blob: 84c6b308417e6a0b036c4c8cce36a729ec0d3d7e [file] [log] [blame]
// 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 "net/quic/quic_framer.h"
#include "base/containers/hash_tables.h"
#include "base/stl_util.h"
#include "net/quic/crypto/crypto_framer.h"
#include "net/quic/crypto/crypto_handshake_message.h"
#include "net/quic/crypto/crypto_protocol.h"
#include "net/quic/crypto/quic_decrypter.h"
#include "net/quic/crypto/quic_encrypter.h"
#include "net/quic/quic_data_reader.h"
#include "net/quic/quic_data_writer.h"
#include "net/quic/quic_flags.h"
#include "net/quic/quic_socket_address_coder.h"
using base::StringPiece;
using std::make_pair;
using std::map;
using std::max;
using std::min;
using std::numeric_limits;
using std::string;
namespace net {
namespace {
// Mask to select the lowest 48 bits of a sequence number.
const QuicPacketSequenceNumber k6ByteSequenceNumberMask =
GG_UINT64_C(0x0000FFFFFFFFFFFF);
const QuicPacketSequenceNumber k4ByteSequenceNumberMask =
GG_UINT64_C(0x00000000FFFFFFFF);
const QuicPacketSequenceNumber k2ByteSequenceNumberMask =
GG_UINT64_C(0x000000000000FFFF);
const QuicPacketSequenceNumber k1ByteSequenceNumberMask =
GG_UINT64_C(0x00000000000000FF);
const QuicConnectionId k1ByteConnectionIdMask = GG_UINT64_C(0x00000000000000FF);
const QuicConnectionId k4ByteConnectionIdMask = GG_UINT64_C(0x00000000FFFFFFFF);
// Number of bits the sequence number length bits are shifted from the right
// edge of the public header.
const uint8 kPublicHeaderSequenceNumberShift = 4;
// New Frame Types, QUIC v. >= 10:
// There are two interpretations for the Frame Type byte in the QUIC protocol,
// resulting in two Frame Types: Special Frame Types and Regular Frame Types.
//
// Regular Frame Types use the Frame Type byte simply. Currently defined
// Regular Frame Types are:
// Padding : 0b 00000000 (0x00)
// ResetStream : 0b 00000001 (0x01)
// ConnectionClose : 0b 00000010 (0x02)
// GoAway : 0b 00000011 (0x03)
// WindowUpdate : 0b 00000100 (0x04)
// Blocked : 0b 00000101 (0x05)
//
// Special Frame Types encode both a Frame Type and corresponding flags
// all in the Frame Type byte. Currently defined Special Frame Types are:
// Stream : 0b 1xxxxxxx
// Ack : 0b 01xxxxxx
// CongestionFeedback : 0b 001xxxxx
//
// Semantics of the flag bits above (the x bits) depends on the frame type.
// Masks to determine if the frame type is a special use
// and for specific special frame types.
const uint8 kQuicFrameTypeSpecialMask = 0xE0; // 0b 11100000
const uint8 kQuicFrameTypeStreamMask = 0x80;
const uint8 kQuicFrameTypeAckMask = 0x40;
const uint8 kQuicFrameTypeCongestionFeedbackMask = 0x20;
// Stream frame relative shifts and masks for interpreting the stream flags.
// StreamID may be 1, 2, 3, or 4 bytes.
const uint8 kQuicStreamIdShift = 2;
const uint8 kQuicStreamIDLengthMask = 0x03;
// Offset may be 0, 2, 3, 4, 5, 6, 7, 8 bytes.
const uint8 kQuicStreamOffsetShift = 3;
const uint8 kQuicStreamOffsetMask = 0x07;
// Data length may be 0 or 2 bytes.
const uint8 kQuicStreamDataLengthShift = 1;
const uint8 kQuicStreamDataLengthMask = 0x01;
// Fin bit may be set or not.
const uint8 kQuicStreamFinShift = 1;
const uint8 kQuicStreamFinMask = 0x01;
// Sequence number size shift used in AckFrames.
const uint8 kQuicSequenceNumberLengthShift = 2;
// Acks may be truncated.
const uint8 kQuicAckTruncatedShift = 1;
const uint8 kQuicAckTruncatedMask = 0x01;
// Acks may not have any nacks.
const uint8 kQuicHasNacksMask = 0x01;
// Returns the absolute value of the difference between |a| and |b|.
QuicPacketSequenceNumber Delta(QuicPacketSequenceNumber a,
QuicPacketSequenceNumber b) {
// Since these are unsigned numbers, we can't just return abs(a - b)
if (a < b) {
return b - a;
}
return a - b;
}
QuicPacketSequenceNumber ClosestTo(QuicPacketSequenceNumber target,
QuicPacketSequenceNumber a,
QuicPacketSequenceNumber b) {
return (Delta(target, a) < Delta(target, b)) ? a : b;
}
QuicSequenceNumberLength ReadSequenceNumberLength(uint8 flags) {
switch (flags & PACKET_FLAGS_6BYTE_SEQUENCE) {
case PACKET_FLAGS_6BYTE_SEQUENCE:
return PACKET_6BYTE_SEQUENCE_NUMBER;
case PACKET_FLAGS_4BYTE_SEQUENCE:
return PACKET_4BYTE_SEQUENCE_NUMBER;
case PACKET_FLAGS_2BYTE_SEQUENCE:
return PACKET_2BYTE_SEQUENCE_NUMBER;
case PACKET_FLAGS_1BYTE_SEQUENCE:
return PACKET_1BYTE_SEQUENCE_NUMBER;
default:
LOG(DFATAL) << "Unreachable case statement.";
return PACKET_6BYTE_SEQUENCE_NUMBER;
}
}
} // namespace
bool QuicFramerVisitorInterface::OnWindowUpdateFrame(
const QuicWindowUpdateFrame& frame) {
return true;
}
bool QuicFramerVisitorInterface::OnBlockedFrame(const QuicBlockedFrame& frame) {
return true;
}
QuicFramer::QuicFramer(const QuicVersionVector& supported_versions,
QuicTime creation_time,
bool is_server)
: visitor_(NULL),
fec_builder_(NULL),
entropy_calculator_(NULL),
error_(QUIC_NO_ERROR),
last_sequence_number_(0),
last_serialized_connection_id_(0),
supported_versions_(supported_versions),
decrypter_level_(ENCRYPTION_NONE),
alternative_decrypter_level_(ENCRYPTION_NONE),
alternative_decrypter_latch_(false),
is_server_(is_server),
validate_flags_(true),
creation_time_(creation_time),
last_timestamp_(QuicTime::Delta::Zero()) {
DCHECK(!supported_versions.empty());
quic_version_ = supported_versions_[0];
decrypter_.reset(QuicDecrypter::Create(kNULL));
encrypter_[ENCRYPTION_NONE].reset(
QuicEncrypter::Create(kNULL));
}
QuicFramer::~QuicFramer() {}
// static
size_t QuicFramer::GetMinStreamFrameSize(QuicStreamId stream_id,
QuicStreamOffset offset,
bool last_frame_in_packet,
InFecGroup is_in_fec_group) {
bool no_stream_frame_length = last_frame_in_packet &&
is_in_fec_group == NOT_IN_FEC_GROUP;
return kQuicFrameTypeSize + GetStreamIdSize(stream_id) +
GetStreamOffsetSize(offset) +
(no_stream_frame_length ? 0 : kQuicStreamPayloadLengthSize);
}
// static
size_t QuicFramer::GetMinAckFrameSize(
QuicSequenceNumberLength sequence_number_length,
QuicSequenceNumberLength largest_observed_length) {
return kQuicFrameTypeSize + kQuicEntropyHashSize +
largest_observed_length + kQuicDeltaTimeLargestObservedSize;
}
// static
size_t QuicFramer::GetStopWaitingFrameSize(
QuicSequenceNumberLength sequence_number_length) {
return kQuicFrameTypeSize + kQuicEntropyHashSize +
sequence_number_length;
}
// static
size_t QuicFramer::GetMinRstStreamFrameSize() {
return kQuicFrameTypeSize + kQuicMaxStreamIdSize +
kQuicMaxStreamOffsetSize + kQuicErrorCodeSize +
kQuicErrorDetailsLengthSize;
}
// static
size_t QuicFramer::GetMinConnectionCloseFrameSize() {
return kQuicFrameTypeSize + kQuicErrorCodeSize + kQuicErrorDetailsLengthSize;
}
// static
size_t QuicFramer::GetMinGoAwayFrameSize() {
return kQuicFrameTypeSize + kQuicErrorCodeSize + kQuicErrorDetailsLengthSize +
kQuicMaxStreamIdSize;
}
// static
size_t QuicFramer::GetWindowUpdateFrameSize() {
return kQuicFrameTypeSize + kQuicMaxStreamIdSize + kQuicMaxStreamOffsetSize;
}
// static
size_t QuicFramer::GetBlockedFrameSize() {
return kQuicFrameTypeSize + kQuicMaxStreamIdSize;
}
// static
size_t QuicFramer::GetStreamIdSize(QuicStreamId stream_id) {
// Sizes are 1 through 4 bytes.
for (int i = 1; i <= 4; ++i) {
stream_id >>= 8;
if (stream_id == 0) {
return i;
}
}
LOG(DFATAL) << "Failed to determine StreamIDSize.";
return 4;
}
// static
size_t QuicFramer::GetStreamOffsetSize(QuicStreamOffset offset) {
// 0 is a special case.
if (offset == 0) {
return 0;
}
// 2 through 8 are the remaining sizes.
offset >>= 8;
for (int i = 2; i <= 8; ++i) {
offset >>= 8;
if (offset == 0) {
return i;
}
}
LOG(DFATAL) << "Failed to determine StreamOffsetSize.";
return 8;
}
// static
size_t QuicFramer::GetVersionNegotiationPacketSize(size_t number_versions) {
return kPublicFlagsSize + PACKET_8BYTE_CONNECTION_ID +
number_versions * kQuicVersionSize;
}
bool QuicFramer::IsSupportedVersion(const QuicVersion version) const {
for (size_t i = 0; i < supported_versions_.size(); ++i) {
if (version == supported_versions_[i]) {
return true;
}
}
return false;
}
size_t QuicFramer::GetSerializedFrameLength(
const QuicFrame& frame,
size_t free_bytes,
bool first_frame,
bool last_frame,
InFecGroup is_in_fec_group,
QuicSequenceNumberLength sequence_number_length) {
if (frame.type == PADDING_FRAME) {
// PADDING implies end of packet.
return free_bytes;
}
size_t frame_len =
ComputeFrameLength(frame, last_frame, is_in_fec_group,
sequence_number_length);
if (frame_len <= free_bytes) {
// Frame fits within packet. Note that acks may be truncated.
return frame_len;
}
// Only truncate the first frame in a packet, so if subsequent ones go
// over, stop including more frames.
if (!first_frame) {
return 0;
}
bool can_truncate = frame.type == ACK_FRAME &&
free_bytes >= GetMinAckFrameSize(PACKET_6BYTE_SEQUENCE_NUMBER,
PACKET_6BYTE_SEQUENCE_NUMBER);
if (can_truncate) {
// Truncate the frame so the packet will not exceed kMaxPacketSize.
// Note that we may not use every byte of the writer in this case.
DVLOG(1) << "Truncating large frame, free bytes: " << free_bytes;
return free_bytes;
}
if (!FLAGS_quic_allow_oversized_packets_for_test) {
return 0;
}
LOG(DFATAL) << "Packet size too small to fit frame.";
return frame_len;
}
QuicFramer::AckFrameInfo::AckFrameInfo() : max_delta(0) {}
QuicFramer::AckFrameInfo::~AckFrameInfo() {}
QuicPacketEntropyHash QuicFramer::GetPacketEntropyHash(
const QuicPacketHeader& header) const {
return header.entropy_flag << (header.packet_sequence_number % 8);
}
SerializedPacket QuicFramer::BuildDataPacket(
const QuicPacketHeader& header,
const QuicFrames& frames,
size_t packet_size) {
QuicDataWriter writer(packet_size);
const SerializedPacket kNoPacket(
0, PACKET_1BYTE_SEQUENCE_NUMBER, NULL, 0, NULL);
if (!AppendPacketHeader(header, &writer)) {
LOG(DFATAL) << "AppendPacketHeader failed";
return kNoPacket;
}
for (size_t i = 0; i < frames.size(); ++i) {
const QuicFrame& frame = frames[i];
// Determine if we should write stream frame length in header.
const bool no_stream_frame_length =
(header.is_in_fec_group == NOT_IN_FEC_GROUP) &&
(i == frames.size() - 1);
if (!AppendTypeByte(frame, no_stream_frame_length, &writer)) {
LOG(DFATAL) << "AppendTypeByte failed";
return kNoPacket;
}
switch (frame.type) {
case PADDING_FRAME:
writer.WritePadding();
break;
case STREAM_FRAME:
if (!AppendStreamFrame(
*frame.stream_frame, no_stream_frame_length, &writer)) {
LOG(DFATAL) << "AppendStreamFrame failed";
return kNoPacket;
}
break;
case ACK_FRAME:
if (!AppendAckFrameAndTypeByte(
header, *frame.ack_frame, &writer)) {
LOG(DFATAL) << "AppendAckFrameAndTypeByte failed";
return kNoPacket;
}
break;
case CONGESTION_FEEDBACK_FRAME:
if (!AppendCongestionFeedbackFrame(
*frame.congestion_feedback_frame, &writer)) {
LOG(DFATAL) << "AppendCongestionFeedbackFrame failed";
return kNoPacket;
}
break;
case STOP_WAITING_FRAME:
if (!AppendStopWaitingFrame(
header, *frame.stop_waiting_frame, &writer)) {
LOG(DFATAL) << "AppendStopWaitingFrame failed";
return kNoPacket;
}
break;
case PING_FRAME:
if (quic_version_ == QUIC_VERSION_16) {
LOG(DFATAL) << "Attempt to add a PingFrame in "
<< QuicVersionToString(quic_version_);
return kNoPacket;
}
// Ping has no payload.
break;
case RST_STREAM_FRAME:
if (!AppendRstStreamFrame(*frame.rst_stream_frame, &writer)) {
LOG(DFATAL) << "AppendRstStreamFrame failed";
return kNoPacket;
}
break;
case CONNECTION_CLOSE_FRAME:
if (!AppendConnectionCloseFrame(
*frame.connection_close_frame, &writer)) {
LOG(DFATAL) << "AppendConnectionCloseFrame failed";
return kNoPacket;
}
break;
case GOAWAY_FRAME:
if (!AppendGoAwayFrame(*frame.goaway_frame, &writer)) {
LOG(DFATAL) << "AppendGoAwayFrame failed";
return kNoPacket;
}
break;
case WINDOW_UPDATE_FRAME:
if (!AppendWindowUpdateFrame(*frame.window_update_frame, &writer)) {
LOG(DFATAL) << "AppendWindowUpdateFrame failed";
return kNoPacket;
}
break;
case BLOCKED_FRAME:
if (!AppendBlockedFrame(*frame.blocked_frame, &writer)) {
LOG(DFATAL) << "AppendBlockedFrame failed";
return kNoPacket;
}
break;
default:
RaiseError(QUIC_INVALID_FRAME_DATA);
LOG(DFATAL) << "QUIC_INVALID_FRAME_DATA";
return kNoPacket;
}
}
// Save the length before writing, because take clears it.
const size_t len = writer.length();
// Less than or equal because truncated acks end up with max_plaintex_size
// length, even though they're typically slightly shorter.
DCHECK_LE(len, packet_size);
QuicPacket* packet = QuicPacket::NewDataPacket(
writer.take(), len, true, header.public_header.connection_id_length,
header.public_header.version_flag,
header.public_header.sequence_number_length);
if (fec_builder_) {
fec_builder_->OnBuiltFecProtectedPayload(header,
packet->FecProtectedData());
}
return SerializedPacket(header.packet_sequence_number,
header.public_header.sequence_number_length, packet,
GetPacketEntropyHash(header), NULL);
}
SerializedPacket QuicFramer::BuildFecPacket(const QuicPacketHeader& header,
const QuicFecData& fec) {
DCHECK_EQ(IN_FEC_GROUP, header.is_in_fec_group);
DCHECK_NE(0u, header.fec_group);
size_t len = GetPacketHeaderSize(header);
len += fec.redundancy.length();
QuicDataWriter writer(len);
const SerializedPacket kNoPacket(
0, PACKET_1BYTE_SEQUENCE_NUMBER, NULL, 0, NULL);
if (!AppendPacketHeader(header, &writer)) {
LOG(DFATAL) << "AppendPacketHeader failed";
return kNoPacket;
}
if (!writer.WriteBytes(fec.redundancy.data(), fec.redundancy.length())) {
LOG(DFATAL) << "Failed to add FEC";
return kNoPacket;
}
return SerializedPacket(
header.packet_sequence_number,
header.public_header.sequence_number_length,
QuicPacket::NewFecPacket(writer.take(), len, true,
header.public_header.connection_id_length,
header.public_header.version_flag,
header.public_header.sequence_number_length),
GetPacketEntropyHash(header), NULL);
}
// static
QuicEncryptedPacket* QuicFramer::BuildPublicResetPacket(
const QuicPublicResetPacket& packet) {
DCHECK(packet.public_header.reset_flag);
CryptoHandshakeMessage reset;
reset.set_tag(kPRST);
reset.SetValue(kRNON, packet.nonce_proof);
reset.SetValue(kRSEQ, packet.rejected_sequence_number);
if (!packet.client_address.address().empty()) {
// packet.client_address is non-empty.
QuicSocketAddressCoder address_coder(packet.client_address);
string serialized_address = address_coder.Encode();
if (serialized_address.empty()) {
return NULL;
}
reset.SetStringPiece(kCADR, serialized_address);
}
const QuicData& reset_serialized = reset.GetSerialized();
size_t len =
kPublicFlagsSize + PACKET_8BYTE_CONNECTION_ID + reset_serialized.length();
QuicDataWriter writer(len);
uint8 flags = static_cast<uint8>(PACKET_PUBLIC_FLAGS_RST |
PACKET_PUBLIC_FLAGS_8BYTE_CONNECTION_ID);
if (!writer.WriteUInt8(flags)) {
return NULL;
}
if (!writer.WriteUInt64(packet.public_header.connection_id)) {
return NULL;
}
if (!writer.WriteBytes(reset_serialized.data(), reset_serialized.length())) {
return NULL;
}
return new QuicEncryptedPacket(writer.take(), len, true);
}
QuicEncryptedPacket* QuicFramer::BuildVersionNegotiationPacket(
const QuicPacketPublicHeader& header,
const QuicVersionVector& supported_versions) {
DCHECK(header.version_flag);
size_t len = GetVersionNegotiationPacketSize(supported_versions.size());
QuicDataWriter writer(len);
uint8 flags = static_cast<uint8>(PACKET_PUBLIC_FLAGS_VERSION |
PACKET_PUBLIC_FLAGS_8BYTE_CONNECTION_ID);
if (!writer.WriteUInt8(flags)) {
return NULL;
}
if (!writer.WriteUInt64(header.connection_id)) {
return NULL;
}
for (size_t i = 0; i < supported_versions.size(); ++i) {
if (!writer.WriteUInt32(QuicVersionToQuicTag(supported_versions[i]))) {
return NULL;
}
}
return new QuicEncryptedPacket(writer.take(), len, true);
}
bool QuicFramer::ProcessPacket(const QuicEncryptedPacket& packet) {
DCHECK(!reader_.get());
reader_.reset(new QuicDataReader(packet.data(), packet.length()));
visitor_->OnPacket();
// First parse the public header.
QuicPacketPublicHeader public_header;
if (!ProcessPublicHeader(&public_header)) {
DLOG(WARNING) << "Unable to process public header.";
DCHECK_NE("", detailed_error_);
return RaiseError(QUIC_INVALID_PACKET_HEADER);
}
if (!visitor_->OnUnauthenticatedPublicHeader(public_header)) {
// The visitor suppresses further processing of the packet.
reader_.reset(NULL);
return true;
}
if (is_server_ && public_header.version_flag &&
public_header.versions[0] != quic_version_) {
if (!visitor_->OnProtocolVersionMismatch(public_header.versions[0])) {
reader_.reset(NULL);
return true;
}
}
bool rv;
if (!is_server_ && public_header.version_flag) {
rv = ProcessVersionNegotiationPacket(&public_header);
} else if (public_header.reset_flag) {
rv = ProcessPublicResetPacket(public_header);
} else {
rv = ProcessDataPacket(public_header, packet);
}
reader_.reset(NULL);
return rv;
}
bool QuicFramer::ProcessVersionNegotiationPacket(
QuicPacketPublicHeader* public_header) {
DCHECK(!is_server_);
// Try reading at least once to raise error if the packet is invalid.
do {
QuicTag version;
if (!reader_->ReadBytes(&version, kQuicVersionSize)) {
set_detailed_error("Unable to read supported version in negotiation.");
return RaiseError(QUIC_INVALID_VERSION_NEGOTIATION_PACKET);
}
public_header->versions.push_back(QuicTagToQuicVersion(version));
} while (!reader_->IsDoneReading());
visitor_->OnVersionNegotiationPacket(*public_header);
return true;
}
bool QuicFramer::ProcessDataPacket(
const QuicPacketPublicHeader& public_header,
const QuicEncryptedPacket& packet) {
QuicPacketHeader header(public_header);
if (!ProcessPacketHeader(&header, packet)) {
DLOG(WARNING) << "Unable to process data packet header.";
return false;
}
if (!visitor_->OnPacketHeader(header)) {
// The visitor suppresses further processing of the packet.
return true;
}
if (packet.length() > kMaxPacketSize) {
DLOG(WARNING) << "Packet too large: " << packet.length();
return RaiseError(QUIC_PACKET_TOO_LARGE);
}
// Handle the payload.
if (!header.fec_flag) {
if (header.is_in_fec_group == IN_FEC_GROUP) {
StringPiece payload = reader_->PeekRemainingPayload();
visitor_->OnFecProtectedPayload(payload);
}
if (!ProcessFrameData(header)) {
DCHECK_NE(QUIC_NO_ERROR, error_); // ProcessFrameData sets the error.
DLOG(WARNING) << "Unable to process frame data.";
return false;
}
} else {
QuicFecData fec_data;
fec_data.fec_group = header.fec_group;
fec_data.redundancy = reader_->ReadRemainingPayload();
visitor_->OnFecData(fec_data);
}
visitor_->OnPacketComplete();
return true;
}
bool QuicFramer::ProcessPublicResetPacket(
const QuicPacketPublicHeader& public_header) {
QuicPublicResetPacket packet(public_header);
scoped_ptr<CryptoHandshakeMessage> reset(
CryptoFramer::ParseMessage(reader_->ReadRemainingPayload()));
if (!reset.get()) {
set_detailed_error("Unable to read reset message.");
return RaiseError(QUIC_INVALID_PUBLIC_RST_PACKET);
}
if (reset->tag() != kPRST) {
set_detailed_error("Incorrect message tag.");
return RaiseError(QUIC_INVALID_PUBLIC_RST_PACKET);
}
if (reset->GetUint64(kRNON, &packet.nonce_proof) != QUIC_NO_ERROR) {
set_detailed_error("Unable to read nonce proof.");
return RaiseError(QUIC_INVALID_PUBLIC_RST_PACKET);
}
// TODO(satyamshekhar): validate nonce to protect against DoS.
if (reset->GetUint64(kRSEQ, &packet.rejected_sequence_number) !=
QUIC_NO_ERROR) {
set_detailed_error("Unable to read rejected sequence number.");
return RaiseError(QUIC_INVALID_PUBLIC_RST_PACKET);
}
StringPiece address;
if (reset->GetStringPiece(kCADR, &address)) {
QuicSocketAddressCoder address_coder;
if (address_coder.Decode(address.data(), address.length())) {
packet.client_address = IPEndPoint(address_coder.ip(),
address_coder.port());
}
}
visitor_->OnPublicResetPacket(packet);
return true;
}
bool QuicFramer::ProcessRevivedPacket(QuicPacketHeader* header,
StringPiece payload) {
DCHECK(!reader_.get());
visitor_->OnRevivedPacket();
header->entropy_hash = GetPacketEntropyHash(*header);
if (!visitor_->OnPacketHeader(*header)) {
return true;
}
if (payload.length() > kMaxPacketSize) {
set_detailed_error("Revived packet too large.");
return RaiseError(QUIC_PACKET_TOO_LARGE);
}
reader_.reset(new QuicDataReader(payload.data(), payload.length()));
if (!ProcessFrameData(*header)) {
DCHECK_NE(QUIC_NO_ERROR, error_); // ProcessFrameData sets the error.
DLOG(WARNING) << "Unable to process frame data.";
return false;
}
visitor_->OnPacketComplete();
reader_.reset(NULL);
return true;
}
bool QuicFramer::AppendPacketHeader(const QuicPacketHeader& header,
QuicDataWriter* writer) {
DVLOG(1) << "Appending header: " << header;
DCHECK(header.fec_group > 0 || header.is_in_fec_group == NOT_IN_FEC_GROUP);
uint8 public_flags = 0;
if (header.public_header.reset_flag) {
public_flags |= PACKET_PUBLIC_FLAGS_RST;
}
if (header.public_header.version_flag) {
public_flags |= PACKET_PUBLIC_FLAGS_VERSION;
}
public_flags |=
GetSequenceNumberFlags(header.public_header.sequence_number_length)
<< kPublicHeaderSequenceNumberShift;
switch (header.public_header.connection_id_length) {
case PACKET_0BYTE_CONNECTION_ID:
if (!writer->WriteUInt8(
public_flags | PACKET_PUBLIC_FLAGS_0BYTE_CONNECTION_ID)) {
return false;
}
break;
case PACKET_1BYTE_CONNECTION_ID:
if (!writer->WriteUInt8(
public_flags | PACKET_PUBLIC_FLAGS_1BYTE_CONNECTION_ID)) {
return false;
}
if (!writer->WriteUInt8(
header.public_header.connection_id & k1ByteConnectionIdMask)) {
return false;
}
break;
case PACKET_4BYTE_CONNECTION_ID:
if (!writer->WriteUInt8(
public_flags | PACKET_PUBLIC_FLAGS_4BYTE_CONNECTION_ID)) {
return false;
}
if (!writer->WriteUInt32(
header.public_header.connection_id & k4ByteConnectionIdMask)) {
return false;
}
break;
case PACKET_8BYTE_CONNECTION_ID:
if (!writer->WriteUInt8(
public_flags | PACKET_PUBLIC_FLAGS_8BYTE_CONNECTION_ID)) {
return false;
}
if (!writer->WriteUInt64(header.public_header.connection_id)) {
return false;
}
break;
}
last_serialized_connection_id_ = header.public_header.connection_id;
if (header.public_header.version_flag) {
DCHECK(!is_server_);
writer->WriteUInt32(QuicVersionToQuicTag(quic_version_));
}
if (!AppendPacketSequenceNumber(header.public_header.sequence_number_length,
header.packet_sequence_number, writer)) {
return false;
}
uint8 private_flags = 0;
if (header.entropy_flag) {
private_flags |= PACKET_PRIVATE_FLAGS_ENTROPY;
}
if (header.is_in_fec_group == IN_FEC_GROUP) {
private_flags |= PACKET_PRIVATE_FLAGS_FEC_GROUP;
}
if (header.fec_flag) {
private_flags |= PACKET_PRIVATE_FLAGS_FEC;
}
if (!writer->WriteUInt8(private_flags)) {
return false;
}
// The FEC group number is the sequence number of the first fec
// protected packet, or 0 if this packet is not protected.
if (header.is_in_fec_group == IN_FEC_GROUP) {
DCHECK_GE(header.packet_sequence_number, header.fec_group);
DCHECK_GT(255u, header.packet_sequence_number - header.fec_group);
// Offset from the current packet sequence number to the first fec
// protected packet.
uint8 first_fec_protected_packet_offset =
header.packet_sequence_number - header.fec_group;
if (!writer->WriteBytes(&first_fec_protected_packet_offset, 1)) {
return false;
}
}
return true;
}
const QuicTime::Delta QuicFramer::CalculateTimestampFromWire(
uint32 time_delta_us) {
// The new time_delta might have wrapped to the next epoch, or it
// might have reverse wrapped to the previous epoch, or it might
// remain in the same epoch. Select the time closest to the previous
// time.
//
// epoch_delta is the delta between epochs. A delta is 4 bytes of
// microseconds.
const uint64 epoch_delta = GG_UINT64_C(1) << 32;
uint64 epoch = last_timestamp_.ToMicroseconds() & ~(epoch_delta - 1);
// Wrapping is safe here because a wrapped value will not be ClosestTo below.
uint64 prev_epoch = epoch - epoch_delta;
uint64 next_epoch = epoch + epoch_delta;
uint64 time = ClosestTo(last_timestamp_.ToMicroseconds(),
epoch + time_delta_us,
ClosestTo(last_timestamp_.ToMicroseconds(),
prev_epoch + time_delta_us,
next_epoch + time_delta_us));
return QuicTime::Delta::FromMicroseconds(time);
}
QuicPacketSequenceNumber QuicFramer::CalculatePacketSequenceNumberFromWire(
QuicSequenceNumberLength sequence_number_length,
QuicPacketSequenceNumber packet_sequence_number) const {
// The new sequence number might have wrapped to the next epoch, or
// it might have reverse wrapped to the previous epoch, or it might
// remain in the same epoch. Select the sequence number closest to the
// next expected sequence number, the previous sequence number plus 1.
// epoch_delta is the delta between epochs the sequence number was serialized
// with, so the correct value is likely the same epoch as the last sequence
// number or an adjacent epoch.
const QuicPacketSequenceNumber epoch_delta =
GG_UINT64_C(1) << (8 * sequence_number_length);
QuicPacketSequenceNumber next_sequence_number = last_sequence_number_ + 1;
QuicPacketSequenceNumber epoch = last_sequence_number_ & ~(epoch_delta - 1);
QuicPacketSequenceNumber prev_epoch = epoch - epoch_delta;
QuicPacketSequenceNumber next_epoch = epoch + epoch_delta;
return ClosestTo(next_sequence_number,
epoch + packet_sequence_number,
ClosestTo(next_sequence_number,
prev_epoch + packet_sequence_number,
next_epoch + packet_sequence_number));
}
bool QuicFramer::ProcessPublicHeader(
QuicPacketPublicHeader* public_header) {
uint8 public_flags;
if (!reader_->ReadBytes(&public_flags, 1)) {
set_detailed_error("Unable to read public flags.");
return false;
}
public_header->reset_flag = (public_flags & PACKET_PUBLIC_FLAGS_RST) != 0;
public_header->version_flag =
(public_flags & PACKET_PUBLIC_FLAGS_VERSION) != 0;
if (validate_flags_ &&
!public_header->version_flag && public_flags > PACKET_PUBLIC_FLAGS_MAX) {
set_detailed_error("Illegal public flags value.");
return false;
}
if (public_header->reset_flag && public_header->version_flag) {
set_detailed_error("Got version flag in reset packet");
return false;
}
switch (public_flags & PACKET_PUBLIC_FLAGS_8BYTE_CONNECTION_ID) {
case PACKET_PUBLIC_FLAGS_8BYTE_CONNECTION_ID:
if (!reader_->ReadUInt64(&public_header->connection_id)) {
set_detailed_error("Unable to read ConnectionId.");
return false;
}
public_header->connection_id_length = PACKET_8BYTE_CONNECTION_ID;
break;
case PACKET_PUBLIC_FLAGS_4BYTE_CONNECTION_ID:
// If the connection_id is truncated, expect to read the last serialized
// connection_id.
if (!reader_->ReadBytes(&public_header->connection_id,
PACKET_4BYTE_CONNECTION_ID)) {
set_detailed_error("Unable to read ConnectionId.");
return false;
}
if ((public_header->connection_id & k4ByteConnectionIdMask) !=
(last_serialized_connection_id_ & k4ByteConnectionIdMask)) {
set_detailed_error("Truncated 4 byte ConnectionId does not match "
"previous connection_id.");
return false;
}
public_header->connection_id_length = PACKET_4BYTE_CONNECTION_ID;
public_header->connection_id = last_serialized_connection_id_;
break;
case PACKET_PUBLIC_FLAGS_1BYTE_CONNECTION_ID:
if (!reader_->ReadBytes(&public_header->connection_id,
PACKET_1BYTE_CONNECTION_ID)) {
set_detailed_error("Unable to read ConnectionId.");
return false;
}
if ((public_header->connection_id & k1ByteConnectionIdMask) !=
(last_serialized_connection_id_ & k1ByteConnectionIdMask)) {
set_detailed_error("Truncated 1 byte ConnectionId does not match "
"previous connection_id.");
return false;
}
public_header->connection_id_length = PACKET_1BYTE_CONNECTION_ID;
public_header->connection_id = last_serialized_connection_id_;
break;
case PACKET_PUBLIC_FLAGS_0BYTE_CONNECTION_ID:
public_header->connection_id_length = PACKET_0BYTE_CONNECTION_ID;
public_header->connection_id = last_serialized_connection_id_;
break;
}
public_header->sequence_number_length =
ReadSequenceNumberLength(
public_flags >> kPublicHeaderSequenceNumberShift);
// Read the version only if the packet is from the client.
// version flag from the server means version negotiation packet.
if (public_header->version_flag && is_server_) {
QuicTag version_tag;
if (!reader_->ReadUInt32(&version_tag)) {
set_detailed_error("Unable to read protocol version.");
return false;
}
// If the version from the new packet is the same as the version of this
// framer, then the public flags should be set to something we understand.
// If not, this raises an error.
QuicVersion version = QuicTagToQuicVersion(version_tag);
if (version == quic_version_ && public_flags > PACKET_PUBLIC_FLAGS_MAX) {
set_detailed_error("Illegal public flags value.");
return false;
}
public_header->versions.push_back(version);
}
return true;
}
// static
QuicSequenceNumberLength QuicFramer::GetMinSequenceNumberLength(
QuicPacketSequenceNumber sequence_number) {
if (sequence_number < 1 << (PACKET_1BYTE_SEQUENCE_NUMBER * 8)) {
return PACKET_1BYTE_SEQUENCE_NUMBER;
} else if (sequence_number < 1 << (PACKET_2BYTE_SEQUENCE_NUMBER * 8)) {
return PACKET_2BYTE_SEQUENCE_NUMBER;
} else if (sequence_number <
GG_UINT64_C(1) << (PACKET_4BYTE_SEQUENCE_NUMBER * 8)) {
return PACKET_4BYTE_SEQUENCE_NUMBER;
} else {
return PACKET_6BYTE_SEQUENCE_NUMBER;
}
}
// static
uint8 QuicFramer::GetSequenceNumberFlags(
QuicSequenceNumberLength sequence_number_length) {
switch (sequence_number_length) {
case PACKET_1BYTE_SEQUENCE_NUMBER:
return PACKET_FLAGS_1BYTE_SEQUENCE;
case PACKET_2BYTE_SEQUENCE_NUMBER:
return PACKET_FLAGS_2BYTE_SEQUENCE;
case PACKET_4BYTE_SEQUENCE_NUMBER:
return PACKET_FLAGS_4BYTE_SEQUENCE;
case PACKET_6BYTE_SEQUENCE_NUMBER:
return PACKET_FLAGS_6BYTE_SEQUENCE;
default:
LOG(DFATAL) << "Unreachable case statement.";
return PACKET_FLAGS_6BYTE_SEQUENCE;
}
}
// static
QuicFramer::AckFrameInfo QuicFramer::GetAckFrameInfo(
const QuicAckFrame& frame) {
AckFrameInfo ack_info;
if (!frame.missing_packets.empty()) {
DCHECK_GE(frame.largest_observed, *frame.missing_packets.rbegin());
size_t cur_range_length = 0;
SequenceNumberSet::const_iterator iter = frame.missing_packets.begin();
QuicPacketSequenceNumber last_missing = *iter;
++iter;
for (; iter != frame.missing_packets.end(); ++iter) {
if (cur_range_length != numeric_limits<uint8>::max() &&
*iter == (last_missing + 1)) {
++cur_range_length;
} else {
ack_info.nack_ranges[last_missing - cur_range_length] =
cur_range_length;
cur_range_length = 0;
}
ack_info.max_delta = max(ack_info.max_delta, *iter - last_missing);
last_missing = *iter;
}
// Include the last nack range.
ack_info.nack_ranges[last_missing - cur_range_length] = cur_range_length;
// Include the range to the largest observed.
ack_info.max_delta = max(ack_info.max_delta,
frame.largest_observed - last_missing);
}
return ack_info;
}
bool QuicFramer::ProcessPacketHeader(
QuicPacketHeader* header,
const QuicEncryptedPacket& packet) {
if (!ProcessPacketSequenceNumber(header->public_header.sequence_number_length,
&header->packet_sequence_number)) {
set_detailed_error("Unable to read sequence number.");
return RaiseError(QUIC_INVALID_PACKET_HEADER);
}
if (header->packet_sequence_number == 0u) {
set_detailed_error("Packet sequence numbers cannot be 0.");
return RaiseError(QUIC_INVALID_PACKET_HEADER);
}
if (!visitor_->OnUnauthenticatedHeader(*header)) {
return false;
}
if (!DecryptPayload(*header, packet)) {
set_detailed_error("Unable to decrypt payload.");
return RaiseError(QUIC_DECRYPTION_FAILURE);
}
uint8 private_flags;
if (!reader_->ReadBytes(&private_flags, 1)) {
set_detailed_error("Unable to read private flags.");
return RaiseError(QUIC_INVALID_PACKET_HEADER);
}
if (private_flags > PACKET_PRIVATE_FLAGS_MAX) {
set_detailed_error("Illegal private flags value.");
return RaiseError(QUIC_INVALID_PACKET_HEADER);
}
header->entropy_flag = (private_flags & PACKET_PRIVATE_FLAGS_ENTROPY) != 0;
header->fec_flag = (private_flags & PACKET_PRIVATE_FLAGS_FEC) != 0;
if ((private_flags & PACKET_PRIVATE_FLAGS_FEC_GROUP) != 0) {
header->is_in_fec_group = IN_FEC_GROUP;
uint8 first_fec_protected_packet_offset;
if (!reader_->ReadBytes(&first_fec_protected_packet_offset, 1)) {
set_detailed_error("Unable to read first fec protected packet offset.");
return RaiseError(QUIC_INVALID_PACKET_HEADER);
}
if (first_fec_protected_packet_offset >= header->packet_sequence_number) {
set_detailed_error("First fec protected packet offset must be less "
"than the sequence number.");
return RaiseError(QUIC_INVALID_PACKET_HEADER);
}
header->fec_group =
header->packet_sequence_number - first_fec_protected_packet_offset;
}
header->entropy_hash = GetPacketEntropyHash(*header);
// Set the last sequence number after we have decrypted the packet
// so we are confident is not attacker controlled.
last_sequence_number_ = header->packet_sequence_number;
return true;
}
bool QuicFramer::ProcessPacketSequenceNumber(
QuicSequenceNumberLength sequence_number_length,
QuicPacketSequenceNumber* sequence_number) {
QuicPacketSequenceNumber wire_sequence_number = 0u;
if (!reader_->ReadBytes(&wire_sequence_number, sequence_number_length)) {
return false;
}
// TODO(ianswett): Explore the usefulness of trying multiple sequence numbers
// in case the first guess is incorrect.
*sequence_number =
CalculatePacketSequenceNumberFromWire(sequence_number_length,
wire_sequence_number);
return true;
}
bool QuicFramer::ProcessFrameData(const QuicPacketHeader& header) {
if (reader_->IsDoneReading()) {
set_detailed_error("Packet has no frames.");
return RaiseError(QUIC_MISSING_PAYLOAD);
}
while (!reader_->IsDoneReading()) {
uint8 frame_type;
if (!reader_->ReadBytes(&frame_type, 1)) {
set_detailed_error("Unable to read frame type.");
return RaiseError(QUIC_INVALID_FRAME_DATA);
}
if (frame_type & kQuicFrameTypeSpecialMask) {
// Stream Frame
if (frame_type & kQuicFrameTypeStreamMask) {
QuicStreamFrame frame;
if (!ProcessStreamFrame(frame_type, &frame)) {
return RaiseError(QUIC_INVALID_STREAM_DATA);
}
if (!visitor_->OnStreamFrame(frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
// Ack Frame
if (frame_type & kQuicFrameTypeAckMask) {
QuicAckFrame frame;
if (!ProcessAckFrame(frame_type, &frame)) {
return RaiseError(QUIC_INVALID_ACK_DATA);
}
if (!visitor_->OnAckFrame(frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
// Congestion Feedback Frame
if (frame_type & kQuicFrameTypeCongestionFeedbackMask) {
if (quic_version_ > QUIC_VERSION_22) {
set_detailed_error("Congestion Feedback Frame has been deprecated.");
DLOG(WARNING) << "Congestion Feedback Frame has been deprecated.";
}
QuicCongestionFeedbackFrame frame;
if (!ProcessCongestionFeedbackFrame(&frame)) {
return RaiseError(QUIC_INVALID_CONGESTION_FEEDBACK_DATA);
}
if (!visitor_->OnCongestionFeedbackFrame(frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
// This was a special frame type that did not match any
// of the known ones. Error.
set_detailed_error("Illegal frame type.");
DLOG(WARNING) << "Illegal frame type: "
<< static_cast<int>(frame_type);
return RaiseError(QUIC_INVALID_FRAME_DATA);
}
switch (frame_type) {
case PADDING_FRAME:
// We're done with the packet.
return true;
case RST_STREAM_FRAME: {
QuicRstStreamFrame frame;
if (!ProcessRstStreamFrame(&frame)) {
return RaiseError(QUIC_INVALID_RST_STREAM_DATA);
}
if (!visitor_->OnRstStreamFrame(frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
case CONNECTION_CLOSE_FRAME: {
QuicConnectionCloseFrame frame;
if (!ProcessConnectionCloseFrame(&frame)) {
return RaiseError(QUIC_INVALID_CONNECTION_CLOSE_DATA);
}
if (!visitor_->OnConnectionCloseFrame(frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
case GOAWAY_FRAME: {
QuicGoAwayFrame goaway_frame;
if (!ProcessGoAwayFrame(&goaway_frame)) {
return RaiseError(QUIC_INVALID_GOAWAY_DATA);
}
if (!visitor_->OnGoAwayFrame(goaway_frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
case WINDOW_UPDATE_FRAME: {
QuicWindowUpdateFrame window_update_frame;
if (!ProcessWindowUpdateFrame(&window_update_frame)) {
return RaiseError(QUIC_INVALID_WINDOW_UPDATE_DATA);
}
if (!visitor_->OnWindowUpdateFrame(window_update_frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
case BLOCKED_FRAME: {
QuicBlockedFrame blocked_frame;
if (!ProcessBlockedFrame(&blocked_frame)) {
return RaiseError(QUIC_INVALID_BLOCKED_DATA);
}
if (!visitor_->OnBlockedFrame(blocked_frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
case STOP_WAITING_FRAME: {
QuicStopWaitingFrame stop_waiting_frame;
if (!ProcessStopWaitingFrame(header, &stop_waiting_frame)) {
return RaiseError(QUIC_INVALID_STOP_WAITING_DATA);
}
if (!visitor_->OnStopWaitingFrame(stop_waiting_frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
case PING_FRAME: {
if (quic_version_ == QUIC_VERSION_16) {
LOG(DFATAL) << "Trying to read a Ping in "
<< QuicVersionToString(quic_version_);
return RaiseError(QUIC_INTERNAL_ERROR);
}
// Ping has no payload.
QuicPingFrame ping_frame;
if (!visitor_->OnPingFrame(ping_frame)) {
DVLOG(1) << "Visitor asked to stop further processing.";
// Returning true since there was no parsing error.
return true;
}
continue;
}
default:
set_detailed_error("Illegal frame type.");
DLOG(WARNING) << "Illegal frame type: "
<< static_cast<int>(frame_type);
return RaiseError(QUIC_INVALID_FRAME_DATA);
}
}
return true;
}
bool QuicFramer::ProcessStreamFrame(uint8 frame_type,
QuicStreamFrame* frame) {
uint8 stream_flags = frame_type;
stream_flags &= ~kQuicFrameTypeStreamMask;
// Read from right to left: StreamID, Offset, Data Length, Fin.
const uint8 stream_id_length = (stream_flags & kQuicStreamIDLengthMask) + 1;
stream_flags >>= kQuicStreamIdShift;
uint8 offset_length = (stream_flags & kQuicStreamOffsetMask);
// There is no encoding for 1 byte, only 0 and 2 through 8.
if (offset_length > 0) {
offset_length += 1;
}
stream_flags >>= kQuicStreamOffsetShift;
bool has_data_length =
(stream_flags & kQuicStreamDataLengthMask) == kQuicStreamDataLengthMask;
stream_flags >>= kQuicStreamDataLengthShift;
frame->fin = (stream_flags & kQuicStreamFinMask) == kQuicStreamFinShift;
frame->stream_id = 0;
if (!reader_->ReadBytes(&frame->stream_id, stream_id_length)) {
set_detailed_error("Unable to read stream_id.");
return false;
}
frame->offset = 0;
if (!reader_->ReadBytes(&frame->offset, offset_length)) {
set_detailed_error("Unable to read offset.");
return false;
}
StringPiece frame_data;
if (has_data_length) {
if (!reader_->ReadStringPiece16(&frame_data)) {
set_detailed_error("Unable to read frame data.");
return false;
}
} else {
if (!reader_->ReadStringPiece(&frame_data, reader_->BytesRemaining())) {
set_detailed_error("Unable to read frame data.");
return false;
}
}
// Point frame to the right data.
frame->data.Clear();
if (!frame_data.empty()) {
frame->data.Append(const_cast<char*>(frame_data.data()), frame_data.size());
}
return true;
}
bool QuicFramer::ProcessAckFrame(uint8 frame_type, QuicAckFrame* ack_frame) {
// Determine the three lengths from the frame type: largest observed length,
// missing sequence number length, and missing range length.
const QuicSequenceNumberLength missing_sequence_number_length =
ReadSequenceNumberLength(frame_type);
frame_type >>= kQuicSequenceNumberLengthShift;
const QuicSequenceNumberLength largest_observed_sequence_number_length =
ReadSequenceNumberLength(frame_type);
frame_type >>= kQuicSequenceNumberLengthShift;
ack_frame->is_truncated = frame_type & kQuicAckTruncatedMask;
frame_type >>= kQuicAckTruncatedShift;
bool has_nacks = frame_type & kQuicHasNacksMask;
if (!reader_->ReadBytes(&ack_frame->entropy_hash, 1)) {
set_detailed_error("Unable to read entropy hash for received packets.");
return false;
}
if (!reader_->ReadBytes(&ack_frame->largest_observed,
largest_observed_sequence_number_length)) {
set_detailed_error("Unable to read largest observed.");
return false;
}
uint64 delta_time_largest_observed_us;
if (!reader_->ReadUFloat16(&delta_time_largest_observed_us)) {
set_detailed_error("Unable to read delta time largest observed.");
return false;
}
if (delta_time_largest_observed_us == kUFloat16MaxValue) {
ack_frame->delta_time_largest_observed = QuicTime::Delta::Infinite();
} else {
ack_frame->delta_time_largest_observed =
QuicTime::Delta::FromMicroseconds(delta_time_largest_observed_us);
}
if (!ProcessTimestampsInAckFrame(ack_frame)) {
return false;
}
if (!has_nacks) {
return true;
}
uint8 num_missing_ranges;
if (!reader_->ReadBytes(&num_missing_ranges, 1)) {
set_detailed_error("Unable to read num missing packet ranges.");
return false;
}
QuicPacketSequenceNumber last_sequence_number = ack_frame->largest_observed;
for (size_t i = 0; i < num_missing_ranges; ++i) {
QuicPacketSequenceNumber missing_delta = 0;
if (!reader_->ReadBytes(&missing_delta, missing_sequence_number_length)) {
set_detailed_error("Unable to read missing sequence number delta.");
return false;
}
last_sequence_number -= missing_delta;
QuicPacketSequenceNumber range_length = 0;
if (!reader_->ReadBytes(&range_length, PACKET_1BYTE_SEQUENCE_NUMBER)) {
set_detailed_error("Unable to read missing sequence number range.");
return false;
}
for (size_t i = 0; i <= range_length; ++i) {
ack_frame->missing_packets.insert(last_sequence_number - i);
}
// Subtract an extra 1 to ensure ranges are represented efficiently and
// can't overlap by 1 sequence number. This allows a missing_delta of 0
// to represent an adjacent nack range.
last_sequence_number -= (range_length + 1);
}
// Parse the revived packets list.
uint8 num_revived_packets;
if (!reader_->ReadBytes(&num_revived_packets, 1)) {
set_detailed_error("Unable to read num revived packets.");
return false;
}
for (size_t i = 0; i < num_revived_packets; ++i) {
QuicPacketSequenceNumber revived_packet = 0;
if (!reader_->ReadBytes(&revived_packet,
largest_observed_sequence_number_length)) {
set_detailed_error("Unable to read revived packet.");
return false;
}
ack_frame->revived_packets.insert(revived_packet);
}
return true;
}
bool QuicFramer::ProcessTimestampsInAckFrame(QuicAckFrame* ack_frame) {
if (version() > QUIC_VERSION_22 && !ack_frame->is_truncated) {
uint8 num_received_packets;
if (!reader_->ReadBytes(&num_received_packets, 1)) {
set_detailed_error("Unable to read num received packets.");
return false;
}
if (num_received_packets > 0) {
uint8 delta_from_largest_observed;
if (!reader_->ReadBytes(&delta_from_largest_observed,
PACKET_1BYTE_SEQUENCE_NUMBER)) {
set_detailed_error(
"Unable to read sequence delta in received packets.");
return false;
}
QuicPacketSequenceNumber seq_num = ack_frame->largest_observed -
delta_from_largest_observed;
// Time delta from the framer creation.
uint32 time_delta_us;
if (!reader_->ReadBytes(&time_delta_us, sizeof(time_delta_us))) {
set_detailed_error("Unable to read time delta in received packets.");
return false;
}
last_timestamp_ = CalculateTimestampFromWire(time_delta_us);
ack_frame->received_packet_times.push_back(
make_pair(seq_num, creation_time_.Add(last_timestamp_)));
for (uint8 i = 1; i < num_received_packets; ++i) {
if (!reader_->ReadBytes(&delta_from_largest_observed,
PACKET_1BYTE_SEQUENCE_NUMBER)) {
set_detailed_error(
"Unable to read sequence delta in received packets.");
return false;
}
seq_num = ack_frame->largest_observed - delta_from_largest_observed;
// Time delta from the previous timestamp.
uint64 incremental_time_delta_us;
if (!reader_->ReadUFloat16(&incremental_time_delta_us)) {
set_detailed_error(
"Unable to read incremental time delta in received packets.");
return false;
}
last_timestamp_ = last_timestamp_.Add(
QuicTime::Delta::FromMicroseconds(incremental_time_delta_us));
ack_frame->received_packet_times.push_back(
make_pair(seq_num, creation_time_.Add(last_timestamp_)));
}
}
}
return true;
}
bool QuicFramer::ProcessStopWaitingFrame(const QuicPacketHeader& header,
QuicStopWaitingFrame* stop_waiting) {
if (!reader_->ReadBytes(&stop_waiting->entropy_hash, 1)) {
set_detailed_error("Unable to read entropy hash for sent packets.");
return false;
}
QuicPacketSequenceNumber least_unacked_delta = 0;
if (!reader_->ReadBytes(&least_unacked_delta,
header.public_header.sequence_number_length)) {
set_detailed_error("Unable to read least unacked delta.");
return false;
}
DCHECK_GE(header.packet_sequence_number, least_unacked_delta);
stop_waiting->least_unacked =
header.packet_sequence_number - least_unacked_delta;
return true;
}
bool QuicFramer::ProcessCongestionFeedbackFrame(
QuicCongestionFeedbackFrame* frame) {
uint8 feedback_type;
if (!reader_->ReadBytes(&feedback_type, 1)) {
set_detailed_error("Unable to read congestion feedback type.");
return false;
}
frame->type =
static_cast<CongestionFeedbackType>(feedback_type);
switch (frame->type) {
case kTCP: {
CongestionFeedbackMessageTCP* tcp = &frame->tcp;
uint16 receive_window = 0;
if (!reader_->ReadUInt16(&receive_window)) {
set_detailed_error("Unable to read receive window.");
return false;
}
// Simple bit packing, don't send the 4 least significant bits.
tcp->receive_window = static_cast<QuicByteCount>(receive_window) << 4;
break;
}
default:
set_detailed_error("Illegal congestion feedback type.");
DLOG(WARNING) << "Illegal congestion feedback type: "
<< frame->type;
return RaiseError(QUIC_INVALID_FRAME_DATA);
}
return true;
}
bool QuicFramer::ProcessRstStreamFrame(QuicRstStreamFrame* frame) {
if (!reader_->ReadUInt32(&frame->stream_id)) {
set_detailed_error("Unable to read stream_id.");
return false;
}
if (!reader_->ReadUInt64(&frame->byte_offset)) {
set_detailed_error("Unable to read rst stream sent byte offset.");
return false;
}
uint32 error_code;
if (!reader_->ReadUInt32(&error_code)) {
set_detailed_error("Unable to read rst stream error code.");
return false;
}
if (error_code >= QUIC_STREAM_LAST_ERROR ||
error_code < QUIC_STREAM_NO_ERROR) {
set_detailed_error("Invalid rst stream error code.");
return false;
}
frame->error_code = static_cast<QuicRstStreamErrorCode>(error_code);
StringPiece error_details;
if (!reader_->ReadStringPiece16(&error_details)) {
set_detailed_error("Unable to read rst stream error details.");
return false;
}
frame->error_details = error_details.as_string();
return true;
}
bool QuicFramer::ProcessConnectionCloseFrame(QuicConnectionCloseFrame* frame) {
uint32 error_code;
if (!reader_->ReadUInt32(&error_code)) {
set_detailed_error("Unable to read connection close error code.");
return false;
}
if (error_code >= QUIC_LAST_ERROR ||
error_code < QUIC_NO_ERROR) {
set_detailed_error("Invalid error code.");
return false;
}
frame->error_code = static_cast<QuicErrorCode>(error_code);
StringPiece error_details;
if (!reader_->ReadStringPiece16(&error_details)) {
set_detailed_error("Unable to read connection close error details.");
return false;
}
frame->error_details = error_details.as_string();
return true;
}
bool QuicFramer::ProcessGoAwayFrame(QuicGoAwayFrame* frame) {
uint32 error_code;
if (!reader_->ReadUInt32(&error_code)) {
set_detailed_error("Unable to read go away error code.");
return false;
}
frame->error_code = static_cast<QuicErrorCode>(error_code);
if (error_code >= QUIC_LAST_ERROR ||
error_code < QUIC_NO_ERROR) {
set_detailed_error("Invalid error code.");
return false;
}
uint32 stream_id;
if (!reader_->ReadUInt32(&stream_id)) {
set_detailed_error("Unable to read last good stream id.");
return false;
}
frame->last_good_stream_id = static_cast<QuicStreamId>(stream_id);
StringPiece reason_phrase;
if (!reader_->ReadStringPiece16(&reason_phrase)) {
set_detailed_error("Unable to read goaway reason.");
return false;
}
frame->reason_phrase = reason_phrase.as_string();
return true;
}
bool QuicFramer::ProcessWindowUpdateFrame(QuicWindowUpdateFrame* frame) {
if (!reader_->ReadUInt32(&frame->stream_id)) {
set_detailed_error("Unable to read stream_id.");
return false;
}
if (!reader_->ReadUInt64(&frame->byte_offset)) {
set_detailed_error("Unable to read window byte_offset.");
return false;
}
return true;
}
bool QuicFramer::ProcessBlockedFrame(QuicBlockedFrame* frame) {
if (!reader_->ReadUInt32(&frame->stream_id)) {
set_detailed_error("Unable to read stream_id.");
return false;
}
return true;
}
// static
StringPiece QuicFramer::GetAssociatedDataFromEncryptedPacket(
const QuicEncryptedPacket& encrypted,
QuicConnectionIdLength connection_id_length,
bool includes_version,
QuicSequenceNumberLength sequence_number_length) {
return StringPiece(
encrypted.data() + kStartOfHashData, GetStartOfEncryptedData(
connection_id_length, includes_version, sequence_number_length)
- kStartOfHashData);
}
void QuicFramer::SetDecrypter(QuicDecrypter* decrypter,
EncryptionLevel level) {
DCHECK(alternative_decrypter_.get() == NULL);
DCHECK_GE(level, decrypter_level_);
decrypter_.reset(decrypter);
decrypter_level_ = level;
}
void QuicFramer::SetAlternativeDecrypter(QuicDecrypter* decrypter,
EncryptionLevel level,
bool latch_once_used) {
alternative_decrypter_.reset(decrypter);
alternative_decrypter_level_ = level;
alternative_decrypter_latch_ = latch_once_used;
}
const QuicDecrypter* QuicFramer::decrypter() const {
return decrypter_.get();
}
const QuicDecrypter* QuicFramer::alternative_decrypter() const {
return alternative_decrypter_.get();
}
void QuicFramer::SetEncrypter(EncryptionLevel level,
QuicEncrypter* encrypter) {
DCHECK_GE(level, 0);
DCHECK_LT(level, NUM_ENCRYPTION_LEVELS);
encrypter_[level].reset(encrypter);
}
const QuicEncrypter* QuicFramer::encrypter(EncryptionLevel level) const {
DCHECK_GE(level, 0);
DCHECK_LT(level, NUM_ENCRYPTION_LEVELS);
DCHECK(encrypter_[level].get() != NULL);
return encrypter_[level].get();
}
QuicEncryptedPacket* QuicFramer::EncryptPacket(
EncryptionLevel level,
QuicPacketSequenceNumber packet_sequence_number,
const QuicPacket& packet) {
DCHECK(encrypter_[level].get() != NULL);
scoped_ptr<QuicData> out(encrypter_[level]->EncryptPacket(
packet_sequence_number, packet.AssociatedData(), packet.Plaintext()));
if (out.get() == NULL) {
RaiseError(QUIC_ENCRYPTION_FAILURE);
return NULL;
}
StringPiece header_data = packet.BeforePlaintext();
size_t len = header_data.length() + out->length();
char* buffer = new char[len];
// TODO(rch): eliminate this buffer copy by passing in a buffer to Encrypt().
memcpy(buffer, header_data.data(), header_data.length());
memcpy(buffer + header_data.length(), out->data(), out->length());
return new QuicEncryptedPacket(buffer, len, true);
}
size_t QuicFramer::GetMaxPlaintextSize(size_t ciphertext_size) {
// In order to keep the code simple, we don't have the current encryption
// level to hand. Both the NullEncrypter and AES-GCM have a tag length of 12.
size_t min_plaintext_size = ciphertext_size;
for (int i = ENCRYPTION_NONE; i < NUM_ENCRYPTION_LEVELS; i++) {
if (encrypter_[i].get() != NULL) {
size_t size = encrypter_[i]->GetMaxPlaintextSize(ciphertext_size);
if (size < min_plaintext_size) {
min_plaintext_size = size;
}
}
}
return min_plaintext_size;
}
bool QuicFramer::DecryptPayload(const QuicPacketHeader& header,
const QuicEncryptedPacket& packet) {
StringPiece encrypted;
if (!reader_->ReadStringPiece(&encrypted, reader_->BytesRemaining())) {
return false;
}
DCHECK(decrypter_.get() != NULL);
decrypted_.reset(decrypter_->DecryptPacket(
header.packet_sequence_number,
GetAssociatedDataFromEncryptedPacket(
packet,
header.public_header.connection_id_length,
header.public_header.version_flag,
header.public_header.sequence_number_length),
encrypted));
if (decrypted_.get() != NULL) {
visitor_->OnDecryptedPacket(decrypter_level_);
} else if (alternative_decrypter_.get() != NULL) {
decrypted_.reset(alternative_decrypter_->DecryptPacket(
header.packet_sequence_number,
GetAssociatedDataFromEncryptedPacket(
packet,
header.public_header.connection_id_length,
header.public_header.version_flag,
header.public_header.sequence_number_length),
encrypted));
if (decrypted_.get() != NULL) {
visitor_->OnDecryptedPacket(alternative_decrypter_level_);
if (alternative_decrypter_latch_) {
// Switch to the alternative decrypter and latch so that we cannot
// switch back.
decrypter_.reset(alternative_decrypter_.release());
decrypter_level_ = alternative_decrypter_level_;
alternative_decrypter_level_ = ENCRYPTION_NONE;
} else {
// Switch the alternative decrypter so that we use it first next time.
decrypter_.swap(alternative_decrypter_);
EncryptionLevel level = alternative_decrypter_level_;
alternative_decrypter_level_ = decrypter_level_;
decrypter_level_ = level;
}
}
}
if (decrypted_.get() == NULL) {
DLOG(WARNING) << "DecryptPacket failed for sequence_number:"
<< header.packet_sequence_number;
return false;
}
reader_.reset(new QuicDataReader(decrypted_->data(), decrypted_->length()));
return true;
}
size_t QuicFramer::GetAckFrameSize(
const QuicAckFrame& ack,
QuicSequenceNumberLength sequence_number_length) {
AckFrameInfo ack_info = GetAckFrameInfo(ack);
QuicSequenceNumberLength largest_observed_length =
GetMinSequenceNumberLength(ack.largest_observed);
QuicSequenceNumberLength missing_sequence_number_length =
GetMinSequenceNumberLength(ack_info.max_delta);
size_t ack_size = GetMinAckFrameSize(sequence_number_length,
largest_observed_length);
if (!ack_info.nack_ranges.empty()) {
ack_size += kNumberOfNackRangesSize + kNumberOfRevivedPacketsSize;
ack_size += min(ack_info.nack_ranges.size(), kMaxNackRanges) *
(missing_sequence_number_length + PACKET_1BYTE_SEQUENCE_NUMBER);
ack_size += min(ack.revived_packets.size(),
kMaxRevivedPackets) * largest_observed_length;
}
// In version 23, if the ack will be truncated due to too many nack ranges,
// then do not include the number of timestamps (1 byte).
if (version() > QUIC_VERSION_22 &&
ack_info.nack_ranges.size() <= kMaxNackRanges) {
// 1 byte for the number of timestamps.
ack_size += 1;
if (ack.received_packet_times.size() > 0) {
// 1 byte for sequence number, 4 bytes for timestamp for the first
// packet.
ack_size += 5;
// 1 byte for sequence number, 2 bytes for timestamp for the other
// packets.
ack_size += 3 * (ack.received_packet_times.size() - 1);
}
}
return ack_size;
}
size_t QuicFramer::ComputeFrameLength(
const QuicFrame& frame,
bool last_frame_in_packet,
InFecGroup is_in_fec_group,
QuicSequenceNumberLength sequence_number_length) {
switch (frame.type) {
case STREAM_FRAME:
return GetMinStreamFrameSize(frame.stream_frame->stream_id,
frame.stream_frame->offset,
last_frame_in_packet,
is_in_fec_group) +
frame.stream_frame->data.TotalBufferSize();
case ACK_FRAME: {
return GetAckFrameSize(*frame.ack_frame, sequence_number_length);
}
case CONGESTION_FEEDBACK_FRAME: {
size_t len = kQuicFrameTypeSize;
const QuicCongestionFeedbackFrame& congestion_feedback =
*frame.congestion_feedback_frame;
len += 1; // Congestion feedback type.
switch (congestion_feedback.type) {
case kTCP:
len += 2; // Receive window.
break;
default:
set_detailed_error("Illegal feedback type.");
DVLOG(1) << "Illegal feedback type: " << congestion_feedback.type;
break;
}
return len;
}
case STOP_WAITING_FRAME:
return GetStopWaitingFrameSize(sequence_number_length);
case PING_FRAME:
// Ping has no payload.
return kQuicFrameTypeSize;
case RST_STREAM_FRAME:
return GetMinRstStreamFrameSize() +
frame.rst_stream_frame->error_details.size();
case CONNECTION_CLOSE_FRAME:
return GetMinConnectionCloseFrameSize() +
frame.connection_close_frame->error_details.size();
case GOAWAY_FRAME:
return GetMinGoAwayFrameSize() + frame.goaway_frame->reason_phrase.size();
case WINDOW_UPDATE_FRAME:
return GetWindowUpdateFrameSize();
case BLOCKED_FRAME:
return GetBlockedFrameSize();
case PADDING_FRAME:
DCHECK(false);
return 0;
case NUM_FRAME_TYPES:
DCHECK(false);
return 0;
}
// Not reachable, but some Chrome compilers can't figure that out. *sigh*
DCHECK(false);
return 0;
}
bool QuicFramer::AppendTypeByte(const QuicFrame& frame,
bool no_stream_frame_length,
QuicDataWriter* writer) {
uint8 type_byte = 0;
switch (frame.type) {
case STREAM_FRAME: {
if (frame.stream_frame == NULL) {
LOG(DFATAL) << "Failed to append STREAM frame with no stream_frame.";
}
// Fin bit.
type_byte |= frame.stream_frame->fin ? kQuicStreamFinMask : 0;
// Data Length bit.
type_byte <<= kQuicStreamDataLengthShift;
type_byte |= no_stream_frame_length ? 0: kQuicStreamDataLengthMask;
// Offset 3 bits.
type_byte <<= kQuicStreamOffsetShift;
const size_t offset_len = GetStreamOffsetSize(frame.stream_frame->offset);
if (offset_len > 0) {
type_byte |= offset_len - 1;
}
// stream id 2 bits.
type_byte <<= kQuicStreamIdShift;
type_byte |= GetStreamIdSize(frame.stream_frame->stream_id) - 1;
type_byte |= kQuicFrameTypeStreamMask; // Set Stream Frame Type to 1.
break;
}
case ACK_FRAME:
return true;
case CONGESTION_FEEDBACK_FRAME: {
// TODO(ianswett): Use extra 5 bits in the congestion feedback framing.
type_byte = kQuicFrameTypeCongestionFeedbackMask;
break;
}
default:
type_byte = frame.type;
break;
}
return writer->WriteUInt8(type_byte);
}
// static
bool QuicFramer::AppendPacketSequenceNumber(
QuicSequenceNumberLength sequence_number_length,
QuicPacketSequenceNumber packet_sequence_number,
QuicDataWriter* writer) {
// Ensure the entire sequence number can be written.
if (writer->capacity() - writer->length() <
static_cast<size_t>(sequence_number_length)) {
return false;
}
switch (sequence_number_length) {
case PACKET_1BYTE_SEQUENCE_NUMBER:
return writer->WriteUInt8(
packet_sequence_number & k1ByteSequenceNumberMask);
break;
case PACKET_2BYTE_SEQUENCE_NUMBER:
return writer->WriteUInt16(
packet_sequence_number & k2ByteSequenceNumberMask);
break;
case PACKET_4BYTE_SEQUENCE_NUMBER:
return writer->WriteUInt32(
packet_sequence_number & k4ByteSequenceNumberMask);
break;
case PACKET_6BYTE_SEQUENCE_NUMBER:
return writer->WriteUInt48(
packet_sequence_number & k6ByteSequenceNumberMask);
break;
default:
DCHECK(false) << "sequence_number_length: " << sequence_number_length;
return false;
}
}
bool QuicFramer::AppendStreamFrame(
const QuicStreamFrame& frame,
bool no_stream_frame_length,
QuicDataWriter* writer) {
if (!writer->WriteBytes(&frame.stream_id, GetStreamIdSize(frame.stream_id))) {
LOG(DFATAL) << "Writing stream id size failed.";
return false;
}
if (!writer->WriteBytes(&frame.offset, GetStreamOffsetSize(frame.offset))) {
LOG(DFATAL) << "Writing offset size failed.";
return false;
}
if (!no_stream_frame_length) {
if (!writer->WriteUInt16(frame.data.TotalBufferSize())) {
LOG(DFATAL) << "Writing stream frame length failed";
return false;
}
}
if (!writer->WriteIOVector(frame.data)) {
LOG(DFATAL) << "Writing frame data failed.";
return false;
}
return true;
}
// static
void QuicFramer::set_version(const QuicVersion version) {
DCHECK(IsSupportedVersion(version)) << QuicVersionToString(version);
quic_version_ = version;
}
bool QuicFramer::AppendAckFrameAndTypeByte(
const QuicPacketHeader& header,
const QuicAckFrame& frame,
QuicDataWriter* writer) {
AckFrameInfo ack_info = GetAckFrameInfo(frame);
QuicPacketSequenceNumber ack_largest_observed = frame.largest_observed;
QuicSequenceNumberLength largest_observed_length =
GetMinSequenceNumberLength(ack_largest_observed);
QuicSequenceNumberLength missing_sequence_number_length =
GetMinSequenceNumberLength(ack_info.max_delta);
// Determine whether we need to truncate ranges.
size_t available_range_bytes = writer->capacity() - writer->length() -
kNumberOfRevivedPacketsSize - kNumberOfNackRangesSize -
GetMinAckFrameSize(header.public_header.sequence_number_length,
largest_observed_length);
size_t max_num_ranges = available_range_bytes /
(missing_sequence_number_length + PACKET_1BYTE_SEQUENCE_NUMBER);
max_num_ranges = min(kMaxNackRanges, max_num_ranges);
bool truncated = ack_info.nack_ranges.size() > max_num_ranges;
DVLOG_IF(1, truncated) << "Truncating ack from "
<< ack_info.nack_ranges.size() << " ranges to "
<< max_num_ranges;
// Write out the type byte by setting the low order bits and doing shifts
// to make room for the next bit flags to be set.
// Whether there are any nacks.
uint8 type_byte = ack_info.nack_ranges.empty() ? 0 : kQuicHasNacksMask;
// truncating bit.
type_byte <<= kQuicAckTruncatedShift;
type_byte |= truncated ? kQuicAckTruncatedMask : 0;
// Largest observed sequence number length.
type_byte <<= kQuicSequenceNumberLengthShift;
type_byte |= GetSequenceNumberFlags(largest_observed_length);
// Missing sequence number length.
type_byte <<= kQuicSequenceNumberLengthShift;
type_byte |= GetSequenceNumberFlags(missing_sequence_number_length);
type_byte |= kQuicFrameTypeAckMask;
if (!writer->WriteUInt8(type_byte)) {
return false;
}
QuicPacketEntropyHash ack_entropy_hash = frame.entropy_hash;
NackRangeMap::reverse_iterator ack_iter = ack_info.nack_ranges.rbegin();
if (truncated) {
// Skip the nack ranges which the truncated ack won't include and set
// a correct largest observed for the truncated ack.
for (size_t i = 1; i < (ack_info.nack_ranges.size() - max_num_ranges);
++i) {
++ack_iter;
}
// If the last range is followed by acks, include them.
// If the last range is followed by another range, specify the end of the
// range as the largest_observed.
ack_largest_observed = ack_iter->first - 1;
// Also update the entropy so it matches the largest observed.
ack_entropy_hash = entropy_calculator_->EntropyHash(ack_largest_observed);
++ack_iter;
}
if (!writer->WriteUInt8(ack_entropy_hash)) {
return false;
}
if (!AppendPacketSequenceNumber(largest_observed_length,
ack_largest_observed, writer)) {
return false;
}
uint64 delta_time_largest_observed_us = kUFloat16MaxValue;
if (!frame.delta_time_largest_observed.IsInfinite()) {
DCHECK_LE(0u, frame.delta_time_largest_observed.ToMicroseconds());
delta_time_largest_observed_us =
frame.delta_time_largest_observed.ToMicroseconds();
}
if (!writer->WriteUFloat16(delta_time_largest_observed_us)) {
return false;
}
// Timestamp goes at the end of the required fields.
if (version() > QUIC_VERSION_22 && !truncated) {
if (!AppendTimestampToAckFrame(frame, writer)) {
return false;
}
}
if (ack_info.nack_ranges.empty()) {
return true;
}
const uint8 num_missing_ranges =
min(ack_info.nack_ranges.size(), max_num_ranges);
if (!writer->WriteBytes(&num_missing_ranges, 1)) {
return false;
}
int num_ranges_written = 0;
QuicPacketSequenceNumber last_sequence_written = ack_largest_observed;
for (; ack_iter != ack_info.nack_ranges.rend(); ++ack_iter) {
// Calculate the delta to the last number in the range.
QuicPacketSequenceNumber missing_delta =
last_sequence_written - (ack_iter->first + ack_iter->second);
if (!AppendPacketSequenceNumber(missing_sequence_number_length,
missing_delta, writer)) {
return false;
}
if (!AppendPacketSequenceNumber(PACKET_1BYTE_SEQUENCE_NUMBER,
ack_iter->second, writer)) {
return false;
}
// Subtract 1 so a missing_delta of 0 means an adjacent range.
last_sequence_written = ack_iter->first - 1;
++num_ranges_written;
}
DCHECK_EQ(num_missing_ranges, num_ranges_written);
// Append revived packets.
// If not all the revived packets fit, only mention the ones that do.
uint8 num_revived_packets = min(frame.revived_packets.size(),
kMaxRevivedPackets);
num_revived_packets = min(
static_cast<size_t>(num_revived_packets),
(writer->capacity() - writer->length()) / largest_observed_length);
if (!writer->WriteBytes(&num_revived_packets, 1)) {
return false;
}
SequenceNumberSet::const_iterator iter = frame.revived_packets.begin();
for (int i = 0; i < num_revived_packets; ++i, ++iter) {
LOG_IF(DFATAL, !ContainsKey(frame.missing_packets, *iter));
if (!AppendPacketSequenceNumber(largest_observed_length,
*iter, writer)) {
return false;
}
}
return true;
}
bool QuicFramer::AppendCongestionFeedbackFrame(
const QuicCongestionFeedbackFrame& frame,
QuicDataWriter* writer) {
if (!writer->WriteBytes(&frame.type, 1)) {
return false;
}
switch (frame.type) {
case kTCP: {
const CongestionFeedbackMessageTCP& tcp = frame.tcp;
DCHECK_LE(tcp.receive_window, 1u << 20);
// Simple bit packing, don't send the 4 least significant bits.
uint16 receive_window = static_cast<uint16>(tcp.receive_window >> 4);
if (!writer->WriteUInt16(receive_window)) {
return false;
}
break;
}
default:
return false;
}
return true;
}
bool QuicFramer::AppendTimestampToAckFrame(const QuicAckFrame& frame,
QuicDataWriter* writer) {
DCHECK_GE(version(), QUIC_VERSION_23);
DCHECK_GE(numeric_limits<uint8>::max(), frame.received_packet_times.size());
// num_received_packets is only 1 byte.
if (frame.received_packet_times.size() > numeric_limits<uint8>::max()) {
return false;
}
uint8 num_received_packets = frame.received_packet_times.size();
if (!writer->WriteBytes(&num_received_packets, 1)) {
return false;
}
if (num_received_packets == 0) {
return true;
}
PacketTimeList::const_iterator it = frame.received_packet_times.begin();
QuicPacketSequenceNumber sequence_number = it->first;
QuicPacketSequenceNumber delta_from_largest_observed =
frame.largest_observed - sequence_number;
DCHECK_GE(numeric_limits<uint8>::max(), delta_from_largest_observed);
if (delta_from_largest_observed > numeric_limits<uint8>::max()) {
return false;
}
if (!writer->WriteUInt8(
delta_from_largest_observed & k1ByteSequenceNumberMask)) {
return false;
}
// Use the lowest 4 bytes of the time delta from the creation_time_.
const uint64 time_epoch_delta_us = GG_UINT64_C(1) << 32;
uint32 time_delta_us =
static_cast<uint32>(it->second.Subtract(creation_time_).ToMicroseconds()
& (time_epoch_delta_us - 1));
if (!writer->WriteBytes(&time_delta_us, sizeof(time_delta_us))) {
return false;
}
QuicTime prev_time = it->second;
for (++it; it != frame.received_packet_times.end(); ++it) {
sequence_number = it->first;
delta_from_largest_observed = frame.largest_observed - sequence_number;
if (delta_from_largest_observed > numeric_limits<uint8>::max()) {
return false;
}
if (!writer->WriteUInt8(
delta_from_largest_observed & k1ByteSequenceNumberMask)) {
return false;
}
uint64 time_delta_us = it->second.Subtract(prev_time).ToMicroseconds();
prev_time = it->second;
if (!writer->WriteUFloat16(time_delta_us)) {
return false;
}
}
return true;
}
bool QuicFramer::AppendStopWaitingFrame(
const QuicPacketHeader& header,
const QuicStopWaitingFrame& frame,
QuicDataWriter* writer) {
DCHECK_GE(header.packet_sequence_number, frame.least_unacked);
const QuicPacketSequenceNumber least_unacked_delta =
header.packet_sequence_number - frame.least_unacked;
const QuicPacketSequenceNumber length_shift =
header.public_header.sequence_number_length * 8;
if (!writer->WriteUInt8(frame.entropy_hash)) {
LOG(DFATAL) << " hash failed";
return false;
}
if (least_unacked_delta >> length_shift > 0) {
LOG(DFATAL) << "sequence_number_length "
<< header.public_header.sequence_number_length
<< " is too small for least_unacked_delta: "
<< least_unacked_delta;
return false;
}
if (!AppendPacketSequenceNumber(header.public_header.sequence_number_length,
least_unacked_delta, writer)) {
LOG(DFATAL) << " seq failed: "
<< header.public_header.sequence_number_length;
return false;
}
return true;
}
bool QuicFramer::AppendRstStreamFrame(
const QuicRstStreamFrame& frame,
QuicDataWriter* writer) {
if (!writer->WriteUInt32(frame.stream_id)) {
return false;
}
if (!writer->WriteUInt64(frame.byte_offset)) {
return false;
}
uint32 error_code = static_cast<uint32>(frame.error_code);
if (!writer->WriteUInt32(error_code)) {
return false;
}
if (!writer->WriteStringPiece16(frame.error_details)) {
return false;
}
return true;
}
bool QuicFramer::AppendConnectionCloseFrame(
const QuicConnectionCloseFrame& frame,
QuicDataWriter* writer) {
uint32 error_code = static_cast<uint32>(frame.error_code);
if (!writer->WriteUInt32(error_code)) {
return false;
}
if (!writer->WriteStringPiece16(frame.error_details)) {
return false;
}
return true;
}
bool QuicFramer::AppendGoAwayFrame(const QuicGoAwayFrame& frame,
QuicDataWriter* writer) {
uint32 error_code = static_cast<uint32>(frame.error_code);
if (!writer->WriteUInt32(error_code)) {
return false;
}
uint32 stream_id = static_cast<uint32>(frame.last_good_stream_id);
if (!writer->WriteUInt32(stream_id)) {
return false;
}
if (!writer->WriteStringPiece16(frame.reason_phrase)) {
return false;
}
return true;
}
bool QuicFramer::AppendWindowUpdateFrame(const QuicWindowUpdateFrame& frame,
QuicDataWriter* writer) {
uint32 stream_id = static_cast<uint32>(frame.stream_id);
if (!writer->WriteUInt32(stream_id)) {
return false;
}
if (!writer->WriteUInt64(frame.byte_offset)) {
return false;
}
return true;
}
bool QuicFramer::AppendBlockedFrame(const QuicBlockedFrame& frame,
QuicDataWriter* writer) {
uint32 stream_id = static_cast<uint32>(frame.stream_id);
if (!writer->WriteUInt32(stream_id)) {
return false;
}
return true;
}
bool QuicFramer::RaiseError(QuicErrorCode error) {
DVLOG(1) << "Error detail: " << detailed_error_;
set_error(error);
visitor_->OnError(this);
reader_.reset(NULL);
return false;
}
} // namespace net