quic/test_tools/simulator/quic_endpoint_base.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/quic_endpoint_base.h"

 #include <memory>
 #include <utility>

 #include "absl/strings/str_cat.h"
 #include "quic/core/crypto/crypto_handshake_message.h"
 #include "quic/core/crypto/crypto_protocol.h"
 #include "quic/core/quic_connection.h"
 #include "quic/core/quic_data_writer.h"
 #include "quic/platform/api/quic_test_output.h"
 #include "quic/test_tools/quic_connection_peer.h"
 #include "quic/test_tools/quic_test_utils.h"
 #include "quic/test_tools/simulator/simulator.h"

 namespace quic {
 namespace simulator {

 // Takes a SHA-1 hash of the name and converts it into five 32-bit integers.
 static std::vector<uint32_t> HashNameIntoFive32BitIntegers(std::string name) {
   const std::string hash = test::Sha1Hash(name);

   std::vector<uint32_t> output;
   uint32_t current_number = 0;
   for (size_t i = 0; i < hash.size(); i++) {
     current_number = (current_number << 8) + hash[i];
     if (i % 4 == 3) {
       output.push_back(i);
       current_number = 0;
     }
   }

   return output;
 }

 QuicSocketAddress GetAddressFromName(std::string name) {
   const std::vector<uint32_t> hash = HashNameIntoFive32BitIntegers(name);

   // Generate a random port between 1025 and 65535.
   const uint16_t port = 1025 + hash[0] % (65535 - 1025 + 1);

   // Generate a random 10.x.x.x address, where x is between 1 and 254.
   std::string ip_address{"\xa\0\0\0", 4};
   for (size_t i = 1; i < 4; i++) {
     ip_address[i] = 1 + hash[i] % 254;
   }
   QuicIpAddress host;
   host.FromPackedString(ip_address.c_str(), ip_address.length());
   return QuicSocketAddress(host, port);
 }

 QuicEndpointBase::QuicEndpointBase(Simulator* simulator,
                                    std::string name,
                                    std::string peer_name)
     : Endpoint(simulator, name),
       peer_name_(peer_name),
       writer_(this),
       nic_tx_queue_(simulator,
                     absl::StrCat(name, " (TX Queue)"),
                     kMaxOutgoingPacketSize * kTxQueueSize),
       connection_(nullptr),
       write_blocked_count_(0),
       drop_next_packet_(false) {
   nic_tx_queue_.set_listener_interface(this);
 }

 QuicEndpointBase::~QuicEndpointBase() {
   if (trace_visitor_ != nullptr) {
     const char* perspective_prefix =
         connection_->perspective() == Perspective::IS_CLIENT ? "C" : "S";

     std::string identifier = absl::StrCat(
         perspective_prefix, connection_->connection_id().ToString());
     QuicRecordTrace(identifier, trace_visitor_->trace()->SerializeAsString());
   }
 }

 void QuicEndpointBase::DropNextIncomingPacket() {
   drop_next_packet_ = true;
 }

 void QuicEndpointBase::RecordTrace() {
   trace_visitor_ = std::make_unique<QuicTraceVisitor>(connection_.get());
   connection_->set_debug_visitor(trace_visitor_.get());
 }

 void QuicEndpointBase::AcceptPacket(std::unique_ptr<Packet> packet) {
   if (packet->destination != name_) {
     return;
   }
   if (drop_next_packet_) {
     drop_next_packet_ = false;
     return;
   }

   QuicReceivedPacket received_packet(packet->contents.data(),
                                      packet->contents.size(), clock_->Now());
   connection_->ProcessUdpPacket(connection_->self_address(),
                                 connection_->peer_address(), received_packet);
 }

 UnconstrainedPortInterface* QuicEndpointBase::GetRxPort() {
   return this;
 }

 void QuicEndpointBase::SetTxPort(ConstrainedPortInterface* port) {
   // Any egress done by the endpoint is actually handled by a queue on an NIC.
   nic_tx_queue_.set_tx_port(port);
 }

 void QuicEndpointBase::OnPacketDequeued() {
   if (writer_.IsWriteBlocked() &&
       (nic_tx_queue_.capacity() - nic_tx_queue_.bytes_queued()) >=
           kMaxOutgoingPacketSize) {
     writer_.SetWritable();
     connection_->OnCanWrite();
   }
 }

 QuicEndpointBase::Writer::Writer(QuicEndpointBase* endpoint)
     : endpoint_(endpoint), is_blocked_(false) {}

 QuicEndpointBase::Writer::~Writer() {}

 WriteResult QuicEndpointBase::Writer::WritePacket(
     const char* buffer,
     size_t buf_len,
     const QuicIpAddress& /*self_address*/,
     const QuicSocketAddress& /*peer_address*/,
     PerPacketOptions* options) {
   QUICHE_DCHECK(!IsWriteBlocked());
   QUICHE_DCHECK(options == nullptr);
   QUICHE_DCHECK(buf_len <= kMaxOutgoingPacketSize);

   // Instead of losing a packet, become write-blocked when the egress queue is
   // full.
   if (endpoint_->nic_tx_queue_.packets_queued() > kTxQueueSize) {
     is_blocked_ = true;
     endpoint_->write_blocked_count_++;
     return WriteResult(WRITE_STATUS_BLOCKED, 0);
   }

   auto packet = std::make_unique<Packet>();
   packet->source = endpoint_->name();
   packet->destination = endpoint_->peer_name_;
   packet->tx_timestamp = endpoint_->clock_->Now();

   packet->contents = std::string(buffer, buf_len);
   packet->size = buf_len;

   endpoint_->nic_tx_queue_.AcceptPacket(std::move(packet));

   return WriteResult(WRITE_STATUS_OK, buf_len);
 }

 bool QuicEndpointBase::Writer::IsWriteBlocked() const {
   return is_blocked_;
 }

 void QuicEndpointBase::Writer::SetWritable() {
   is_blocked_ = false;
 }

 QuicByteCount QuicEndpointBase::Writer::GetMaxPacketSize(
     const QuicSocketAddress& /*peer_address*/) const {
   return kMaxOutgoingPacketSize;
 }

 bool QuicEndpointBase::Writer::SupportsReleaseTime() const {
   return false;
 }

 bool QuicEndpointBase::Writer::IsBatchMode() const {
   return false;
 }

 QuicPacketBuffer QuicEndpointBase::Writer::GetNextWriteLocation(
     const QuicIpAddress& /*self_address*/,
     const QuicSocketAddress& /*peer_address*/) {
   return {nullptr, nullptr};
 }

 WriteResult QuicEndpointBase::Writer::Flush() {
   return WriteResult(WRITE_STATUS_OK, 0);
 }

 QuicEndpointMultiplexer::QuicEndpointMultiplexer(
     std::string name,
     const std::vector<QuicEndpointBase*>& endpoints)
     : Endpoint((*endpoints.begin())->simulator(), name) {
   for (QuicEndpointBase* endpoint : endpoints) {
     mapping_.insert(std::make_pair(endpoint->name(), endpoint));
   }
 }

 QuicEndpointMultiplexer::~QuicEndpointMultiplexer() {}

 void QuicEndpointMultiplexer::AcceptPacket(std::unique_ptr<Packet> packet) {
   auto key_value_pair_it = mapping_.find(packet->destination);
   if (key_value_pair_it == mapping_.end()) {
     return;
   }

   key_value_pair_it->second->GetRxPort()->AcceptPacket(std::move(packet));
 }
 UnconstrainedPortInterface* QuicEndpointMultiplexer::GetRxPort() {
   return this;
 }
 void QuicEndpointMultiplexer::SetTxPort(ConstrainedPortInterface* port) {
   for (auto& key_value_pair : mapping_) {
     key_value_pair.second->SetTxPort(port);
   }
 }

 }  // 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/quic_endpoint_base.h"

	#include <memory>
	#include <utility>

	#include "absl/strings/str_cat.h"
	#include "quic/core/crypto/crypto_handshake_message.h"
	#include "quic/core/crypto/crypto_protocol.h"
	#include "quic/core/quic_connection.h"
	#include "quic/core/quic_data_writer.h"
	#include "quic/platform/api/quic_test_output.h"
	#include "quic/test_tools/quic_connection_peer.h"
	#include "quic/test_tools/quic_test_utils.h"
	#include "quic/test_tools/simulator/simulator.h"

	namespace quic {
	namespace simulator {

	// Takes a SHA-1 hash of the name and converts it into five 32-bit integers.
	static std::vector<uint32_t> HashNameIntoFive32BitIntegers(std::string name) {
	const std::string hash = test::Sha1Hash(name);

	std::vector<uint32_t> output;
	uint32_t current_number = 0;
	for (size_t i = 0; i < hash.size(); i++) {
	current_number = (current_number << 8) + hash[i];
	if (i % 4 == 3) {
	output.push_back(i);
	current_number = 0;
	}
	}

	return output;
	}

	QuicSocketAddress GetAddressFromName(std::string name) {
	const std::vector<uint32_t> hash = HashNameIntoFive32BitIntegers(name);

	// Generate a random port between 1025 and 65535.
	const uint16_t port = 1025 + hash[0] % (65535 - 1025 + 1);

	// Generate a random 10.x.x.x address, where x is between 1 and 254.
	std::string ip_address{"\xa\0\0\0", 4};
	for (size_t i = 1; i < 4; i++) {
	ip_address[i] = 1 + hash[i] % 254;
	}
	QuicIpAddress host;
	host.FromPackedString(ip_address.c_str(), ip_address.length());
	return QuicSocketAddress(host, port);
	}

	QuicEndpointBase::QuicEndpointBase(Simulator* simulator,
	std::string name,
	std::string peer_name)
	: Endpoint(simulator, name),
	peer_name_(peer_name),
	writer_(this),
	nic_tx_queue_(simulator,
	absl::StrCat(name, " (TX Queue)"),
	kMaxOutgoingPacketSize * kTxQueueSize),
	connection_(nullptr),
	write_blocked_count_(0),
	drop_next_packet_(false) {
	nic_tx_queue_.set_listener_interface(this);
	}

	QuicEndpointBase::~QuicEndpointBase() {
	if (trace_visitor_ != nullptr) {
	const char* perspective_prefix =
	connection_->perspective() == Perspective::IS_CLIENT ? "C" : "S";

	std::string identifier = absl::StrCat(
	perspective_prefix, connection_->connection_id().ToString());
	QuicRecordTrace(identifier, trace_visitor_->trace()->SerializeAsString());
	}
	}

	void QuicEndpointBase::DropNextIncomingPacket() {
	drop_next_packet_ = true;
	}

	void QuicEndpointBase::RecordTrace() {
	trace_visitor_ = std::make_unique<QuicTraceVisitor>(connection_.get());
	connection_->set_debug_visitor(trace_visitor_.get());
	}

	void QuicEndpointBase::AcceptPacket(std::unique_ptr<Packet> packet) {
	if (packet->destination != name_) {
	return;
	}
	if (drop_next_packet_) {
	drop_next_packet_ = false;
	return;
	}

	QuicReceivedPacket received_packet(packet->contents.data(),
	packet->contents.size(), clock_->Now());
	connection_->ProcessUdpPacket(connection_->self_address(),
	connection_->peer_address(), received_packet);
	}

	UnconstrainedPortInterface* QuicEndpointBase::GetRxPort() {
	return this;
	}

	void QuicEndpointBase::SetTxPort(ConstrainedPortInterface* port) {
	// Any egress done by the endpoint is actually handled by a queue on an NIC.
	nic_tx_queue_.set_tx_port(port);
	}

	void QuicEndpointBase::OnPacketDequeued() {
	if (writer_.IsWriteBlocked() &&
	(nic_tx_queue_.capacity() - nic_tx_queue_.bytes_queued()) >=
	kMaxOutgoingPacketSize) {
	writer_.SetWritable();
	connection_->OnCanWrite();
	}
	}

	QuicEndpointBase::Writer::Writer(QuicEndpointBase* endpoint)
	: endpoint_(endpoint), is_blocked_(false) {}

	QuicEndpointBase::Writer::~Writer() {}

	WriteResult QuicEndpointBase::Writer::WritePacket(
	const char* buffer,
	size_t buf_len,
	const QuicIpAddress& /self_address/,
	const QuicSocketAddress& /peer_address/,
	PerPacketOptions* options) {
	QUICHE_DCHECK(!IsWriteBlocked());
	QUICHE_DCHECK(options == nullptr);
	QUICHE_DCHECK(buf_len <= kMaxOutgoingPacketSize);

	// Instead of losing a packet, become write-blocked when the egress queue is
	// full.
	if (endpoint_->nic_tx_queue_.packets_queued() > kTxQueueSize) {
	is_blocked_ = true;
	endpoint_->write_blocked_count_++;
	return WriteResult(WRITE_STATUS_BLOCKED, 0);
	}

	auto packet = std::make_unique<Packet>();
	packet->source = endpoint_->name();
	packet->destination = endpoint_->peer_name_;
	packet->tx_timestamp = endpoint_->clock_->Now();

	packet->contents = std::string(buffer, buf_len);
	packet->size = buf_len;

	endpoint_->nic_tx_queue_.AcceptPacket(std::move(packet));

	return WriteResult(WRITE_STATUS_OK, buf_len);
	}

	bool QuicEndpointBase::Writer::IsWriteBlocked() const {
	return is_blocked_;
	}

	void QuicEndpointBase::Writer::SetWritable() {
	is_blocked_ = false;
	}

	QuicByteCount QuicEndpointBase::Writer::GetMaxPacketSize(
	const QuicSocketAddress& /peer_address/) const {
	return kMaxOutgoingPacketSize;
	}

	bool QuicEndpointBase::Writer::SupportsReleaseTime() const {
	return false;
	}

	bool QuicEndpointBase::Writer::IsBatchMode() const {
	return false;
	}

	QuicPacketBuffer QuicEndpointBase::Writer::GetNextWriteLocation(
	const QuicIpAddress& /self_address/,
	const QuicSocketAddress& /peer_address/) {
	return {nullptr, nullptr};
	}

	WriteResult QuicEndpointBase::Writer::Flush() {
	return WriteResult(WRITE_STATUS_OK, 0);
	}

	QuicEndpointMultiplexer::QuicEndpointMultiplexer(
	std::string name,
	const std::vector<QuicEndpointBase*>& endpoints)
	: Endpoint((*endpoints.begin())->simulator(), name) {
	for (QuicEndpointBase* endpoint : endpoints) {
	mapping_.insert(std::make_pair(endpoint->name(), endpoint));
	}
	}

	QuicEndpointMultiplexer::~QuicEndpointMultiplexer() {}

	void QuicEndpointMultiplexer::AcceptPacket(std::unique_ptr<Packet> packet) {
	auto key_value_pair_it = mapping_.find(packet->destination);
	if (key_value_pair_it == mapping_.end()) {
	return;
	}

	key_value_pair_it->second->GetRxPort()->AcceptPacket(std::move(packet));
	}
	UnconstrainedPortInterface* QuicEndpointMultiplexer::GetRxPort() {
	return this;
	}
	void QuicEndpointMultiplexer::SetTxPort(ConstrainedPortInterface* port) {
	for (auto& key_value_pair : mapping_) {
	key_value_pair.second->SetTxPort(port);
	}
	}

	} // namespace simulator
	} // namespace quic