quiche/quic/masque/masque_encapsulated_client.cc - quiche.git - Git at Google

 // Copyright 2019 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 "quiche/quic/masque/masque_encapsulated_client.h"

 #include <optional>

 #include "quiche/quic/core/quic_utils.h"
 #include "quiche/quic/masque/masque_client.h"
 #include "quiche/quic/masque/masque_client_session.h"
 #include "quiche/quic/masque/masque_encapsulated_client_session.h"
 #include "quiche/quic/masque/masque_utils.h"
 #include "quiche/quic/tools/quic_client_default_network_helper.h"
 #include "quiche/common/quiche_data_reader.h"
 #include "quiche/common/quiche_data_writer.h"

 namespace quic {

 namespace {

 class ChecksumWriter {
  public:
   explicit ChecksumWriter(quiche::QuicheDataWriter& writer) : writer_(writer) {}
   void IngestUInt16(uint16_t val) { accumulator_ += val; }
   void IngestUInt8(uint8_t val) {
     uint16_t val16 = odd_ ? val : (val << 8);
     accumulator_ += val16;
     odd_ = !odd_;
   }
   bool IngestData(size_t offset, size_t length) {
     quiche::QuicheDataReader reader(
         writer_.data(), std::min<size_t>(offset + length, writer_.capacity()));
     if (!reader.Seek(offset) || reader.BytesRemaining() < length) {
       return false;
     }
     // Handle any potentially off first byte.
     uint8_t first_byte;
     if (odd_ && reader.ReadUInt8(&first_byte)) {
       IngestUInt8(first_byte);
     }
     // Handle each 16-bit word at a time.
     while (reader.BytesRemaining() >= sizeof(uint16_t)) {
       uint16_t word;
       if (!reader.ReadUInt16(&word)) {
         return false;
       }
       IngestUInt16(word);
     }
     // Handle any leftover odd byte.
     uint8_t last_byte;
     if (reader.ReadUInt8(&last_byte)) {
       IngestUInt8(last_byte);
     }
     return true;
   }
   bool WriteChecksumAtOffset(size_t offset) {
     while (accumulator_ >> 16 > 0) {
       accumulator_ = (accumulator_ & 0xffff) + (accumulator_ >> 16);
     }
     accumulator_ = 0xffff & ~accumulator_;
     quiche::QuicheDataWriter writer2(writer_.capacity(), writer_.data());
     return writer2.Seek(offset) && writer2.WriteUInt16(accumulator_);
   }

  private:
   quiche::QuicheDataWriter& writer_;
   uint32_t accumulator_ = 0xffff;
   bool odd_ = false;
 };

 // Custom packet writer that allows getting all of a connection's outgoing
 // packets.
 class MasquePacketWriter : public QuicPacketWriter {
  public:
   explicit MasquePacketWriter(MasqueEncapsulatedClient* client)
       : client_(client) {}
   WriteResult WritePacket(const char* buffer, size_t buf_len,
                           const QuicIpAddress& /*self_address*/,
                           const QuicSocketAddress& peer_address,
                           PerPacketOptions* /*options*/) override {
     QUICHE_DCHECK(peer_address.IsInitialized());
     QUIC_DVLOG(1) << "MasquePacketWriter trying to write " << buf_len
                   << " bytes to " << peer_address;
     if (client_->masque_client()->masque_mode() == MasqueMode::kConnectIp) {
       constexpr size_t kIPv4HeaderSize = 20;
       constexpr size_t kIPv4ChecksumOffset = 10;
       constexpr size_t kIPv6HeaderSize = 40;
       constexpr size_t kUdpHeaderSize = 8;
       const size_t udp_length = kUdpHeaderSize + buf_len;
       std::string packet;
       packet.resize(
           (peer_address.host().IsIPv6() ? kIPv6HeaderSize : kIPv4HeaderSize) +
           udp_length);
       quiche::QuicheDataWriter writer(packet.size(), packet.data());
       if (peer_address.host().IsIPv6()) {
         // Write IPv6 header.
         QUICHE_CHECK(writer.WriteUInt8(0x60));  // Version = 6 and DSCP.
         QUICHE_CHECK(writer.WriteUInt8(0));     // DSCP/ECN and flow label.
         QUICHE_CHECK(writer.WriteUInt16(0));    // Flow label.
         QUICHE_CHECK(writer.WriteUInt16(udp_length));  // Payload Length.
         QUICHE_CHECK(writer.WriteUInt8(17));           // Next header = UDP.
         QUICHE_CHECK(writer.WriteUInt8(64));           // Hop limit = 64.
         in6_addr source_address = {};
         if (client_->masque_encapsulated_client_session()
                 ->local_v6_address()
                 .IsIPv6()) {
           source_address = client_->masque_encapsulated_client_session()
                                ->local_v6_address()
                                .GetIPv6();
         }
         QUICHE_CHECK(
             writer.WriteBytes(&source_address, sizeof(source_address)));
         in6_addr destination_address = peer_address.host().GetIPv6();
         QUICHE_CHECK(writer.WriteBytes(&destination_address,
                                        sizeof(destination_address)));
       } else {
         // Write IPv4 header.
         QUICHE_CHECK(writer.WriteUInt8(0x45));  // Version = 4, IHL = 5.
         QUICHE_CHECK(writer.WriteUInt8(0));     // DSCP/ECN.
         QUICHE_CHECK(writer.WriteUInt16(packet.size()));  // Total Length.
         QUICHE_CHECK(writer.WriteUInt32(0));              // No fragmentation.
         QUICHE_CHECK(writer.WriteUInt8(64));              // TTL = 64.
         QUICHE_CHECK(writer.WriteUInt8(17));              // IP Protocol = UDP.
         QUICHE_CHECK(writer.WriteUInt16(0));  // Checksum = 0 initially.
         in_addr source_address = {};
         if (client_->masque_encapsulated_client_session()
                 ->local_v4_address()
                 .IsIPv4()) {
           source_address = client_->masque_encapsulated_client_session()
                                ->local_v4_address()
                                .GetIPv4();
         }
         QUICHE_CHECK(
             writer.WriteBytes(&source_address, sizeof(source_address)));
         in_addr destination_address = peer_address.host().GetIPv4();
         QUICHE_CHECK(writer.WriteBytes(&destination_address,
                                        sizeof(destination_address)));
         ChecksumWriter ip_checksum_writer(writer);
         QUICHE_CHECK(ip_checksum_writer.IngestData(0, kIPv4HeaderSize));
         QUICHE_CHECK(
             ip_checksum_writer.WriteChecksumAtOffset(kIPv4ChecksumOffset));
       }
       // Write UDP header.
       QUICHE_CHECK(writer.WriteUInt16(0x1234));  // Source port.
       QUICHE_CHECK(
           writer.WriteUInt16(peer_address.port()));  // Destination port.
       QUICHE_CHECK(writer.WriteUInt16(udp_length));  // UDP length.
       QUICHE_CHECK(writer.WriteUInt16(0));           // Checksum = 0 initially.
       // Write UDP payload.
       QUICHE_CHECK(writer.WriteBytes(buffer, buf_len));
       ChecksumWriter udp_checksum_writer(writer);
       if (peer_address.host().IsIPv6()) {
         QUICHE_CHECK(udp_checksum_writer.IngestData(8, 32));  // IP addresses.
         udp_checksum_writer.IngestUInt16(0);  // High bits of UDP length.
         udp_checksum_writer.IngestUInt16(
             udp_length);                      // Low bits of UDP length.
         udp_checksum_writer.IngestUInt16(0);  // Zeroes.
         udp_checksum_writer.IngestUInt8(0);   // Zeroes.
         udp_checksum_writer.IngestUInt8(17);  // Next header = UDP.
         QUICHE_CHECK(udp_checksum_writer.IngestData(
             kIPv6HeaderSize, udp_length));  // UDP header and data.
         QUICHE_CHECK(
             udp_checksum_writer.WriteChecksumAtOffset(kIPv6HeaderSize + 6));
       } else {
         QUICHE_CHECK(udp_checksum_writer.IngestData(12, 8));  // IP addresses.
         udp_checksum_writer.IngestUInt8(0);                   // Zeroes.
         udp_checksum_writer.IngestUInt8(17);           // IP Protocol = UDP.
         udp_checksum_writer.IngestUInt16(udp_length);  // UDP length.
         QUICHE_CHECK(udp_checksum_writer.IngestData(
             kIPv4HeaderSize, udp_length));  // UDP header and data.
         QUICHE_CHECK(
             udp_checksum_writer.WriteChecksumAtOffset(kIPv4HeaderSize + 6));
       }
       client_->masque_client()->masque_client_session()->SendIpPacket(
           packet, client_->masque_encapsulated_client_session());
     } else {
       absl::string_view packet(buffer, buf_len);
       client_->masque_client()->masque_client_session()->SendPacket(
           packet, peer_address, client_->masque_encapsulated_client_session());
     }
     return WriteResult(WRITE_STATUS_OK, buf_len);
   }

   bool IsWriteBlocked() const override { return false; }

   void SetWritable() override {}

   absl::optional<int> MessageTooBigErrorCode() const override {
     return absl::nullopt;
   }

   QuicByteCount GetMaxPacketSize(
       const QuicSocketAddress& /*peer_address*/) const override {
     return kMasqueMaxEncapsulatedPacketSize;
   }

   bool SupportsReleaseTime() const override { return false; }

   bool IsBatchMode() const override { return false; }
   QuicPacketBuffer GetNextWriteLocation(
       const QuicIpAddress& /*self_address*/,
       const QuicSocketAddress& /*peer_address*/) override {
     return {nullptr, nullptr};
   }

   WriteResult Flush() override { return WriteResult(WRITE_STATUS_OK, 0); }

  private:
   MasqueEncapsulatedClient* client_;  // Unowned.
 };

 // Custom network helper that allows injecting a custom packet writer in order
 // to get all of a connection's outgoing packets.
 class MasqueClientDefaultNetworkHelper : public QuicClientDefaultNetworkHelper {
  public:
   MasqueClientDefaultNetworkHelper(QuicEventLoop* event_loop,
                                    MasqueEncapsulatedClient* client)
       : QuicClientDefaultNetworkHelper(event_loop, client), client_(client) {}
   QuicPacketWriter* CreateQuicPacketWriter() override {
     return new MasquePacketWriter(client_);
   }

  private:
   MasqueEncapsulatedClient* client_;  // Unowned.
 };

 }  // namespace

 MasqueEncapsulatedClient::MasqueEncapsulatedClient(
     QuicSocketAddress server_address, const QuicServerId& server_id,
     QuicEventLoop* event_loop, std::unique_ptr<ProofVerifier> proof_verifier,
     MasqueClient* masque_client)
     : QuicDefaultClient(
           server_address, server_id, MasqueSupportedVersions(),
           MasqueEncapsulatedConfig(), event_loop,
           std::make_unique<MasqueClientDefaultNetworkHelper>(event_loop, this),
           std::move(proof_verifier)),
       masque_client_(masque_client) {}

 MasqueEncapsulatedClient::~MasqueEncapsulatedClient() {
   masque_client_->masque_client_session()->CloseConnectUdpStream(
       masque_encapsulated_client_session());
 }

 std::unique_ptr<QuicSession> MasqueEncapsulatedClient::CreateQuicClientSession(
     const ParsedQuicVersionVector& supported_versions,
     QuicConnection* connection) {
   QUIC_DLOG(INFO) << "Creating MASQUE encapsulated session for "
                   << connection->connection_id();
   return std::make_unique<MasqueEncapsulatedClientSession>(
       *config(), supported_versions, connection, server_id(), crypto_config(),
       push_promise_index(), masque_client_->masque_client_session());
 }

 MasqueEncapsulatedClientSession*
 MasqueEncapsulatedClient::masque_encapsulated_client_session() {
   return static_cast<MasqueEncapsulatedClientSession*>(
       QuicDefaultClient::session());
 }

 }  // namespace quic
	// Copyright 2019 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 "quiche/quic/masque/masque_encapsulated_client.h"

	#include <optional>

	#include "quiche/quic/core/quic_utils.h"
	#include "quiche/quic/masque/masque_client.h"
	#include "quiche/quic/masque/masque_client_session.h"
	#include "quiche/quic/masque/masque_encapsulated_client_session.h"
	#include "quiche/quic/masque/masque_utils.h"
	#include "quiche/quic/tools/quic_client_default_network_helper.h"
	#include "quiche/common/quiche_data_reader.h"
	#include "quiche/common/quiche_data_writer.h"

	namespace quic {

	namespace {

	class ChecksumWriter {
	public:
	explicit ChecksumWriter(quiche::QuicheDataWriter& writer) : writer_(writer) {}
	void IngestUInt16(uint16_t val) { accumulator_ += val; }
	void IngestUInt8(uint8_t val) {
	uint16_t val16 = odd_ ? val : (val << 8);
	accumulator_ += val16;
	odd_ = !odd_;
	}
	bool IngestData(size_t offset, size_t length) {
	quiche::QuicheDataReader reader(
	writer_.data(), std::min<size_t>(offset + length, writer_.capacity()));
	if (!reader.Seek(offset) \|\| reader.BytesRemaining() < length) {
	return false;
	}
	// Handle any potentially off first byte.
	uint8_t first_byte;
	if (odd_ && reader.ReadUInt8(&first_byte)) {
	IngestUInt8(first_byte);
	}
	// Handle each 16-bit word at a time.
	while (reader.BytesRemaining() >= sizeof(uint16_t)) {
	uint16_t word;
	if (!reader.ReadUInt16(&word)) {
	return false;
	}
	IngestUInt16(word);
	}
	// Handle any leftover odd byte.
	uint8_t last_byte;
	if (reader.ReadUInt8(&last_byte)) {
	IngestUInt8(last_byte);
	}
	return true;
	}
	bool WriteChecksumAtOffset(size_t offset) {
	while (accumulator_ >> 16 > 0) {
	accumulator_ = (accumulator_ & 0xffff) + (accumulator_ >> 16);
	}
	accumulator_ = 0xffff & ~accumulator_;
	quiche::QuicheDataWriter writer2(writer_.capacity(), writer_.data());
	return writer2.Seek(offset) && writer2.WriteUInt16(accumulator_);
	}

	private:
	quiche::QuicheDataWriter& writer_;
	uint32_t accumulator_ = 0xffff;
	bool odd_ = false;
	};

	// Custom packet writer that allows getting all of a connection's outgoing
	// packets.
	class MasquePacketWriter : public QuicPacketWriter {
	public:
	explicit MasquePacketWriter(MasqueEncapsulatedClient* client)
	: client_(client) {}
	WriteResult WritePacket(const char* buffer, size_t buf_len,
	const QuicIpAddress& /self_address/,
	const QuicSocketAddress& peer_address,
	PerPacketOptions* /options/) override {
	QUICHE_DCHECK(peer_address.IsInitialized());
	QUIC_DVLOG(1) << "MasquePacketWriter trying to write " << buf_len
	<< " bytes to " << peer_address;
	if (client_->masque_client()->masque_mode() == MasqueMode::kConnectIp) {
	constexpr size_t kIPv4HeaderSize = 20;
	constexpr size_t kIPv4ChecksumOffset = 10;
	constexpr size_t kIPv6HeaderSize = 40;
	constexpr size_t kUdpHeaderSize = 8;
	const size_t udp_length = kUdpHeaderSize + buf_len;
	std::string packet;
	packet.resize(
	(peer_address.host().IsIPv6() ? kIPv6HeaderSize : kIPv4HeaderSize) +
	udp_length);
	quiche::QuicheDataWriter writer(packet.size(), packet.data());
	if (peer_address.host().IsIPv6()) {
	// Write IPv6 header.
	QUICHE_CHECK(writer.WriteUInt8(0x60)); // Version = 6 and DSCP.
	QUICHE_CHECK(writer.WriteUInt8(0)); // DSCP/ECN and flow label.
	QUICHE_CHECK(writer.WriteUInt16(0)); // Flow label.
	QUICHE_CHECK(writer.WriteUInt16(udp_length)); // Payload Length.
	QUICHE_CHECK(writer.WriteUInt8(17)); // Next header = UDP.
	QUICHE_CHECK(writer.WriteUInt8(64)); // Hop limit = 64.
	in6_addr source_address = {};
	if (client_->masque_encapsulated_client_session()
	->local_v6_address()
	.IsIPv6()) {
	source_address = client_->masque_encapsulated_client_session()
	->local_v6_address()
	.GetIPv6();
	}
	QUICHE_CHECK(
	writer.WriteBytes(&source_address, sizeof(source_address)));
	in6_addr destination_address = peer_address.host().GetIPv6();
	QUICHE_CHECK(writer.WriteBytes(&destination_address,
	sizeof(destination_address)));
	} else {
	// Write IPv4 header.
	QUICHE_CHECK(writer.WriteUInt8(0x45)); // Version = 4, IHL = 5.
	QUICHE_CHECK(writer.WriteUInt8(0)); // DSCP/ECN.
	QUICHE_CHECK(writer.WriteUInt16(packet.size())); // Total Length.
	QUICHE_CHECK(writer.WriteUInt32(0)); // No fragmentation.
	QUICHE_CHECK(writer.WriteUInt8(64)); // TTL = 64.
	QUICHE_CHECK(writer.WriteUInt8(17)); // IP Protocol = UDP.
	QUICHE_CHECK(writer.WriteUInt16(0)); // Checksum = 0 initially.
	in_addr source_address = {};
	if (client_->masque_encapsulated_client_session()
	->local_v4_address()
	.IsIPv4()) {
	source_address = client_->masque_encapsulated_client_session()
	->local_v4_address()
	.GetIPv4();
	}
	QUICHE_CHECK(
	writer.WriteBytes(&source_address, sizeof(source_address)));
	in_addr destination_address = peer_address.host().GetIPv4();
	QUICHE_CHECK(writer.WriteBytes(&destination_address,
	sizeof(destination_address)));
	ChecksumWriter ip_checksum_writer(writer);
	QUICHE_CHECK(ip_checksum_writer.IngestData(0, kIPv4HeaderSize));
	QUICHE_CHECK(
	ip_checksum_writer.WriteChecksumAtOffset(kIPv4ChecksumOffset));
	}
	// Write UDP header.
	QUICHE_CHECK(writer.WriteUInt16(0x1234)); // Source port.
	QUICHE_CHECK(
	writer.WriteUInt16(peer_address.port())); // Destination port.
	QUICHE_CHECK(writer.WriteUInt16(udp_length)); // UDP length.
	QUICHE_CHECK(writer.WriteUInt16(0)); // Checksum = 0 initially.
	// Write UDP payload.
	QUICHE_CHECK(writer.WriteBytes(buffer, buf_len));
	ChecksumWriter udp_checksum_writer(writer);
	if (peer_address.host().IsIPv6()) {
	QUICHE_CHECK(udp_checksum_writer.IngestData(8, 32)); // IP addresses.
	udp_checksum_writer.IngestUInt16(0); // High bits of UDP length.
	udp_checksum_writer.IngestUInt16(
	udp_length); // Low bits of UDP length.
	udp_checksum_writer.IngestUInt16(0); // Zeroes.
	udp_checksum_writer.IngestUInt8(0); // Zeroes.
	udp_checksum_writer.IngestUInt8(17); // Next header = UDP.
	QUICHE_CHECK(udp_checksum_writer.IngestData(
	kIPv6HeaderSize, udp_length)); // UDP header and data.
	QUICHE_CHECK(
	udp_checksum_writer.WriteChecksumAtOffset(kIPv6HeaderSize + 6));
	} else {
	QUICHE_CHECK(udp_checksum_writer.IngestData(12, 8)); // IP addresses.
	udp_checksum_writer.IngestUInt8(0); // Zeroes.
	udp_checksum_writer.IngestUInt8(17); // IP Protocol = UDP.
	udp_checksum_writer.IngestUInt16(udp_length); // UDP length.
	QUICHE_CHECK(udp_checksum_writer.IngestData(
	kIPv4HeaderSize, udp_length)); // UDP header and data.
	QUICHE_CHECK(
	udp_checksum_writer.WriteChecksumAtOffset(kIPv4HeaderSize + 6));
	}
	client_->masque_client()->masque_client_session()->SendIpPacket(
	packet, client_->masque_encapsulated_client_session());
	} else {
	absl::string_view packet(buffer, buf_len);
	client_->masque_client()->masque_client_session()->SendPacket(
	packet, peer_address, client_->masque_encapsulated_client_session());
	}
	return WriteResult(WRITE_STATUS_OK, buf_len);
	}

	bool IsWriteBlocked() const override { return false; }

	void SetWritable() override {}

	absl::optional<int> MessageTooBigErrorCode() const override {
	return absl::nullopt;
	}

	QuicByteCount GetMaxPacketSize(
	const QuicSocketAddress& /peer_address/) const override {
	return kMasqueMaxEncapsulatedPacketSize;
	}

	bool SupportsReleaseTime() const override { return false; }

	bool IsBatchMode() const override { return false; }
	QuicPacketBuffer GetNextWriteLocation(
	const QuicIpAddress& /self_address/,
	const QuicSocketAddress& /peer_address/) override {
	return {nullptr, nullptr};
	}

	WriteResult Flush() override { return WriteResult(WRITE_STATUS_OK, 0); }

	private:
	MasqueEncapsulatedClient* client_; // Unowned.
	};

	// Custom network helper that allows injecting a custom packet writer in order
	// to get all of a connection's outgoing packets.
	class MasqueClientDefaultNetworkHelper : public QuicClientDefaultNetworkHelper {
	public:
	MasqueClientDefaultNetworkHelper(QuicEventLoop* event_loop,
	MasqueEncapsulatedClient* client)
	: QuicClientDefaultNetworkHelper(event_loop, client), client_(client) {}
	QuicPacketWriter* CreateQuicPacketWriter() override {
	return new MasquePacketWriter(client_);
	}

	private:
	MasqueEncapsulatedClient* client_; // Unowned.
	};

	} // namespace

	MasqueEncapsulatedClient::MasqueEncapsulatedClient(
	QuicSocketAddress server_address, const QuicServerId& server_id,
	QuicEventLoop* event_loop, std::unique_ptr<ProofVerifier> proof_verifier,
	MasqueClient* masque_client)
	: QuicDefaultClient(
	server_address, server_id, MasqueSupportedVersions(),
	MasqueEncapsulatedConfig(), event_loop,
	std::make_unique<MasqueClientDefaultNetworkHelper>(event_loop, this),
	std::move(proof_verifier)),
	masque_client_(masque_client) {}

	MasqueEncapsulatedClient::~MasqueEncapsulatedClient() {
	masque_client_->masque_client_session()->CloseConnectUdpStream(
	masque_encapsulated_client_session());
	}

	std::unique_ptr<QuicSession> MasqueEncapsulatedClient::CreateQuicClientSession(
	const ParsedQuicVersionVector& supported_versions,
	QuicConnection* connection) {
	QUIC_DLOG(INFO) << "Creating MASQUE encapsulated session for "
	<< connection->connection_id();
	return std::make_unique<MasqueEncapsulatedClientSession>(
	*config(), supported_versions, connection, server_id(), crypto_config(),
	push_promise_index(), masque_client_->masque_client_session());
	}

	MasqueEncapsulatedClientSession*
	MasqueEncapsulatedClient::masque_encapsulated_client_session() {
	return static_cast<MasqueEncapsulatedClientSession*>(
	QuicDefaultClient::session());
	}

	} // namespace quic