quic/quartc/quartc_factory.cc - quiche.git - Git at Google

 // Copyright (c) 2017 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/quartc/quartc_factory.h"

 #include "net/third_party/quiche/src/quic/core/crypto/quic_random.h"
 #include "net/third_party/quiche/src/quic/core/quic_utils.h"
 #include "net/third_party/quiche/src/quic/core/tls_client_handshaker.h"
 #include "net/third_party/quiche/src/quic/core/tls_server_handshaker.h"
 #include "net/third_party/quiche/src/quic/core/uber_received_packet_manager.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_ptr_util.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_socket_address.h"
 #include "net/third_party/quiche/src/quic/quartc/quartc_connection_helper.h"
 #include "net/third_party/quiche/src/quic/quartc/quartc_crypto_helpers.h"
 #include "net/third_party/quiche/src/quic/quartc/quartc_session.h"

 namespace quic {

 std::unique_ptr<QuartcSession> CreateQuartcClientSession(
     const QuartcSessionConfig& quartc_session_config,
     const QuicClock* clock,
     QuicAlarmFactory* alarm_factory,
     QuicConnectionHelperInterface* connection_helper,
     const ParsedQuicVersionVector& supported_versions,
     QuicStringPiece server_crypto_config,
     QuartcPacketTransport* packet_transport) {
   DCHECK(packet_transport);

   // QuartcSession will eventually own both |writer| and |quic_connection|.
   auto writer = QuicMakeUnique<QuartcPacketWriter>(
       packet_transport, quartc_session_config.max_packet_size);

   // While the QuicConfig is not directly used by the connection, creating it
   // also sets flag values which must be set before creating the connection.
   QuicConfig quic_config = CreateQuicConfig(quartc_session_config);

   // |dummy_id| and |dummy_address| are used because Quartc network layer will
   // not use these two.
   QuicConnectionId dummy_id = QuicUtils::CreateZeroConnectionId(
       supported_versions[0].transport_version);
   QuicSocketAddress dummy_address(QuicIpAddress::Any4(), /*port=*/0);
   std::unique_ptr<QuicConnection> quic_connection = CreateQuicConnection(
       dummy_id, dummy_address, connection_helper, alarm_factory, writer.get(),
       Perspective::IS_CLIENT, supported_versions);

   // Quartc sets its own ack delay; get that ack delay and copy it over
   // to the QuicConfig so that it can be properly advertised to the peer
   // via transport parameter negotiation.
   quic_config.SetMaxAckDelayToSendMs(quic_connection->received_packet_manager()
                                          .max_ack_delay()
                                          .ToMilliseconds());

   return QuicMakeUnique<QuartcClientSession>(
       std::move(quic_connection), quic_config, supported_versions, clock,
       std::move(writer),
       CreateCryptoClientConfig(quartc_session_config.pre_shared_key),
       server_crypto_config);
 }

 void ConfigureGlobalQuicSettings() {
   // Fixes behavior of StopReading() with level-triggered stream sequencers.
   SetQuicReloadableFlag(quic_stop_reading_when_level_triggered, true);

   // Enable version 47 to enable variable-length connection ids.
   SetQuicReloadableFlag(quic_enable_version_47, true);

   // Ensure that we don't drop data because QUIC streams refuse to buffer it.
   // TODO(b/120099046):  Replace this with correct handling of WriteMemSlices().
   SetQuicFlag(FLAGS_quic_buffered_data_threshold,
               std::numeric_limits<int>::max());

   // Enable and request QUIC to include receive timestamps in ACK frames.
   SetQuicReloadableFlag(quic_send_timestamps, true);

   // Enable ACK_DECIMATION_WITH_REORDERING. It requires ack_decimation to be
   // false.
   SetQuicReloadableFlag(quic_enable_ack_decimation, false);

   // Note: flag settings have no effect for Exoblaze builds since
   // SetQuicReloadableFlag() gets stubbed out.
   SetQuicReloadableFlag(quic_bbr_less_probe_rtt, true);   // Enable BBR6,7,8.
   SetQuicReloadableFlag(quic_unified_iw_options, true);   // Enable IWXX opts.
   SetQuicReloadableFlag(quic_bbr_flexible_app_limited, true);  // Enable BBR9.

   // Fix GetPacketHeaderSize
   SetQuicReloadableFlag(quic_fix_get_packet_header_size, true);
 }

 QuicConfig CreateQuicConfig(const QuartcSessionConfig& quartc_session_config) {
   // TODO(b/124398962): Figure out a better way to initialize QUIC flags.
   // Creating a config shouldn't have global side-effects on flags.  However,
   // this has the advantage of ensuring that flag values stay in sync with the
   // options requested by configs, so simply splitting the config and flag
   // settings doesn't seem preferable.
   ConfigureGlobalQuicSettings();

   // In exoblaze this may return false. DCHECK to avoid problems caused by
   // incorrect flags configuration.
   DCHECK(GetQuicReloadableFlag(quic_enable_version_47))
       << "Your build does not support quic reloadable flags and shouldn't "
          "place Quartc calls";

   QuicTagVector copt;
   copt.push_back(kNSTP);

   // Enable and request QUIC to include receive timestamps in ACK frames.
   copt.push_back(kSTMP);

   // Enable ACK_DECIMATION_WITH_REORDERING. It requires ack_decimation to be
   // false.
   copt.push_back(kAKD2);

   // Use unlimited decimation in order to reduce number of unbundled ACKs.
   copt.push_back(kAKDU);

   // Enable time-based loss detection.
   copt.push_back(kTIME);

   copt.push_back(kBBR3);  // Stay in low-gain until in-flight < BDP.
   copt.push_back(kBBR5);  // 40 RTT ack aggregation.
   copt.push_back(kBBR6);  // Use a 0.75 * BDP cwnd during PROBE_RTT.
   copt.push_back(kBBR8);  // Skip PROBE_RTT if app-limited.
   copt.push_back(kBBR9);  // Ignore app-limited if enough data is in flight.
   copt.push_back(kBBQ1);  // 2.773 pacing gain in STARTUP.
   copt.push_back(kBBQ2);  // 2.0 CWND gain in STARTUP.
   copt.push_back(k1RTT);  // Exit STARTUP after 1 RTT with no gains.
   copt.push_back(kIW10);  // 10-packet (14600 byte) initial cwnd.

   if (!quartc_session_config.enable_tail_loss_probe) {
     copt.push_back(kNTLP);
   }

   // TODO(b/112192153):  Test and possible enable slower startup when pipe
   // filling is ready to use.  Slower startup is kBBRS.

   QuicConfig quic_config;

   // Use the limits for the session & stream flow control. The default 16KB
   // limit leads to significantly undersending (not reaching BWE on the outgoing
   // bitrate) due to blocked frames, and it leads to high latency (and one-way
   // delay). Setting it to its limits is not going to cause issues (our streams
   // are small generally, and if we were to buffer 24MB it wouldn't be the end
   // of the world). We can consider setting different limits in future (e.g. 1MB
   // stream, 1.5MB session). It's worth noting that on 1mbps bitrate, limit of
   // 24MB can capture approx 4 minutes of the call, and the default increase in
   // size of the window (half of the window size) is approximately 2 minutes of
   // the call.
   quic_config.SetInitialSessionFlowControlWindowToSend(
       kSessionReceiveWindowLimit);
   quic_config.SetInitialStreamFlowControlWindowToSend(
       kStreamReceiveWindowLimit);
   quic_config.SetConnectionOptionsToSend(copt);
   quic_config.SetClientConnectionOptions(copt);
   if (quartc_session_config.max_time_before_crypto_handshake >
       QuicTime::Delta::Zero()) {
     quic_config.set_max_time_before_crypto_handshake(
         quartc_session_config.max_time_before_crypto_handshake);
   }
   if (quartc_session_config.max_idle_time_before_crypto_handshake >
       QuicTime::Delta::Zero()) {
     quic_config.set_max_idle_time_before_crypto_handshake(
         quartc_session_config.max_idle_time_before_crypto_handshake);
   }
   if (quartc_session_config.idle_network_timeout > QuicTime::Delta::Zero()) {
     quic_config.SetIdleNetworkTimeout(
         quartc_session_config.idle_network_timeout,
         quartc_session_config.idle_network_timeout);
   }

   // The ICE transport provides a unique 5-tuple for each connection. Save
   // overhead by omitting the connection id.
   quic_config.SetBytesForConnectionIdToSend(0);

   // Allow up to 1000 incoming streams at once. Quartc streams typically contain
   // one audio or video frame and close immediately. However, when a video frame
   // becomes larger than one packet, there is some delay between the start and
   // end of each stream. The default maximum of 100 only leaves about 1 second
   // of headroom (Quartc sends ~30 video frames per second) before QUIC starts
   // to refuse incoming streams. Back-pressure should clear backlogs of
   // incomplete streams, but targets 1 second for recovery. Increasing the
   // number of open streams gives sufficient headroom to recover before QUIC
   // refuses new streams.
   quic_config.SetMaxIncomingBidirectionalStreamsToSend(1000);

   return quic_config;
 }

 std::unique_ptr<QuicConnection> CreateQuicConnection(
     QuicConnectionId connection_id,
     const QuicSocketAddress& peer_address,
     QuicConnectionHelperInterface* connection_helper,
     QuicAlarmFactory* alarm_factory,
     QuicPacketWriter* packet_writer,
     Perspective perspective,
     ParsedQuicVersionVector supported_versions) {
   auto quic_connection = QuicMakeUnique<QuicConnection>(
       connection_id, peer_address, connection_helper, alarm_factory,
       packet_writer,
       /*owns_writer=*/false, perspective, supported_versions);
   quic_connection->SetMaxPacketLength(
       packet_writer->GetMaxPacketSize(peer_address));

   QuicSentPacketManager& sent_packet_manager =
       quic_connection->sent_packet_manager();
   UberReceivedPacketManager& received_packet_manager =
       quic_connection->received_packet_manager();

   // Default delayed ack time is 25ms.
   // If data packets are sent less often (e.g. because p-time was modified),
   // we would force acks to be sent every 25ms regardless, increasing
   // overhead. Since generally we guarantee a packet every 20ms, changing
   // this value should have miniscule effect on quality on good connections,
   // but on poor connections, changing this number significantly reduced the
   // number of ack-only packets.
   // The p-time can go up to as high as 120ms, and when it does, it's
   // when the low overhead is the most important thing. Ideally it should be
   // above 120ms, but it cannot be higher than 0.5*RTO, which equals to 100ms.
   received_packet_manager.set_max_ack_delay(
       QuicTime::Delta::FromMilliseconds(100));
   sent_packet_manager.set_peer_max_ack_delay(
       QuicTime::Delta::FromMilliseconds(100));

   quic_connection->set_fill_up_link_during_probing(true);

   // We start ack decimation after 15 packets. Typically, we would see
   // 1-2 crypto handshake packets, one media packet, and 10 probing packets.
   // We want to get acks for the probing packets as soon as possible,
   // but we can start using ack decimation right after first probing completes.
   // The default was to not start ack decimation for the first 100 packets.
   quic_connection->set_min_received_before_ack_decimation(15);

   return quic_connection;
 }

 }  // namespace quic
	// Copyright (c) 2017 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/quartc/quartc_factory.h"

	#include "net/third_party/quiche/src/quic/core/crypto/quic_random.h"
	#include "net/third_party/quiche/src/quic/core/quic_utils.h"
	#include "net/third_party/quiche/src/quic/core/tls_client_handshaker.h"
	#include "net/third_party/quiche/src/quic/core/tls_server_handshaker.h"
	#include "net/third_party/quiche/src/quic/core/uber_received_packet_manager.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_ptr_util.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_socket_address.h"
	#include "net/third_party/quiche/src/quic/quartc/quartc_connection_helper.h"
	#include "net/third_party/quiche/src/quic/quartc/quartc_crypto_helpers.h"
	#include "net/third_party/quiche/src/quic/quartc/quartc_session.h"

	namespace quic {

	std::unique_ptr<QuartcSession> CreateQuartcClientSession(
	const QuartcSessionConfig& quartc_session_config,
	const QuicClock* clock,
	QuicAlarmFactory* alarm_factory,
	QuicConnectionHelperInterface* connection_helper,
	const ParsedQuicVersionVector& supported_versions,
	QuicStringPiece server_crypto_config,
	QuartcPacketTransport* packet_transport) {
	DCHECK(packet_transport);

	// QuartcSession will eventually own both \|writer\| and \|quic_connection\|.
	auto writer = QuicMakeUnique<QuartcPacketWriter>(
	packet_transport, quartc_session_config.max_packet_size);

	// While the QuicConfig is not directly used by the connection, creating it
	// also sets flag values which must be set before creating the connection.
	QuicConfig quic_config = CreateQuicConfig(quartc_session_config);

	// \|dummy_id\| and \|dummy_address\| are used because Quartc network layer will
	// not use these two.
	QuicConnectionId dummy_id = QuicUtils::CreateZeroConnectionId(
	supported_versions[0].transport_version);
	QuicSocketAddress dummy_address(QuicIpAddress::Any4(), /port=/0);
	std::unique_ptr<QuicConnection> quic_connection = CreateQuicConnection(
	dummy_id, dummy_address, connection_helper, alarm_factory, writer.get(),
	Perspective::IS_CLIENT, supported_versions);

	// Quartc sets its own ack delay; get that ack delay and copy it over
	// to the QuicConfig so that it can be properly advertised to the peer
	// via transport parameter negotiation.
	quic_config.SetMaxAckDelayToSendMs(quic_connection->received_packet_manager()
	.max_ack_delay()
	.ToMilliseconds());

	return QuicMakeUnique<QuartcClientSession>(
	std::move(quic_connection), quic_config, supported_versions, clock,
	std::move(writer),
	CreateCryptoClientConfig(quartc_session_config.pre_shared_key),
	server_crypto_config);
	}

	void ConfigureGlobalQuicSettings() {
	// Fixes behavior of StopReading() with level-triggered stream sequencers.
	SetQuicReloadableFlag(quic_stop_reading_when_level_triggered, true);

	// Enable version 47 to enable variable-length connection ids.
	SetQuicReloadableFlag(quic_enable_version_47, true);

	// Ensure that we don't drop data because QUIC streams refuse to buffer it.
	// TODO(b/120099046): Replace this with correct handling of WriteMemSlices().
	SetQuicFlag(FLAGS_quic_buffered_data_threshold,
	std::numeric_limits<int>::max());

	// Enable and request QUIC to include receive timestamps in ACK frames.
	SetQuicReloadableFlag(quic_send_timestamps, true);

	// Enable ACK_DECIMATION_WITH_REORDERING. It requires ack_decimation to be
	// false.
	SetQuicReloadableFlag(quic_enable_ack_decimation, false);

	// Note: flag settings have no effect for Exoblaze builds since
	// SetQuicReloadableFlag() gets stubbed out.
	SetQuicReloadableFlag(quic_bbr_less_probe_rtt, true); // Enable BBR6,7,8.
	SetQuicReloadableFlag(quic_unified_iw_options, true); // Enable IWXX opts.
	SetQuicReloadableFlag(quic_bbr_flexible_app_limited, true); // Enable BBR9.

	// Fix GetPacketHeaderSize
	SetQuicReloadableFlag(quic_fix_get_packet_header_size, true);
	}

	QuicConfig CreateQuicConfig(const QuartcSessionConfig& quartc_session_config) {
	// TODO(b/124398962): Figure out a better way to initialize QUIC flags.
	// Creating a config shouldn't have global side-effects on flags. However,
	// this has the advantage of ensuring that flag values stay in sync with the
	// options requested by configs, so simply splitting the config and flag
	// settings doesn't seem preferable.
	ConfigureGlobalQuicSettings();

	// In exoblaze this may return false. DCHECK to avoid problems caused by
	// incorrect flags configuration.
	DCHECK(GetQuicReloadableFlag(quic_enable_version_47))
	<< "Your build does not support quic reloadable flags and shouldn't "
	"place Quartc calls";

	QuicTagVector copt;
	copt.push_back(kNSTP);

	// Enable and request QUIC to include receive timestamps in ACK frames.
	copt.push_back(kSTMP);

	// Enable ACK_DECIMATION_WITH_REORDERING. It requires ack_decimation to be
	// false.
	copt.push_back(kAKD2);

	// Use unlimited decimation in order to reduce number of unbundled ACKs.
	copt.push_back(kAKDU);

	// Enable time-based loss detection.
	copt.push_back(kTIME);

	copt.push_back(kBBR3); // Stay in low-gain until in-flight < BDP.
	copt.push_back(kBBR5); // 40 RTT ack aggregation.
	copt.push_back(kBBR6); // Use a 0.75 * BDP cwnd during PROBE_RTT.
	copt.push_back(kBBR8); // Skip PROBE_RTT if app-limited.
	copt.push_back(kBBR9); // Ignore app-limited if enough data is in flight.
	copt.push_back(kBBQ1); // 2.773 pacing gain in STARTUP.
	copt.push_back(kBBQ2); // 2.0 CWND gain in STARTUP.
	copt.push_back(k1RTT); // Exit STARTUP after 1 RTT with no gains.
	copt.push_back(kIW10); // 10-packet (14600 byte) initial cwnd.

	if (!quartc_session_config.enable_tail_loss_probe) {
	copt.push_back(kNTLP);
	}

	// TODO(b/112192153): Test and possible enable slower startup when pipe
	// filling is ready to use. Slower startup is kBBRS.

	QuicConfig quic_config;

	// Use the limits for the session & stream flow control. The default 16KB
	// limit leads to significantly undersending (not reaching BWE on the outgoing
	// bitrate) due to blocked frames, and it leads to high latency (and one-way
	// delay). Setting it to its limits is not going to cause issues (our streams
	// are small generally, and if we were to buffer 24MB it wouldn't be the end
	// of the world). We can consider setting different limits in future (e.g. 1MB
	// stream, 1.5MB session). It's worth noting that on 1mbps bitrate, limit of
	// 24MB can capture approx 4 minutes of the call, and the default increase in
	// size of the window (half of the window size) is approximately 2 minutes of
	// the call.
	quic_config.SetInitialSessionFlowControlWindowToSend(
	kSessionReceiveWindowLimit);
	quic_config.SetInitialStreamFlowControlWindowToSend(
	kStreamReceiveWindowLimit);
	quic_config.SetConnectionOptionsToSend(copt);
	quic_config.SetClientConnectionOptions(copt);
	if (quartc_session_config.max_time_before_crypto_handshake >
	QuicTime::Delta::Zero()) {
	quic_config.set_max_time_before_crypto_handshake(
	quartc_session_config.max_time_before_crypto_handshake);
	}
	if (quartc_session_config.max_idle_time_before_crypto_handshake >
	QuicTime::Delta::Zero()) {
	quic_config.set_max_idle_time_before_crypto_handshake(
	quartc_session_config.max_idle_time_before_crypto_handshake);
	}
	if (quartc_session_config.idle_network_timeout > QuicTime::Delta::Zero()) {
	quic_config.SetIdleNetworkTimeout(
	quartc_session_config.idle_network_timeout,
	quartc_session_config.idle_network_timeout);
	}

	// The ICE transport provides a unique 5-tuple for each connection. Save
	// overhead by omitting the connection id.
	quic_config.SetBytesForConnectionIdToSend(0);

	// Allow up to 1000 incoming streams at once. Quartc streams typically contain
	// one audio or video frame and close immediately. However, when a video frame
	// becomes larger than one packet, there is some delay between the start and
	// end of each stream. The default maximum of 100 only leaves about 1 second
	// of headroom (Quartc sends ~30 video frames per second) before QUIC starts
	// to refuse incoming streams. Back-pressure should clear backlogs of
	// incomplete streams, but targets 1 second for recovery. Increasing the
	// number of open streams gives sufficient headroom to recover before QUIC
	// refuses new streams.
	quic_config.SetMaxIncomingBidirectionalStreamsToSend(1000);

	return quic_config;
	}

	std::unique_ptr<QuicConnection> CreateQuicConnection(
	QuicConnectionId connection_id,
	const QuicSocketAddress& peer_address,
	QuicConnectionHelperInterface* connection_helper,
	QuicAlarmFactory* alarm_factory,
	QuicPacketWriter* packet_writer,
	Perspective perspective,
	ParsedQuicVersionVector supported_versions) {
	auto quic_connection = QuicMakeUnique<QuicConnection>(
	connection_id, peer_address, connection_helper, alarm_factory,
	packet_writer,
	/owns_writer=/false, perspective, supported_versions);
	quic_connection->SetMaxPacketLength(
	packet_writer->GetMaxPacketSize(peer_address));

	QuicSentPacketManager& sent_packet_manager =
	quic_connection->sent_packet_manager();
	UberReceivedPacketManager& received_packet_manager =
	quic_connection->received_packet_manager();

	// Default delayed ack time is 25ms.
	// If data packets are sent less often (e.g. because p-time was modified),
	// we would force acks to be sent every 25ms regardless, increasing
	// overhead. Since generally we guarantee a packet every 20ms, changing
	// this value should have miniscule effect on quality on good connections,
	// but on poor connections, changing this number significantly reduced the
	// number of ack-only packets.
	// The p-time can go up to as high as 120ms, and when it does, it's
	// when the low overhead is the most important thing. Ideally it should be
	// above 120ms, but it cannot be higher than 0.5*RTO, which equals to 100ms.
	received_packet_manager.set_max_ack_delay(
	QuicTime::Delta::FromMilliseconds(100));
	sent_packet_manager.set_peer_max_ack_delay(
	QuicTime::Delta::FromMilliseconds(100));

	quic_connection->set_fill_up_link_during_probing(true);

	// We start ack decimation after 15 packets. Typically, we would see
	// 1-2 crypto handshake packets, one media packet, and 10 probing packets.
	// We want to get acks for the probing packets as soon as possible,
	// but we can start using ack decimation right after first probing completes.
	// The default was to not start ack decimation for the first 100 packets.
	quic_connection->set_min_received_before_ack_decimation(15);

	return quic_connection;
	}

	} // namespace quic