                    sink_a,
                    bandwidth,
                    propagation_delay) {}

 SymmetricLink::SymmetricLink(Endpoint* endpoint_a,
                              Endpoint* endpoint_b,
                              QuicBandwidth bandwidth,
                              QuicTime::Delta propagation_delay)
     : SymmetricLink(endpoint_a->simulator(),
                     absl::StrFormat("Link [%s]<->[%s]",
                                     endpoint_a->name(),
                                     endpoint_b->name()),
                     endpoint_a->GetRxPort(),
                     endpoint_b->GetRxPort(),
                     bandwidth,
                     propagation_delay) {
   endpoint_a->SetTxPort(&a_to_b_link_);
   endpoint_b->SetTxPort(&b_to_a_link_);
 }

 }  // 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 "quic/test_tools/simulator/link.h"

	#include "absl/strings/str_cat.h"
	#include "absl/strings/str_format.h"
	#include "quic/test_tools/simulator/simulator.h"

	namespace quic {
	namespace simulator {

	// Parameters for random noise delay.
	const uint64_t kMaxRandomDelayUs = 10;

	OneWayLink::OneWayLink(Simulator* simulator,
	std::string name,
	UnconstrainedPortInterface* sink,
	QuicBandwidth bandwidth,
	QuicTime::Delta propagation_delay)
	: Actor(simulator, name),
	sink_(sink),
	bandwidth_(bandwidth),
	propagation_delay_(propagation_delay),
	next_write_at_(QuicTime::Zero()) {}

	OneWayLink::~OneWayLink() {}

	OneWayLink::QueuedPacket::QueuedPacket(std::unique_ptr<Packet> packet,
	QuicTime dequeue_time)
	: packet(std::move(packet)), dequeue_time(dequeue_time) {}

	OneWayLink::QueuedPacket::QueuedPacket(QueuedPacket&& other) = default;

	OneWayLink::QueuedPacket::~QueuedPacket() {}

	void OneWayLink::AcceptPacket(std::unique_ptr<Packet> packet) {
	QUICHE_DCHECK(TimeUntilAvailable().IsZero());
	QuicTime::Delta transfer_time = bandwidth_.TransferTime(packet->size);
	next_write_at_ = clock_->Now() + transfer_time;

	packets_in_transit_.emplace_back(
	std::move(packet),
	// Ensure that packets are delivered in order.
	std::max(
	next_write_at_ + propagation_delay_ + GetRandomDelay(transfer_time),
	packets_in_transit_.empty()
	? QuicTime::Zero()
	: packets_in_transit_.back().dequeue_time));
	ScheduleNextPacketDeparture();
	}

	QuicTime::Delta OneWayLink::TimeUntilAvailable() {
	const QuicTime now = clock_->Now();
	if (next_write_at_ <= now) {
	return QuicTime::Delta::Zero();
	}

	return next_write_at_ - now;
	}

	void OneWayLink::Act() {
	QUICHE_DCHECK(!packets_in_transit_.empty());
	QUICHE_DCHECK(packets_in_transit_.front().dequeue_time >= clock_->Now());

	sink_->AcceptPacket(std::move(packets_in_transit_.front().packet));
	packets_in_transit_.pop_front();

	ScheduleNextPacketDeparture();
	}

	void OneWayLink::ScheduleNextPacketDeparture() {
	if (packets_in_transit_.empty()) {
	return;
	}

	Schedule(packets_in_transit_.front().dequeue_time);
	}

	QuicTime::Delta OneWayLink::GetRandomDelay(QuicTime::Delta transfer_time) {
	if (!simulator_->enable_random_delays()) {
	return QuicTime::Delta::Zero();
	}

	QuicTime::Delta delta = QuicTime::Delta::FromMicroseconds(
	simulator_->GetRandomGenerator()->RandUint64() % (kMaxRandomDelayUs + 1));
	// Have an upper bound on the delay to ensure packets do not go out of order.
	delta = std::min(delta, transfer_time * 0.5);
	return delta;
	}

	SymmetricLink::SymmetricLink(Simulator* simulator,
	std::string name,
	UnconstrainedPortInterface* sink_a,
	UnconstrainedPortInterface* sink_b,
	QuicBandwidth bandwidth,
	QuicTime::Delta propagation_delay)
	: a_to_b_link_(simulator,
	absl::StrCat(name, " (A-to-B)"),
	sink_b,
	bandwidth,
	propagation_delay),
	b_to_a_link_(simulator,
	absl::StrCat(name, " (B-to-A)"),
	sink_a,
	bandwidth,
	propagation_delay) {}

	SymmetricLink::SymmetricLink(Endpoint* endpoint_a,
	Endpoint* endpoint_b,
	QuicBandwidth bandwidth,
	QuicTime::Delta propagation_delay)
	: SymmetricLink(endpoint_a->simulator(),
	absl::StrFormat("Link [%s]<->[%s]",
	endpoint_a->name(),
	endpoint_b->name()),
	endpoint_a->GetRxPort(),
	endpoint_b->GetRxPort(),
	bandwidth,
	propagation_delay) {
	endpoint_a->SetTxPort(&a_to_b_link_);
	endpoint_b->SetTxPort(&b_to_a_link_);
	}

	} // namespace simulator
	} // namespace quic