test/scenario/network/network_emulation_manager.cc - src - Git at Google

 /*
  *  Copyright (c) 2019 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "test/scenario/network/network_emulation_manager.h"

 #include <algorithm>
 #include <memory>

 #include "absl/memory/memory.h"
 #include "api/units/time_delta.h"
 #include "api/units/timestamp.h"
 #include "rtc_base/fake_network.h"

 namespace webrtc {
 namespace test {
 namespace {

 constexpr int64_t kPacketProcessingIntervalMs = 1;
 // uint32_t representation of 192.168.0.0 address
 constexpr uint32_t kMinIPv4Address = 0xC0A80000;
 // uint32_t representation of 192.168.255.255 address
 constexpr uint32_t kMaxIPv4Address = 0xC0A8FFFF;

 }  // namespace

 NetworkEmulationManagerImpl::NetworkEmulationManagerImpl()
     : clock_(Clock::GetRealTimeClock()),
       next_node_id_(1),
       next_ip4_address_(kMinIPv4Address),
       task_queue_("network_emulation_manager") {
   process_task_handle_ = RepeatingTaskHandle::Start(task_queue_.Get(), [this] {
     ProcessNetworkPackets();
     return TimeDelta::ms(kPacketProcessingIntervalMs);
   });
 }

 // TODO(srte): Ensure that any pending task that must be run for consistency
 // (such as stats collection tasks) are not cancelled when the task queue is
 // destroyed.
 NetworkEmulationManagerImpl::~NetworkEmulationManagerImpl() = default;

 EmulatedNetworkNode* NetworkEmulationManagerImpl::CreateEmulatedNode(
     std::unique_ptr<NetworkBehaviorInterface> network_behavior) {
   auto node = absl::make_unique<EmulatedNetworkNode>(
       clock_, &task_queue_, std::move(network_behavior));
   EmulatedNetworkNode* out = node.get();

   struct Closure {
     void operator()() { manager->network_nodes_.push_back(std::move(node)); }
     NetworkEmulationManagerImpl* manager;
     std::unique_ptr<EmulatedNetworkNode> node;
   };
   task_queue_.PostTask(Closure{this, std::move(node)});
   return out;
 }

 EmulatedEndpoint* NetworkEmulationManagerImpl::CreateEndpoint(
     EmulatedEndpointConfig config) {
   absl::optional<rtc::IPAddress> ip = config.ip;
   if (!ip) {
     switch (config.generated_ip_family) {
       case EmulatedEndpointConfig::IpAddressFamily::kIpv4:
         ip = GetNextIPv4Address();
         RTC_CHECK(ip) << "All auto generated IPv4 addresses exhausted";
         break;
       case EmulatedEndpointConfig::IpAddressFamily::kIpv6:
         ip = GetNextIPv4Address();
         RTC_CHECK(ip) << "All auto generated IPv6 addresses exhausted";
         ip = ip->AsIPv6Address();
         break;
     }
   }

   bool res = used_ip_addresses_.insert(*ip).second;
   RTC_CHECK(res) << "IP=" << ip->ToString() << " already in use";
   auto node = absl::make_unique<EmulatedEndpoint>(
       next_node_id_++, *ip, config.start_as_enabled, &task_queue_, clock_);
   EmulatedEndpoint* out = node.get();
   endpoints_.push_back(std::move(node));
   return out;
 }

 void NetworkEmulationManagerImpl::EnableEndpoint(EmulatedEndpoint* endpoint) {
   EmulatedNetworkManager* network_manager =
       endpoint_to_network_manager_[endpoint];
   RTC_CHECK(network_manager);
   network_manager->EnableEndpoint(endpoint);
 }

 void NetworkEmulationManagerImpl::DisableEndpoint(EmulatedEndpoint* endpoint) {
   EmulatedNetworkManager* network_manager =
       endpoint_to_network_manager_[endpoint];
   RTC_CHECK(network_manager);
   network_manager->DisableEndpoint(endpoint);
 }

 EmulatedRoute* NetworkEmulationManagerImpl::CreateRoute(
     EmulatedEndpoint* from,
     const std::vector<EmulatedNetworkNode*>& via_nodes,
     EmulatedEndpoint* to) {
   // Because endpoint has no send node by default at least one should be
   // provided here.
   RTC_CHECK(!via_nodes.empty());

   from->router()->SetReceiver(to->GetPeerLocalAddress(), via_nodes[0]);
   EmulatedNetworkNode* cur_node = via_nodes[0];
   for (size_t i = 1; i < via_nodes.size(); ++i) {
     cur_node->router()->SetReceiver(to->GetPeerLocalAddress(), via_nodes[i]);
     cur_node = via_nodes[i];
   }
   cur_node->router()->SetReceiver(to->GetPeerLocalAddress(), to);

   std::unique_ptr<EmulatedRoute> route =
       absl::make_unique<EmulatedRoute>(from, std::move(via_nodes), to);
   EmulatedRoute* out = route.get();
   routes_.push_back(std::move(route));
   return out;
 }

 void NetworkEmulationManagerImpl::ClearRoute(EmulatedRoute* route) {
   RTC_CHECK(route->active) << "Route already cleared";
   task_queue_.SendTask([route]() {
     // Remove receiver from intermediate nodes.
     for (auto* node : route->via_nodes) {
       node->router()->RemoveReceiver(route->to->GetPeerLocalAddress());
     }
     // Remove destination endpoint from source endpoint's router.
     route->from->router()->RemoveReceiver(route->to->GetPeerLocalAddress());

     route->active = false;
   });
 }

 TrafficRoute* NetworkEmulationManagerImpl::CreateTrafficRoute(
     const std::vector<EmulatedNetworkNode*>& via_nodes) {
   RTC_CHECK(!via_nodes.empty());
   EmulatedEndpoint* endpoint = CreateEndpoint(EmulatedEndpointConfig());

   // Setup a route via specified nodes.
   EmulatedNetworkNode* cur_node = via_nodes[0];
   for (size_t i = 1; i < via_nodes.size(); ++i) {
     cur_node->router()->SetReceiver(endpoint->GetPeerLocalAddress(),
                                     via_nodes[i]);
     cur_node = via_nodes[i];
   }
   cur_node->router()->SetReceiver(endpoint->GetPeerLocalAddress(), endpoint);

   std::unique_ptr<TrafficRoute> traffic_route =
       absl::make_unique<TrafficRoute>(clock_, via_nodes[0], endpoint);
   TrafficRoute* out = traffic_route.get();
   traffic_routes_.push_back(std::move(traffic_route));
   return out;
 }

 RandomWalkCrossTraffic*
 NetworkEmulationManagerImpl::CreateRandomWalkCrossTraffic(
     TrafficRoute* traffic_route,
     RandomWalkConfig config) {
   auto traffic = absl::make_unique<RandomWalkCrossTraffic>(std::move(config),
                                                            traffic_route);
   RandomWalkCrossTraffic* out = traffic.get();
   struct Closure {
     void operator()() {
       manager->random_cross_traffics_.push_back(std::move(traffic));
     }
     NetworkEmulationManagerImpl* manager;
     std::unique_ptr<RandomWalkCrossTraffic> traffic;
   };
   task_queue_.PostTask(Closure{this, std::move(traffic)});
   return out;
 }

 PulsedPeaksCrossTraffic*
 NetworkEmulationManagerImpl::CreatePulsedPeaksCrossTraffic(
     TrafficRoute* traffic_route,
     PulsedPeaksConfig config) {
   auto traffic = absl::make_unique<PulsedPeaksCrossTraffic>(std::move(config),
                                                             traffic_route);
   PulsedPeaksCrossTraffic* out = traffic.get();
   struct Closure {
     void operator()() {
       manager->pulsed_cross_traffics_.push_back(std::move(traffic));
     }
     NetworkEmulationManagerImpl* manager;
     std::unique_ptr<PulsedPeaksCrossTraffic> traffic;
   };
   task_queue_.PostTask(Closure{this, std::move(traffic)});
   return out;
 }

 EmulatedNetworkManagerInterface*
 NetworkEmulationManagerImpl::CreateEmulatedNetworkManagerInterface(
     const std::vector<EmulatedEndpoint*>& endpoints) {
   auto endpoints_container = absl::make_unique<EndpointsContainer>(endpoints);
   auto network_manager = absl::make_unique<EmulatedNetworkManager>(
       clock_, endpoints_container.get());
   for (auto* endpoint : endpoints) {
     // Associate endpoint with network manager.
     bool insertion_result =
         endpoint_to_network_manager_.insert({endpoint, network_manager.get()})
             .second;
     RTC_CHECK(insertion_result)
         << "Endpoint ip=" << endpoint->GetPeerLocalAddress().ToString()
         << " is already used for another network";
   }

   EmulatedNetworkManagerInterface* out = network_manager.get();

   endpoints_containers_.push_back(std::move(endpoints_container));
   network_managers_.push_back(std::move(network_manager));
   return out;
 }

 absl::optional<rtc::IPAddress>
 NetworkEmulationManagerImpl::GetNextIPv4Address() {
   uint32_t addresses_count = kMaxIPv4Address - kMinIPv4Address;
   for (uint32_t i = 0; i < addresses_count; i++) {
     rtc::IPAddress ip(next_ip4_address_);
     if (next_ip4_address_ == kMaxIPv4Address) {
       next_ip4_address_ = kMinIPv4Address;
     } else {
       next_ip4_address_++;
     }
     if (used_ip_addresses_.find(ip) == used_ip_addresses_.end()) {
       return ip;
     }
   }
   return absl::nullopt;
 }

 void NetworkEmulationManagerImpl::ProcessNetworkPackets() {
   Timestamp current_time = Now();
   for (auto& traffic : random_cross_traffics_) {
     traffic->Process(current_time);
   }
   for (auto& traffic : pulsed_cross_traffics_) {
     traffic->Process(current_time);
   }
 }

 Timestamp NetworkEmulationManagerImpl::Now() const {
   return Timestamp::us(clock_->TimeInMicroseconds());
 }

 }  // namespace test
 }  // namespace webrtc
	/*
	* Copyright (c) 2019 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "test/scenario/network/network_emulation_manager.h"

	#include <algorithm>
	#include <memory>

	#include "absl/memory/memory.h"
	#include "api/units/time_delta.h"
	#include "api/units/timestamp.h"
	#include "rtc_base/fake_network.h"

	namespace webrtc {
	namespace test {
	namespace {

	constexpr int64_t kPacketProcessingIntervalMs = 1;
	// uint32_t representation of 192.168.0.0 address
	constexpr uint32_t kMinIPv4Address = 0xC0A80000;
	// uint32_t representation of 192.168.255.255 address
	constexpr uint32_t kMaxIPv4Address = 0xC0A8FFFF;

	} // namespace

	NetworkEmulationManagerImpl::NetworkEmulationManagerImpl()
	: clock_(Clock::GetRealTimeClock()),
	next_node_id_(1),
	next_ip4_address_(kMinIPv4Address),
	task_queue_("network_emulation_manager") {
	process_task_handle_ = RepeatingTaskHandle::Start(task_queue_.Get(), [this] {
	ProcessNetworkPackets();
	return TimeDelta::ms(kPacketProcessingIntervalMs);
	});
	}

	// TODO(srte): Ensure that any pending task that must be run for consistency
	// (such as stats collection tasks) are not cancelled when the task queue is
	// destroyed.
	NetworkEmulationManagerImpl::~NetworkEmulationManagerImpl() = default;

	EmulatedNetworkNode* NetworkEmulationManagerImpl::CreateEmulatedNode(
	std::unique_ptr<NetworkBehaviorInterface> network_behavior) {
	auto node = absl::make_unique<EmulatedNetworkNode>(
	clock_, &task_queue_, std::move(network_behavior));
	EmulatedNetworkNode* out = node.get();

	struct Closure {
	void operator()() { manager->network_nodes_.push_back(std::move(node)); }
	NetworkEmulationManagerImpl* manager;
	std::unique_ptr<EmulatedNetworkNode> node;
	};
	task_queue_.PostTask(Closure{this, std::move(node)});
	return out;
	}

	EmulatedEndpoint* NetworkEmulationManagerImpl::CreateEndpoint(
	EmulatedEndpointConfig config) {
	absl::optional<rtc::IPAddress> ip = config.ip;
	if (!ip) {
	switch (config.generated_ip_family) {
	case EmulatedEndpointConfig::IpAddressFamily::kIpv4:
	ip = GetNextIPv4Address();
	RTC_CHECK(ip) << "All auto generated IPv4 addresses exhausted";
	break;
	case EmulatedEndpointConfig::IpAddressFamily::kIpv6:
	ip = GetNextIPv4Address();
	RTC_CHECK(ip) << "All auto generated IPv6 addresses exhausted";
	ip = ip->AsIPv6Address();
	break;
	}
	}

	bool res = used_ip_addresses_.insert(*ip).second;
	RTC_CHECK(res) << "IP=" << ip->ToString() << " already in use";
	auto node = absl::make_unique<EmulatedEndpoint>(
	next_node_id_++, *ip, config.start_as_enabled, &task_queue_, clock_);
	EmulatedEndpoint* out = node.get();
	endpoints_.push_back(std::move(node));
	return out;
	}

	void NetworkEmulationManagerImpl::EnableEndpoint(EmulatedEndpoint* endpoint) {
	EmulatedNetworkManager* network_manager =
	endpoint_to_network_manager_[endpoint];
	RTC_CHECK(network_manager);
	network_manager->EnableEndpoint(endpoint);
	}

	void NetworkEmulationManagerImpl::DisableEndpoint(EmulatedEndpoint* endpoint) {
	EmulatedNetworkManager* network_manager =
	endpoint_to_network_manager_[endpoint];
	RTC_CHECK(network_manager);
	network_manager->DisableEndpoint(endpoint);
	}

	EmulatedRoute* NetworkEmulationManagerImpl::CreateRoute(
	EmulatedEndpoint* from,
	const std::vector<EmulatedNetworkNode*>& via_nodes,
	EmulatedEndpoint* to) {
	// Because endpoint has no send node by default at least one should be
	// provided here.
	RTC_CHECK(!via_nodes.empty());

	from->router()->SetReceiver(to->GetPeerLocalAddress(), via_nodes[0]);
	EmulatedNetworkNode* cur_node = via_nodes[0];
	for (size_t i = 1; i < via_nodes.size(); ++i) {
	cur_node->router()->SetReceiver(to->GetPeerLocalAddress(), via_nodes[i]);
	cur_node = via_nodes[i];
	}
	cur_node->router()->SetReceiver(to->GetPeerLocalAddress(), to);

	std::unique_ptr<EmulatedRoute> route =
	absl::make_unique<EmulatedRoute>(from, std::move(via_nodes), to);
	EmulatedRoute* out = route.get();
	routes_.push_back(std::move(route));
	return out;
	}

	void NetworkEmulationManagerImpl::ClearRoute(EmulatedRoute* route) {
	RTC_CHECK(route->active) << "Route already cleared";
	task_queue_.SendTask([route]() {
	// Remove receiver from intermediate nodes.
	for (auto* node : route->via_nodes) {
	node->router()->RemoveReceiver(route->to->GetPeerLocalAddress());
	}
	// Remove destination endpoint from source endpoint's router.
	route->from->router()->RemoveReceiver(route->to->GetPeerLocalAddress());

	route->active = false;
	});
	}

	TrafficRoute* NetworkEmulationManagerImpl::CreateTrafficRoute(
	const std::vector<EmulatedNetworkNode*>& via_nodes) {
	RTC_CHECK(!via_nodes.empty());
	EmulatedEndpoint* endpoint = CreateEndpoint(EmulatedEndpointConfig());

	// Setup a route via specified nodes.
	EmulatedNetworkNode* cur_node = via_nodes[0];
	for (size_t i = 1; i < via_nodes.size(); ++i) {
	cur_node->router()->SetReceiver(endpoint->GetPeerLocalAddress(),
	via_nodes[i]);
	cur_node = via_nodes[i];
	}
	cur_node->router()->SetReceiver(endpoint->GetPeerLocalAddress(), endpoint);

	std::unique_ptr<TrafficRoute> traffic_route =
	absl::make_unique<TrafficRoute>(clock_, via_nodes[0], endpoint);
	TrafficRoute* out = traffic_route.get();
	traffic_routes_.push_back(std::move(traffic_route));
	return out;
	}

	RandomWalkCrossTraffic*
	NetworkEmulationManagerImpl::CreateRandomWalkCrossTraffic(
	TrafficRoute* traffic_route,
	RandomWalkConfig config) {
	auto traffic = absl::make_unique<RandomWalkCrossTraffic>(std::move(config),
	traffic_route);
	RandomWalkCrossTraffic* out = traffic.get();
	struct Closure {
	void operator()() {
	manager->random_cross_traffics_.push_back(std::move(traffic));
	}
	NetworkEmulationManagerImpl* manager;
	std::unique_ptr<RandomWalkCrossTraffic> traffic;
	};
	task_queue_.PostTask(Closure{this, std::move(traffic)});
	return out;
	}

	PulsedPeaksCrossTraffic*
	NetworkEmulationManagerImpl::CreatePulsedPeaksCrossTraffic(
	TrafficRoute* traffic_route,
	PulsedPeaksConfig config) {
	auto traffic = absl::make_unique<PulsedPeaksCrossTraffic>(std::move(config),
	traffic_route);
	PulsedPeaksCrossTraffic* out = traffic.get();
	struct Closure {
	void operator()() {
	manager->pulsed_cross_traffics_.push_back(std::move(traffic));
	}
	NetworkEmulationManagerImpl* manager;
	std::unique_ptr<PulsedPeaksCrossTraffic> traffic;
	};
	task_queue_.PostTask(Closure{this, std::move(traffic)});
	return out;
	}

	EmulatedNetworkManagerInterface*
	NetworkEmulationManagerImpl::CreateEmulatedNetworkManagerInterface(
	const std::vector<EmulatedEndpoint*>& endpoints) {
	auto endpoints_container = absl::make_unique<EndpointsContainer>(endpoints);
	auto network_manager = absl::make_unique<EmulatedNetworkManager>(
	clock_, endpoints_container.get());
	for (auto* endpoint : endpoints) {
	// Associate endpoint with network manager.
	bool insertion_result =
	endpoint_to_network_manager_.insert({endpoint, network_manager.get()})
	.second;
	RTC_CHECK(insertion_result)
	<< "Endpoint ip=" << endpoint->GetPeerLocalAddress().ToString()
	<< " is already used for another network";
	}

	EmulatedNetworkManagerInterface* out = network_manager.get();

	endpoints_containers_.push_back(std::move(endpoints_container));
	network_managers_.push_back(std::move(network_manager));
	return out;
	}

	absl::optional<rtc::IPAddress>
	NetworkEmulationManagerImpl::GetNextIPv4Address() {
	uint32_t addresses_count = kMaxIPv4Address - kMinIPv4Address;
	for (uint32_t i = 0; i < addresses_count; i++) {
	rtc::IPAddress ip(next_ip4_address_);
	if (next_ip4_address_ == kMaxIPv4Address) {
	next_ip4_address_ = kMinIPv4Address;
	} else {
	next_ip4_address_++;
	}
	if (used_ip_addresses_.find(ip) == used_ip_addresses_.end()) {
	return ip;
	}
	}
	return absl::nullopt;
	}

	void NetworkEmulationManagerImpl::ProcessNetworkPackets() {
	Timestamp current_time = Now();
	for (auto& traffic : random_cross_traffics_) {
	traffic->Process(current_time);
	}
	for (auto& traffic : pulsed_cross_traffics_) {
	traffic->Process(current_time);
	}
	}

	Timestamp NetworkEmulationManagerImpl::Now() const {
	return Timestamp::us(clock_->TimeInMicroseconds());
	}

	} // namespace test
	} // namespace webrtc