// 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.
#ifndef NET_QUIC_QUIC_PROTOCOL_H_
#define NET_QUIC_QUIC_PROTOCOL_H_
#include <stddef.h>
#include <limits>
#include <map>
#include <ostream>
#include <set>
#include <string>
#include <utility>
#include <vector>
#include "base/basictypes.h"
#include "base/containers/hash_tables.h"
#include "base/logging.h"
#include "base/strings/string_piece.h"
#include "net/base/int128.h"
#include "net/base/ip_endpoint.h"
#include "net/base/net_export.h"
#include "net/quic/iovector.h"
#include "net/quic/quic_bandwidth.h"
#include "net/quic/quic_time.h"
namespace net {
using ::operator<<;
class QuicAckNotifier;
class QuicPacket;
struct QuicPacketHeader;
typedef uint64 QuicConnectionId;
typedef uint32 QuicStreamId;
typedef uint64 QuicStreamOffset;
typedef uint64 QuicPacketSequenceNumber;
typedef QuicPacketSequenceNumber QuicFecGroupNumber;
typedef uint64 QuicPublicResetNonceProof;
typedef uint8 QuicPacketEntropyHash;
typedef uint32 QuicHeaderId;
// QuicTag is the type of a tag in the wire protocol.
typedef uint32 QuicTag;
typedef std::vector<QuicTag> QuicTagVector;
typedef std::map<QuicTag, std::string> QuicTagValueMap;
// TODO(rtenneti): Didn't use SpdyPriority because SpdyPriority is uint8 and
// QuicPriority is uint32. Use SpdyPriority when we change the QUIC_VERSION.
typedef uint32 QuicPriority;
// TODO(rch): Consider Quic specific names for these constants.
// Default and initial maximum size in bytes of a QUIC packet.
const QuicByteCount kDefaultMaxPacketSize = 1200;
// The maximum packet size of any QUIC packet, based on ethernet's max size,
// minus the IP and UDP headers. IPv6 has a 40 byte header, UPD adds an
// additional 8 bytes. This is a total overhead of 48 bytes. Ethernet's
// max packet size is 1500 bytes, 1500 - 48 = 1452.
const QuicByteCount kMaxPacketSize = 1452;
// Default maximum packet size used in Linux TCP implementations.
const QuicByteCount kDefaultTCPMSS = 1460;
// Maximum size of the initial congestion window in packets.
const size_t kDefaultInitialWindow = 10;
const uint32 kMaxInitialWindow = 100;
// Default size of initial flow control window, for both stream and session.
const uint32 kDefaultFlowControlSendWindow = 16 * 1024; // 16 KB
// Maximum size of the congestion window, in packets, for TCP congestion control
// algorithms.
const size_t kMaxTcpCongestionWindow = 200;
// Don't allow a client to suggest an RTT longer than 15 seconds.
const uint32 kMaxInitialRoundTripTimeUs = 15 * kNumMicrosPerSecond;
// Maximum number of open streams per connection.
const size_t kDefaultMaxStreamsPerConnection = 100;
// Number of bytes reserved for public flags in the packet header.
const size_t kPublicFlagsSize = 1;
// Number of bytes reserved for version number in the packet header.
const size_t kQuicVersionSize = 4;
// Number of bytes reserved for private flags in the packet header.
const size_t kPrivateFlagsSize = 1;
// Number of bytes reserved for FEC group in the packet header.
const size_t kFecGroupSize = 1;
// Signifies that the QuicPacket will contain version of the protocol.
const bool kIncludeVersion = true;
// Index of the first byte in a QUIC packet which is used in hash calculation.
const size_t kStartOfHashData = 0;
// Limit on the delta between stream IDs.
const QuicStreamId kMaxStreamIdDelta = 200;
// Limit on the delta between header IDs.
const QuicHeaderId kMaxHeaderIdDelta = 200;
// Reserved ID for the crypto stream.
const QuicStreamId kCryptoStreamId = 1;
// Reserved ID for the headers stream.
const QuicStreamId kHeadersStreamId = 3;
// This is the default network timeout a for connection till the crypto
// handshake succeeds and the negotiated timeout from the handshake is received.
const int64 kDefaultInitialTimeoutSecs = 120; // 2 mins.
const int64 kDefaultTimeoutSecs = 60 * 10; // 10 minutes.
const int64 kDefaultMaxTimeForCryptoHandshakeSecs = 5; // 5 secs.
// Default ping timeout.
const int64 kPingTimeoutSecs = 15; // 15 secs.
// We define an unsigned 16-bit floating point value, inspired by IEEE floats
// (http://en.wikipedia.org/wiki/Half_precision_floating-point_format),
// with 5-bit exponent (bias 1), 11-bit mantissa (effective 12 with hidden
// bit) and denormals, but without signs, transfinites or fractions. Wire format
// 16 bits (little-endian byte order) are split into exponent (high 5) and
// mantissa (low 11) and decoded as:
// uint64 value;
// if (exponent == 0) value = mantissa;
// else value = (mantissa | 1 << 11) << (exponent - 1)
const int kUFloat16ExponentBits = 5;
const int kUFloat16MaxExponent = (1 << kUFloat16ExponentBits) - 2; // 30
const int kUFloat16MantissaBits = 16 - kUFloat16ExponentBits; // 11
const int kUFloat16MantissaEffectiveBits = kUFloat16MantissaBits + 1; // 12
const uint64 kUFloat16MaxValue = // 0x3FFC0000000
((GG_UINT64_C(1) << kUFloat16MantissaEffectiveBits) - 1) <<
kUFloat16MaxExponent;
enum TransmissionType {
NOT_RETRANSMISSION,
FIRST_TRANSMISSION_TYPE = NOT_RETRANSMISSION,
HANDSHAKE_RETRANSMISSION, // Retransmits due to handshake timeouts.
ALL_UNACKED_RETRANSMISSION, // Retransmits of all unacked packets.
LOSS_RETRANSMISSION, // Retransmits due to loss detection.
RTO_RETRANSMISSION, // Retransmits due to retransmit time out.
TLP_RETRANSMISSION, // Tail loss probes.
LAST_TRANSMISSION_TYPE = TLP_RETRANSMISSION,
};
enum RetransmissionType {
INITIAL_ENCRYPTION_ONLY,
ALL_PACKETS
};
enum HasRetransmittableData {
NO_RETRANSMITTABLE_DATA,
HAS_RETRANSMITTABLE_DATA,
};
enum IsHandshake {
NOT_HANDSHAKE,
IS_HANDSHAKE
};
// Indicates FEC protection level for data being written.
enum FecProtection {
MUST_FEC_PROTECT, // Callee must FEC protect this data.
MAY_FEC_PROTECT // Callee does not have to but may FEC protect this data.
};
// Indicates FEC policy.
enum FecPolicy {
FEC_PROTECT_ALWAYS, // All data in the stream should be FEC protected.
FEC_PROTECT_OPTIONAL // Data in the stream does not need FEC protection.
};
enum QuicFrameType {
// Regular frame types. The values set here cannot change without the
// introduction of a new QUIC version.
PADDING_FRAME = 0,
RST_STREAM_FRAME = 1,
CONNECTION_CLOSE_FRAME = 2,
GOAWAY_FRAME = 3,
WINDOW_UPDATE_FRAME = 4,
BLOCKED_FRAME = 5,
STOP_WAITING_FRAME = 6,
PING_FRAME = 7,
// STREAM, ACK, and CONGESTION_FEEDBACK frames are special frames. They are
// encoded differently on the wire and their values do not need to be stable.
STREAM_FRAME,
ACK_FRAME,
CONGESTION_FEEDBACK_FRAME,
NUM_FRAME_TYPES
};
enum QuicConnectionIdLength {
PACKET_0BYTE_CONNECTION_ID = 0,
PACKET_1BYTE_CONNECTION_ID = 1,
PACKET_4BYTE_CONNECTION_ID = 4,
PACKET_8BYTE_CONNECTION_ID = 8
};
enum InFecGroup {
NOT_IN_FEC_GROUP,
IN_FEC_GROUP,
};
enum QuicSequenceNumberLength {
PACKET_1BYTE_SEQUENCE_NUMBER = 1,
PACKET_2BYTE_SEQUENCE_NUMBER = 2,
PACKET_4BYTE_SEQUENCE_NUMBER = 4,
PACKET_6BYTE_SEQUENCE_NUMBER = 6
};
// Used to indicate a QuicSequenceNumberLength using two flag bits.
enum QuicSequenceNumberLengthFlags {
PACKET_FLAGS_1BYTE_SEQUENCE = 0, // 00
PACKET_FLAGS_2BYTE_SEQUENCE = 1, // 01
PACKET_FLAGS_4BYTE_SEQUENCE = 1 << 1, // 10
PACKET_FLAGS_6BYTE_SEQUENCE = 1 << 1 | 1, // 11
};
// The public flags are specified in one byte.
enum QuicPacketPublicFlags {
PACKET_PUBLIC_FLAGS_NONE = 0,
// Bit 0: Does the packet header contains version info?
PACKET_PUBLIC_FLAGS_VERSION = 1 << 0,
// Bit 1: Is this packet a public reset packet?
PACKET_PUBLIC_FLAGS_RST = 1 << 1,
// Bits 2 and 3 specify the length of the ConnectionId as follows:
// ----00--: 0 bytes
// ----01--: 1 byte
// ----10--: 4 bytes
// ----11--: 8 bytes
PACKET_PUBLIC_FLAGS_0BYTE_CONNECTION_ID = 0,
PACKET_PUBLIC_FLAGS_1BYTE_CONNECTION_ID = 1 << 2,
PACKET_PUBLIC_FLAGS_4BYTE_CONNECTION_ID = 1 << 3,
PACKET_PUBLIC_FLAGS_8BYTE_CONNECTION_ID = 1 << 3 | 1 << 2,
// Bits 4 and 5 describe the packet sequence number length as follows:
// --00----: 1 byte
// --01----: 2 bytes
// --10----: 4 bytes
// --11----: 6 bytes
PACKET_PUBLIC_FLAGS_1BYTE_SEQUENCE = PACKET_FLAGS_1BYTE_SEQUENCE << 4,
PACKET_PUBLIC_FLAGS_2BYTE_SEQUENCE = PACKET_FLAGS_2BYTE_SEQUENCE << 4,
PACKET_PUBLIC_FLAGS_4BYTE_SEQUENCE = PACKET_FLAGS_4BYTE_SEQUENCE << 4,
PACKET_PUBLIC_FLAGS_6BYTE_SEQUENCE = PACKET_FLAGS_6BYTE_SEQUENCE << 4,
// All bits set (bits 6 and 7 are not currently used): 00111111
PACKET_PUBLIC_FLAGS_MAX = (1 << 6) - 1
};
// The private flags are specified in one byte.
enum QuicPacketPrivateFlags {
PACKET_PRIVATE_FLAGS_NONE = 0,
// Bit 0: Does this packet contain an entropy bit?
PACKET_PRIVATE_FLAGS_ENTROPY = 1 << 0,
// Bit 1: Payload is part of an FEC group?
PACKET_PRIVATE_FLAGS_FEC_GROUP = 1 << 1,
// Bit 2: Payload is FEC as opposed to frames?
PACKET_PRIVATE_FLAGS_FEC = 1 << 2,
// All bits set (bits 3-7 are not currently used): 00000111
PACKET_PRIVATE_FLAGS_MAX = (1 << 3) - 1
};
// The available versions of QUIC. Guaranteed that the integer value of the enum
// will match the version number.
// When adding a new version to this enum you should add it to
// kSupportedQuicVersions (if appropriate), and also add a new case to the
// helper methods QuicVersionToQuicTag, QuicTagToQuicVersion, and
// QuicVersionToString.
enum QuicVersion {
// Special case to indicate unknown/unsupported QUIC version.
QUIC_VERSION_UNSUPPORTED = 0,
QUIC_VERSION_15 = 15,
QUIC_VERSION_16 = 16,
QUIC_VERSION_17 = 17,
QUIC_VERSION_18 = 18,
QUIC_VERSION_19 = 19,
QUIC_VERSION_20 = 20, // Current version.
};
// This vector contains QUIC versions which we currently support.
// This should be ordered such that the highest supported version is the first
// element, with subsequent elements in descending order (versions can be
// skipped as necessary).
//
// IMPORTANT: if you are addding to this list, follow the instructions at
// http://sites/quic/adding-and-removing-versions
static const QuicVersion kSupportedQuicVersions[] = {QUIC_VERSION_20,
QUIC_VERSION_19,
QUIC_VERSION_18,
QUIC_VERSION_17,
QUIC_VERSION_16,
QUIC_VERSION_15};
typedef std::vector<QuicVersion> QuicVersionVector;
// Returns a vector of QUIC versions in kSupportedQuicVersions.
NET_EXPORT_PRIVATE QuicVersionVector QuicSupportedVersions();
// QuicTag is written to and read from the wire, but we prefer to use
// the more readable QuicVersion at other levels.
// Helper function which translates from a QuicVersion to a QuicTag. Returns 0
// if QuicVersion is unsupported.
NET_EXPORT_PRIVATE QuicTag QuicVersionToQuicTag(const QuicVersion version);
// Returns appropriate QuicVersion from a QuicTag.
// Returns QUIC_VERSION_UNSUPPORTED if version_tag cannot be understood.
NET_EXPORT_PRIVATE QuicVersion QuicTagToQuicVersion(const QuicTag version_tag);
// Helper function which translates from a QuicVersion to a string.
// Returns strings corresponding to enum names (e.g. QUIC_VERSION_6).
NET_EXPORT_PRIVATE std::string QuicVersionToString(const QuicVersion version);
// Returns comma separated list of string representations of QuicVersion enum
// values in the supplied |versions| vector.
NET_EXPORT_PRIVATE std::string QuicVersionVectorToString(
const QuicVersionVector& versions);
// Version and Crypto tags are written to the wire with a big-endian
// representation of the name of the tag. For example
// the client hello tag (CHLO) will be written as the
// following 4 bytes: 'C' 'H' 'L' 'O'. Since it is
// stored in memory as a little endian uint32, we need
// to reverse the order of the bytes.
// MakeQuicTag returns a value given the four bytes. For example:
// MakeQuicTag('C', 'H', 'L', 'O');
NET_EXPORT_PRIVATE QuicTag MakeQuicTag(char a, char b, char c, char d);
// Returns true if the tag vector contains the specified tag.
bool ContainsQuicTag(const QuicTagVector& tag_vector, QuicTag tag);
// Size in bytes of the data or fec packet header.
NET_EXPORT_PRIVATE size_t GetPacketHeaderSize(const QuicPacketHeader& header);
NET_EXPORT_PRIVATE size_t GetPacketHeaderSize(
QuicConnectionIdLength connection_id_length,
bool include_version,
QuicSequenceNumberLength sequence_number_length,
InFecGroup is_in_fec_group);
// Index of the first byte in a QUIC packet of FEC protected data.
NET_EXPORT_PRIVATE size_t GetStartOfFecProtectedData(
QuicConnectionIdLength connection_id_length,
bool include_version,
QuicSequenceNumberLength sequence_number_length);
// Index of the first byte in a QUIC packet of encrypted data.
NET_EXPORT_PRIVATE size_t GetStartOfEncryptedData(
QuicConnectionIdLength connection_id_length,
bool include_version,
QuicSequenceNumberLength sequence_number_length);
enum QuicRstStreamErrorCode {
QUIC_STREAM_NO_ERROR = 0,
// There was some error which halted stream processing.
QUIC_ERROR_PROCESSING_STREAM,
// We got two fin or reset offsets which did not match.
QUIC_MULTIPLE_TERMINATION_OFFSETS,
// We got bad payload and can not respond to it at the protocol level.
QUIC_BAD_APPLICATION_PAYLOAD,
// Stream closed due to connection error. No reset frame is sent when this
// happens.
QUIC_STREAM_CONNECTION_ERROR,
// GoAway frame sent. No more stream can be created.
QUIC_STREAM_PEER_GOING_AWAY,
// The stream has been cancelled.
QUIC_STREAM_CANCELLED,
// Sending a RST to allow for proper flow control accounting.
QUIC_RST_FLOW_CONTROL_ACCOUNTING,
// No error. Used as bound while iterating.
QUIC_STREAM_LAST_ERROR,
};
// Because receiving an unknown QuicRstStreamErrorCode results in connection
// teardown, we use this to make sure any errors predating a given version are
// downgraded to the most appropriate existing error.
NET_EXPORT_PRIVATE QuicRstStreamErrorCode AdjustErrorForVersion(
QuicRstStreamErrorCode error_code,
QuicVersion version);
// These values must remain stable as they are uploaded to UMA histograms.
// To add a new error code, use the current value of QUIC_LAST_ERROR and
// increment QUIC_LAST_ERROR.
enum QuicErrorCode {
QUIC_NO_ERROR = 0,
// Connection has reached an invalid state.
QUIC_INTERNAL_ERROR = 1,
// There were data frames after the a fin or reset.
QUIC_STREAM_DATA_AFTER_TERMINATION = 2,
// Control frame is malformed.
QUIC_INVALID_PACKET_HEADER = 3,
// Frame data is malformed.
QUIC_INVALID_FRAME_DATA = 4,
// The packet contained no payload.
QUIC_MISSING_PAYLOAD = 48,
// FEC data is malformed.
QUIC_INVALID_FEC_DATA = 5,
// STREAM frame data is malformed.
QUIC_INVALID_STREAM_DATA = 46,
// STREAM frame data is not encrypted.
QUIC_UNENCRYPTED_STREAM_DATA = 61,
// RST_STREAM frame data is malformed.
QUIC_INVALID_RST_STREAM_DATA = 6,
// CONNECTION_CLOSE frame data is malformed.
QUIC_INVALID_CONNECTION_CLOSE_DATA = 7,
// GOAWAY frame data is malformed.
QUIC_INVALID_GOAWAY_DATA = 8,
// WINDOW_UPDATE frame data is malformed.
QUIC_INVALID_WINDOW_UPDATE_DATA = 57,
// BLOCKED frame data is malformed.
QUIC_INVALID_BLOCKED_DATA = 58,
// STOP_WAITING frame data is malformed.
QUIC_INVALID_STOP_WAITING_DATA = 60,
// ACK frame data is malformed.
QUIC_INVALID_ACK_DATA = 9,
// CONGESTION_FEEDBACK frame data is malformed.
QUIC_INVALID_CONGESTION_FEEDBACK_DATA = 47,
// Version negotiation packet is malformed.
QUIC_INVALID_VERSION_NEGOTIATION_PACKET = 10,
// Public RST packet is malformed.
QUIC_INVALID_PUBLIC_RST_PACKET = 11,
// There was an error decrypting.
QUIC_DECRYPTION_FAILURE = 12,
// There was an error encrypting.
QUIC_ENCRYPTION_FAILURE = 13,
// The packet exceeded kMaxPacketSize.
QUIC_PACKET_TOO_LARGE = 14,
// Data was sent for a stream which did not exist.
QUIC_PACKET_FOR_NONEXISTENT_STREAM = 15,
// The peer is going away. May be a client or server.
QUIC_PEER_GOING_AWAY = 16,
// A stream ID was invalid.
QUIC_INVALID_STREAM_ID = 17,
// A priority was invalid.
QUIC_INVALID_PRIORITY = 49,
// Too many streams already open.
QUIC_TOO_MANY_OPEN_STREAMS = 18,
// Received public reset for this connection.
QUIC_PUBLIC_RESET = 19,
// Invalid protocol version.
QUIC_INVALID_VERSION = 20,
// deprecated: QUIC_STREAM_RST_BEFORE_HEADERS_DECOMPRESSED = 21
// The Header ID for a stream was too far from the previous.
QUIC_INVALID_HEADER_ID = 22,
// Negotiable parameter received during handshake had invalid value.
QUIC_INVALID_NEGOTIATED_VALUE = 23,
// There was an error decompressing data.
QUIC_DECOMPRESSION_FAILURE = 24,
// We hit our prenegotiated (or default) timeout
QUIC_CONNECTION_TIMED_OUT = 25,
// There was an error encountered migrating addresses
QUIC_ERROR_MIGRATING_ADDRESS = 26,
// There was an error while writing to the socket.
QUIC_PACKET_WRITE_ERROR = 27,
// There was an error while reading from the socket.
QUIC_PACKET_READ_ERROR = 51,
// We received a STREAM_FRAME with no data and no fin flag set.
QUIC_INVALID_STREAM_FRAME = 50,
// We received invalid data on the headers stream.
QUIC_INVALID_HEADERS_STREAM_DATA = 56,
// The peer received too much data, violating flow control.
QUIC_FLOW_CONTROL_RECEIVED_TOO_MUCH_DATA = 59,
// The peer sent too much data, violating flow control.
QUIC_FLOW_CONTROL_SENT_TOO_MUCH_DATA = 63,
// The peer received an invalid flow control window.
QUIC_FLOW_CONTROL_INVALID_WINDOW = 64,
// The connection has been IP pooled into an existing connection.
QUIC_CONNECTION_IP_POOLED = 62,
// Crypto errors.
// Hanshake failed.
QUIC_HANDSHAKE_FAILED = 28,
// Handshake message contained out of order tags.
QUIC_CRYPTO_TAGS_OUT_OF_ORDER = 29,
// Handshake message contained too many entries.
QUIC_CRYPTO_TOO_MANY_ENTRIES = 30,
// Handshake message contained an invalid value length.
QUIC_CRYPTO_INVALID_VALUE_LENGTH = 31,
// A crypto message was received after the handshake was complete.
QUIC_CRYPTO_MESSAGE_AFTER_HANDSHAKE_COMPLETE = 32,
// A crypto message was received with an illegal message tag.
QUIC_INVALID_CRYPTO_MESSAGE_TYPE = 33,
// A crypto message was received with an illegal parameter.
QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER = 34,
// An invalid channel id signature was supplied.
QUIC_INVALID_CHANNEL_ID_SIGNATURE = 52,
// A crypto message was received with a mandatory parameter missing.
QUIC_CRYPTO_MESSAGE_PARAMETER_NOT_FOUND = 35,
// A crypto message was received with a parameter that has no overlap
// with the local parameter.
QUIC_CRYPTO_MESSAGE_PARAMETER_NO_OVERLAP = 36,
// A crypto message was received that contained a parameter with too few
// values.
QUIC_CRYPTO_MESSAGE_INDEX_NOT_FOUND = 37,
// An internal error occured in crypto processing.
QUIC_CRYPTO_INTERNAL_ERROR = 38,
// A crypto handshake message specified an unsupported version.
QUIC_CRYPTO_VERSION_NOT_SUPPORTED = 39,
// There was no intersection between the crypto primitives supported by the
// peer and ourselves.
QUIC_CRYPTO_NO_SUPPORT = 40,
// The server rejected our client hello messages too many times.
QUIC_CRYPTO_TOO_MANY_REJECTS = 41,
// The client rejected the server's certificate chain or signature.
QUIC_PROOF_INVALID = 42,
// A crypto message was received with a duplicate tag.
QUIC_CRYPTO_DUPLICATE_TAG = 43,
// A crypto message was received with the wrong encryption level (i.e. it
// should have been encrypted but was not.)
QUIC_CRYPTO_ENCRYPTION_LEVEL_INCORRECT = 44,
// The server config for a server has expired.
QUIC_CRYPTO_SERVER_CONFIG_EXPIRED = 45,
// We failed to setup the symmetric keys for a connection.
QUIC_CRYPTO_SYMMETRIC_KEY_SETUP_FAILED = 53,
// A handshake message arrived, but we are still validating the
// previous handshake message.
QUIC_CRYPTO_MESSAGE_WHILE_VALIDATING_CLIENT_HELLO = 54,
// This connection involved a version negotiation which appears to have been
// tampered with.
QUIC_VERSION_NEGOTIATION_MISMATCH = 55,
// No error. Used as bound while iterating.
QUIC_LAST_ERROR = 65,
};
struct NET_EXPORT_PRIVATE QuicPacketPublicHeader {
QuicPacketPublicHeader();
explicit QuicPacketPublicHeader(const QuicPacketPublicHeader& other);
~QuicPacketPublicHeader();
// Universal header. All QuicPacket headers will have a connection_id and
// public flags.
QuicConnectionId connection_id;
QuicConnectionIdLength connection_id_length;
bool reset_flag;
bool version_flag;
QuicSequenceNumberLength sequence_number_length;
QuicVersionVector versions;
};
// Header for Data or FEC packets.
struct NET_EXPORT_PRIVATE QuicPacketHeader {
QuicPacketHeader();
explicit QuicPacketHeader(const QuicPacketPublicHeader& header);
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicPacketHeader& s);
QuicPacketPublicHeader public_header;
bool fec_flag;
bool entropy_flag;
QuicPacketEntropyHash entropy_hash;
QuicPacketSequenceNumber packet_sequence_number;
InFecGroup is_in_fec_group;
QuicFecGroupNumber fec_group;
};
struct NET_EXPORT_PRIVATE QuicPublicResetPacket {
QuicPublicResetPacket();
explicit QuicPublicResetPacket(const QuicPacketPublicHeader& header);
QuicPacketPublicHeader public_header;
QuicPublicResetNonceProof nonce_proof;
QuicPacketSequenceNumber rejected_sequence_number;
IPEndPoint client_address;
};
enum QuicVersionNegotiationState {
START_NEGOTIATION = 0,
// Server-side this implies we've sent a version negotiation packet and are
// waiting on the client to select a compatible version. Client-side this
// implies we've gotten a version negotiation packet, are retransmitting the
// initial packets with a supported version and are waiting for our first
// packet from the server.
NEGOTIATION_IN_PROGRESS,
// This indicates this endpoint has received a packet from the peer with a
// version this endpoint supports. Version negotiation is complete, and the
// version number will no longer be sent with future packets.
NEGOTIATED_VERSION
};
typedef QuicPacketPublicHeader QuicVersionNegotiationPacket;
// A padding frame contains no payload.
struct NET_EXPORT_PRIVATE QuicPaddingFrame {
};
// A ping frame contains no payload, though it is retransmittable,
// and ACK'd just like other normal frames.
struct NET_EXPORT_PRIVATE QuicPingFrame {
};
struct NET_EXPORT_PRIVATE QuicStreamFrame {
QuicStreamFrame();
QuicStreamFrame(const QuicStreamFrame& frame);
QuicStreamFrame(QuicStreamId stream_id,
bool fin,
QuicStreamOffset offset,
IOVector data);
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicStreamFrame& s);
// Returns a copy of the IOVector |data| as a heap-allocated string.
// Caller must take ownership of the returned string.
std::string* GetDataAsString() const;
QuicStreamId stream_id;
bool fin;
QuicStreamOffset offset; // Location of this data in the stream.
IOVector data;
// If this is set, then when this packet is ACKed the AckNotifier will be
// informed.
QuicAckNotifier* notifier;
};
// TODO(ianswett): Re-evaluate the trade-offs of hash_set vs set when framing
// is finalized.
typedef std::set<QuicPacketSequenceNumber> SequenceNumberSet;
// TODO(pwestin): Add a way to enforce the max size of this map.
typedef std::map<QuicPacketSequenceNumber, QuicTime> TimeMap;
struct NET_EXPORT_PRIVATE ReceivedPacketInfo {
ReceivedPacketInfo();
~ReceivedPacketInfo();
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const ReceivedPacketInfo& s);
// Entropy hash of all packets up to largest observed not including missing
// packets.
QuicPacketEntropyHash entropy_hash;
// The highest packet sequence number we've observed from the peer.
//
// In general, this should be the largest packet number we've received. In
// the case of truncated acks, we may have to advertise a lower "upper bound"
// than largest received, to avoid implicitly acking missing packets that
// don't fit in the missing packet list due to size limitations. In this
// case, largest_observed may be a packet which is also in the missing packets
// list.
QuicPacketSequenceNumber largest_observed;
// Time elapsed since largest_observed was received until this Ack frame was
// sent.
QuicTime::Delta delta_time_largest_observed;
// TODO(satyamshekhar): Can be optimized using an interval set like data
// structure.
// The set of packets which we're expecting and have not received.
SequenceNumberSet missing_packets;
// Whether the ack had to be truncated when sent.
bool is_truncated;
// Packets which have been revived via FEC.
// All of these must also be in missing_packets.
SequenceNumberSet revived_packets;
};
// True if the sequence number is greater than largest_observed or is listed
// as missing.
// Always returns false for sequence numbers less than least_unacked.
bool NET_EXPORT_PRIVATE IsAwaitingPacket(
const ReceivedPacketInfo& received_info,
QuicPacketSequenceNumber sequence_number);
// Inserts missing packets between [lower, higher).
void NET_EXPORT_PRIVATE InsertMissingPacketsBetween(
ReceivedPacketInfo* received_info,
QuicPacketSequenceNumber lower,
QuicPacketSequenceNumber higher);
struct NET_EXPORT_PRIVATE QuicStopWaitingFrame {
QuicStopWaitingFrame();
~QuicStopWaitingFrame();
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicStopWaitingFrame& s);
// Entropy hash of all packets up to, but not including, the least unacked
// packet.
QuicPacketEntropyHash entropy_hash;
// The lowest packet we've sent which is unacked, and we expect an ack for.
QuicPacketSequenceNumber least_unacked;
};
struct NET_EXPORT_PRIVATE QuicAckFrame {
QuicAckFrame();
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicAckFrame& s);
QuicStopWaitingFrame sent_info;
ReceivedPacketInfo received_info;
};
// Defines for all types of congestion feedback that will be negotiated in QUIC,
// kTCP MUST be supported by all QUIC implementations to guarantee 100%
// compatibility.
enum CongestionFeedbackType {
kTCP, // Used to mimic TCP.
kInterArrival, // Use additional inter arrival information.
kFixRate, // Provided for testing.
kTCPBBR, // BBR implementation based on TCP congestion feedback.
};
enum LossDetectionType {
kNack, // Used to mimic TCP's loss detection.
kTime, // Time based loss detection.
};
struct NET_EXPORT_PRIVATE CongestionFeedbackMessageTCP {
CongestionFeedbackMessageTCP();
QuicByteCount receive_window;
};
struct NET_EXPORT_PRIVATE CongestionFeedbackMessageInterArrival {
CongestionFeedbackMessageInterArrival();
~CongestionFeedbackMessageInterArrival();
// The set of received packets since the last feedback was sent, along with
// their arrival times.
TimeMap received_packet_times;
};
struct NET_EXPORT_PRIVATE CongestionFeedbackMessageFixRate {
CongestionFeedbackMessageFixRate();
QuicBandwidth bitrate;
};
struct NET_EXPORT_PRIVATE QuicCongestionFeedbackFrame {
QuicCongestionFeedbackFrame();
~QuicCongestionFeedbackFrame();
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicCongestionFeedbackFrame& c);
CongestionFeedbackType type;
// This should really be a union, but since the inter arrival struct
// is non-trivial, C++ prohibits it.
CongestionFeedbackMessageTCP tcp;
CongestionFeedbackMessageInterArrival inter_arrival;
CongestionFeedbackMessageFixRate fix_rate;
};
struct NET_EXPORT_PRIVATE QuicRstStreamFrame {
QuicRstStreamFrame();
QuicRstStreamFrame(QuicStreamId stream_id,
QuicRstStreamErrorCode error_code,
QuicStreamOffset bytes_written);
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicRstStreamFrame& r);
QuicStreamId stream_id;
QuicRstStreamErrorCode error_code;
std::string error_details;
// Used to update flow control windows. On termination of a stream, both
// endpoints must inform the peer of the number of bytes they have sent on
// that stream. This can be done through normal termination (data packet with
// FIN) or through a RST.
QuicStreamOffset byte_offset;
};
struct NET_EXPORT_PRIVATE QuicConnectionCloseFrame {
QuicConnectionCloseFrame();
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicConnectionCloseFrame& c);
QuicErrorCode error_code;
std::string error_details;
};
struct NET_EXPORT_PRIVATE QuicGoAwayFrame {
QuicGoAwayFrame();
QuicGoAwayFrame(QuicErrorCode error_code,
QuicStreamId last_good_stream_id,
const std::string& reason);
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicGoAwayFrame& g);
QuicErrorCode error_code;
QuicStreamId last_good_stream_id;
std::string reason_phrase;
};
// Flow control updates per-stream and at the connection levoel.
// Based on SPDY's WINDOW_UPDATE frame, but uses an absolute byte offset rather
// than a window delta.
// TODO(rjshade): A possible future optimization is to make stream_id and
// byte_offset variable length, similar to stream frames.
struct NET_EXPORT_PRIVATE QuicWindowUpdateFrame {
QuicWindowUpdateFrame() {}
QuicWindowUpdateFrame(QuicStreamId stream_id, QuicStreamOffset byte_offset);
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicWindowUpdateFrame& w);
// The stream this frame applies to. 0 is a special case meaning the overall
// connection rather than a specific stream.
QuicStreamId stream_id;
// Byte offset in the stream or connection. The receiver of this frame must
// not send data which would result in this offset being exceeded.
QuicStreamOffset byte_offset;
};
// The BLOCKED frame is used to indicate to the remote endpoint that this
// endpoint believes itself to be flow-control blocked but otherwise ready to
// send data. The BLOCKED frame is purely advisory and optional.
// Based on SPDY's BLOCKED frame (undocumented as of 2014-01-28).
struct NET_EXPORT_PRIVATE QuicBlockedFrame {
QuicBlockedFrame() {}
explicit QuicBlockedFrame(QuicStreamId stream_id);
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicBlockedFrame& b);
// The stream this frame applies to. 0 is a special case meaning the overall
// connection rather than a specific stream.
QuicStreamId stream_id;
};
// EncryptionLevel enumerates the stages of encryption that a QUIC connection
// progresses through. When retransmitting a packet, the encryption level needs
// to be specified so that it is retransmitted at a level which the peer can
// understand.
enum EncryptionLevel {
ENCRYPTION_NONE = 0,
ENCRYPTION_INITIAL = 1,
ENCRYPTION_FORWARD_SECURE = 2,
NUM_ENCRYPTION_LEVELS,
};
struct NET_EXPORT_PRIVATE QuicFrame {
QuicFrame();
explicit QuicFrame(QuicPaddingFrame* padding_frame);
explicit QuicFrame(QuicStreamFrame* stream_frame);
explicit QuicFrame(QuicAckFrame* frame);
explicit QuicFrame(QuicCongestionFeedbackFrame* frame);
explicit QuicFrame(QuicRstStreamFrame* frame);
explicit QuicFrame(QuicConnectionCloseFrame* frame);
explicit QuicFrame(QuicStopWaitingFrame* frame);
explicit QuicFrame(QuicPingFrame* frame);
explicit QuicFrame(QuicGoAwayFrame* frame);
explicit QuicFrame(QuicWindowUpdateFrame* frame);
explicit QuicFrame(QuicBlockedFrame* frame);
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicFrame& frame);
QuicFrameType type;
union {
QuicPaddingFrame* padding_frame;
QuicStreamFrame* stream_frame;
QuicAckFrame* ack_frame;
QuicCongestionFeedbackFrame* congestion_feedback_frame;
QuicStopWaitingFrame* stop_waiting_frame;
QuicPingFrame* ping_frame;
QuicRstStreamFrame* rst_stream_frame;
QuicConnectionCloseFrame* connection_close_frame;
QuicGoAwayFrame* goaway_frame;
QuicWindowUpdateFrame* window_update_frame;
QuicBlockedFrame* blocked_frame;
};
};
typedef std::vector<QuicFrame> QuicFrames;
struct NET_EXPORT_PRIVATE QuicFecData {
QuicFecData();
// The FEC group number is also the sequence number of the first
// FEC protected packet. The last protected packet's sequence number will
// be one less than the sequence number of the FEC packet.
QuicFecGroupNumber fec_group;
base::StringPiece redundancy;
};
class NET_EXPORT_PRIVATE QuicData {
public:
QuicData(const char* buffer, size_t length);
QuicData(char* buffer, size_t length, bool owns_buffer);
virtual ~QuicData();
base::StringPiece AsStringPiece() const {
return base::StringPiece(data(), length());
}
const char* data() const { return buffer_; }
size_t length() const { return length_; }
private:
const char* buffer_;
size_t length_;
bool owns_buffer_;
DISALLOW_COPY_AND_ASSIGN(QuicData);
};
class NET_EXPORT_PRIVATE QuicPacket : public QuicData {
public:
static QuicPacket* NewDataPacket(
char* buffer,
size_t length,
bool owns_buffer,
QuicConnectionIdLength connection_id_length,
bool includes_version,
QuicSequenceNumberLength sequence_number_length) {
return new QuicPacket(buffer, length, owns_buffer, connection_id_length,
includes_version, sequence_number_length, false);
}
static QuicPacket* NewFecPacket(
char* buffer,
size_t length,
bool owns_buffer,
QuicConnectionIdLength connection_id_length,
bool includes_version,
QuicSequenceNumberLength sequence_number_length) {
return new QuicPacket(buffer, length, owns_buffer, connection_id_length,
includes_version, sequence_number_length, true);
}
base::StringPiece FecProtectedData() const;
base::StringPiece AssociatedData() const;
base::StringPiece BeforePlaintext() const;
base::StringPiece Plaintext() const;
bool is_fec_packet() const { return is_fec_packet_; }
char* mutable_data() { return buffer_; }
private:
QuicPacket(char* buffer,
size_t length,
bool owns_buffer,
QuicConnectionIdLength connection_id_length,
bool includes_version,
QuicSequenceNumberLength sequence_number_length,
bool is_fec_packet);
char* buffer_;
const bool is_fec_packet_;
const QuicConnectionIdLength connection_id_length_;
const bool includes_version_;
const QuicSequenceNumberLength sequence_number_length_;
DISALLOW_COPY_AND_ASSIGN(QuicPacket);
};
class NET_EXPORT_PRIVATE QuicEncryptedPacket : public QuicData {
public:
QuicEncryptedPacket(const char* buffer, size_t length);
QuicEncryptedPacket(char* buffer, size_t length, bool owns_buffer);
// Clones the packet into a new packet which owns the buffer.
QuicEncryptedPacket* Clone() const;
// By default, gtest prints the raw bytes of an object. The bool data
// member (in the base class QuicData) causes this object to have padding
// bytes, which causes the default gtest object printer to read
// uninitialize memory. So we need to teach gtest how to print this object.
NET_EXPORT_PRIVATE friend std::ostream& operator<<(
std::ostream& os, const QuicEncryptedPacket& s);
private:
DISALLOW_COPY_AND_ASSIGN(QuicEncryptedPacket);
};
class NET_EXPORT_PRIVATE RetransmittableFrames {
public:
RetransmittableFrames();
~RetransmittableFrames();
// Allocates a local copy of the referenced StringPiece has QuicStreamFrame
// use it.
// Takes ownership of |stream_frame|.
const QuicFrame& AddStreamFrame(QuicStreamFrame* stream_frame);
// Takes ownership of the frame inside |frame|.
const QuicFrame& AddNonStreamFrame(const QuicFrame& frame);
const QuicFrames& frames() const { return frames_; }
IsHandshake HasCryptoHandshake() const;
void set_encryption_level(EncryptionLevel level);
EncryptionLevel encryption_level() const {
return encryption_level_;
}
private:
QuicFrames frames_;
EncryptionLevel encryption_level_;
// Data referenced by the StringPiece of a QuicStreamFrame.
std::vector<std::string*> stream_data_;
DISALLOW_COPY_AND_ASSIGN(RetransmittableFrames);
};
struct NET_EXPORT_PRIVATE SerializedPacket {
SerializedPacket(QuicPacketSequenceNumber sequence_number,
QuicSequenceNumberLength sequence_number_length,
QuicPacket* packet,
QuicPacketEntropyHash entropy_hash,
RetransmittableFrames* retransmittable_frames);
~SerializedPacket();
QuicPacketSequenceNumber sequence_number;
QuicSequenceNumberLength sequence_number_length;
QuicPacket* packet;
QuicPacketEntropyHash entropy_hash;
RetransmittableFrames* retransmittable_frames;
// If set, these will be called when this packet is ACKed by the peer.
std::set<QuicAckNotifier*> notifiers;
};
struct NET_EXPORT_PRIVATE TransmissionInfo {
// Used by STL when assigning into a map.
TransmissionInfo();
// Constructs a Transmission with a new all_tranmissions set
// containing |sequence_number|.
TransmissionInfo(RetransmittableFrames* retransmittable_frames,
QuicPacketSequenceNumber sequence_number,
QuicSequenceNumberLength sequence_number_length);
// Constructs a Transmission with the specified |all_tranmissions| set
// and inserts |sequence_number| into it.
TransmissionInfo(RetransmittableFrames* retransmittable_frames,
QuicPacketSequenceNumber sequence_number,
QuicSequenceNumberLength sequence_number_length,
TransmissionType transmission_type,
SequenceNumberSet* all_transmissions);
RetransmittableFrames* retransmittable_frames;
QuicSequenceNumberLength sequence_number_length;
// Zero when the packet is serialized, non-zero once it's sent.
QuicTime sent_time;
// Zero when the packet is serialized, non-zero once it's sent.
QuicByteCount bytes_sent;
size_t nack_count;
// Reason why this packet was transmitted.
TransmissionType transmission_type;
// Stores the sequence numbers of all transmissions of this packet.
// Can never be null.
SequenceNumberSet* all_transmissions;
// In flight packets have not been abandoned or lost.
bool in_flight;
};
} // namespace net
#endif // NET_QUIC_QUIC_PROTOCOL_H_