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// 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 QUICHE_QUIC_CORE_CRYPTO_CRYPTO_PROTOCOL_H_
#define QUICHE_QUIC_CORE_CRYPTO_CRYPTO_PROTOCOL_H_
#include <cstddef>
#include <string>
#include "quic/core/quic_tag.h"
// 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_t, we need
// to reverse the order of the bytes.
//
// We use a macro to ensure that no static initialisers are created. Use the
// MakeQuicTag function in normal code.
#define TAG(a, b, c, d) \
static_cast<QuicTag>((d << 24) + (c << 16) + (b << 8) + a)
namespace quic {
using ServerConfigID = std::string;
// The following tags have been deprecated and should not be reused:
// "1CON", "BBQ4", "NCON", "RCID", "SREJ", "TBKP", "TB10", "SCLS", "SMHL",
// "QNZR", "B2HI", "H2PR", "FIFO", "LIFO", "RRWS", "QNSP", "B2CL", "CHSP",
// "BPTE"
// clang-format off
const QuicTag kCHLO = TAG('C', 'H', 'L', 'O'); // Client hello
const QuicTag kSHLO = TAG('S', 'H', 'L', 'O'); // Server hello
const QuicTag kSCFG = TAG('S', 'C', 'F', 'G'); // Server config
const QuicTag kREJ = TAG('R', 'E', 'J', '\0'); // Reject
const QuicTag kCETV = TAG('C', 'E', 'T', 'V'); // Client encrypted tag-value
// pairs
const QuicTag kPRST = TAG('P', 'R', 'S', 'T'); // Public reset
const QuicTag kSCUP = TAG('S', 'C', 'U', 'P'); // Server config update
const QuicTag kALPN = TAG('A', 'L', 'P', 'N'); // Application-layer protocol
// Key exchange methods
const QuicTag kP256 = TAG('P', '2', '5', '6'); // ECDH, Curve P-256
const QuicTag kC255 = TAG('C', '2', '5', '5'); // ECDH, Curve25519
// AEAD algorithms
const QuicTag kAESG = TAG('A', 'E', 'S', 'G'); // AES128 + GCM-12
const QuicTag kCC20 = TAG('C', 'C', '2', '0'); // ChaCha20 + Poly1305 RFC7539
// Congestion control feedback types
const QuicTag kQBIC = TAG('Q', 'B', 'I', 'C'); // TCP cubic
// Connection options (COPT) values
const QuicTag kAFCW = TAG('A', 'F', 'C', 'W'); // Auto-tune flow control
// receive windows.
const QuicTag kIFW5 = TAG('I', 'F', 'W', '5'); // Set initial size
// of stream flow control
// receive window to
// 32KB. (2^5 KB).
const QuicTag kIFW6 = TAG('I', 'F', 'W', '6'); // Set initial size
// of stream flow control
// receive window to
// 64KB. (2^6 KB).
const QuicTag kIFW7 = TAG('I', 'F', 'W', '7'); // Set initial size
// of stream flow control
// receive window to
// 128KB. (2^7 KB).
const QuicTag kIFW8 = TAG('I', 'F', 'W', '8'); // Set initial size
// of stream flow control
// receive window to
// 256KB. (2^8 KB).
const QuicTag kIFW9 = TAG('I', 'F', 'W', '9'); // Set initial size
// of stream flow control
// receive window to
// 512KB. (2^9 KB).
const QuicTag kIFWA = TAG('I', 'F', 'W', 'a'); // Set initial size
// of stream flow control
// receive window to
// 1MB. (2^0xa KB).
const QuicTag kTBBR = TAG('T', 'B', 'B', 'R'); // Reduced Buffer Bloat TCP
const QuicTag k1RTT = TAG('1', 'R', 'T', 'T'); // STARTUP in BBR for 1 RTT
const QuicTag k2RTT = TAG('2', 'R', 'T', 'T'); // STARTUP in BBR for 2 RTTs
const QuicTag kLRTT = TAG('L', 'R', 'T', 'T'); // Exit STARTUP in BBR on loss
const QuicTag kBBS1 = TAG('B', 'B', 'S', '1'); // DEPRECATED
const QuicTag kBBS2 = TAG('B', 'B', 'S', '2'); // More aggressive packet
// conservation in BBR STARTUP
const QuicTag kBBS3 = TAG('B', 'B', 'S', '3'); // Slowstart packet
// conservation in BBR STARTUP
const QuicTag kBBS4 = TAG('B', 'B', 'S', '4'); // DEPRECATED
const QuicTag kBBS5 = TAG('B', 'B', 'S', '5'); // DEPRECATED
const QuicTag kBBRR = TAG('B', 'B', 'R', 'R'); // Rate-based recovery in BBR
const QuicTag kBBR1 = TAG('B', 'B', 'R', '1'); // DEPRECATED
const QuicTag kBBR2 = TAG('B', 'B', 'R', '2'); // DEPRECATED
const QuicTag kBBR3 = TAG('B', 'B', 'R', '3'); // Fully drain the queue once
// per cycle
const QuicTag kBBR4 = TAG('B', 'B', 'R', '4'); // 20 RTT ack aggregation
const QuicTag kBBR5 = TAG('B', 'B', 'R', '5'); // 40 RTT ack aggregation
const QuicTag kBBR9 = TAG('B', 'B', 'R', '9'); // DEPRECATED
const QuicTag kBBRS = TAG('B', 'B', 'R', 'S'); // DEPRECATED
const QuicTag kBBQ1 = TAG('B', 'B', 'Q', '1'); // BBR with lower 2.77 STARTUP
// pacing and CWND gain.
const QuicTag kBBQ2 = TAG('B', 'B', 'Q', '2'); // BBRv2 with 2.885 STARTUP and
// DRAIN CWND gain.
const QuicTag kBBQ3 = TAG('B', 'B', 'Q', '3'); // BBR with ack aggregation
// compensation in STARTUP.
const QuicTag kBBQ5 = TAG('B', 'B', 'Q', '5'); // Expire ack aggregation upon
// bandwidth increase in
// STARTUP.
const QuicTag kBBQ6 = TAG('B', 'B', 'Q', '6'); // Reduce STARTUP gain to 25%
// more than BW increase.
const QuicTag kBBQ7 = TAG('B', 'B', 'Q', '7'); // Reduce bw_lo by
// bytes_lost/min_rtt.
const QuicTag kBBQ8 = TAG('B', 'B', 'Q', '8'); // Reduce bw_lo by
// bw_lo * bytes_lost/inflight
const QuicTag kBBQ9 = TAG('B', 'B', 'Q', '9'); // Reduce bw_lo by
// bw_lo * bytes_lost/cwnd
const QuicTag kRENO = TAG('R', 'E', 'N', 'O'); // Reno Congestion Control
const QuicTag kTPCC = TAG('P', 'C', 'C', '\0'); // Performance-Oriented
// Congestion Control
const QuicTag kBYTE = TAG('B', 'Y', 'T', 'E'); // TCP cubic or reno in bytes
const QuicTag kIW03 = TAG('I', 'W', '0', '3'); // Force ICWND to 3
const QuicTag kIW10 = TAG('I', 'W', '1', '0'); // Force ICWND to 10
const QuicTag kIW20 = TAG('I', 'W', '2', '0'); // Force ICWND to 20
const QuicTag kIW50 = TAG('I', 'W', '5', '0'); // Force ICWND to 50
const QuicTag kB2ON = TAG('B', '2', 'O', 'N'); // Enable BBRv2
const QuicTag kB2NA = TAG('B', '2', 'N', 'A'); // For BBRv2, do not add ack
// height to queueing threshold
const QuicTag kB2NE = TAG('B', '2', 'N', 'E'); // For BBRv2, always exit
// STARTUP on loss, even if
// bandwidth growth exceeds
// threshold.
const QuicTag kB2RP = TAG('B', '2', 'R', 'P'); // For BBRv2, run PROBE_RTT on
// the regular schedule
const QuicTag kB2LO = TAG('B', '2', 'L', 'O'); // Ignore inflight_lo in BBR2
const QuicTag kB2HR = TAG('B', '2', 'H', 'R'); // 15% inflight_hi headroom.
const QuicTag kB2SL = TAG('B', '2', 'S', 'L'); // When exiting STARTUP due to
// loss, set inflight_hi to the
// max of bdp and max bytes
// delivered in round.
const QuicTag kB2H2 = TAG('B', '2', 'H', '2'); // When exiting PROBE_UP due to
// loss, set inflight_hi to the
// max of inflight@send and max
// bytes delivered in round.
const QuicTag kB2RC = TAG('B', '2', 'R', 'C'); // Disable Reno-coexistence for
// BBR2.
const QuicTag kBSAO = TAG('B', 'S', 'A', 'O'); // Avoid Overestimation in
// Bandwidth Sampler with ack
// aggregation
const QuicTag kB2DL = TAG('B', '2', 'D', 'L'); // Increase inflight_hi based
// on delievered, not inflight.
const QuicTag kNTLP = TAG('N', 'T', 'L', 'P'); // No tail loss probe
const QuicTag k1TLP = TAG('1', 'T', 'L', 'P'); // 1 tail loss probe
const QuicTag k1RTO = TAG('1', 'R', 'T', 'O'); // Send 1 packet upon RTO
const QuicTag kNRTO = TAG('N', 'R', 'T', 'O'); // CWND reduction on loss
const QuicTag kTIME = TAG('T', 'I', 'M', 'E'); // Time based loss detection
const QuicTag kATIM = TAG('A', 'T', 'I', 'M'); // Adaptive time loss detection
const QuicTag kMIN1 = TAG('M', 'I', 'N', '1'); // Min CWND of 1 packet
const QuicTag kMIN4 = TAG('M', 'I', 'N', '4'); // Min CWND of 4 packets,
// with a min rate of 1 BDP.
const QuicTag kTLPR = TAG('T', 'L', 'P', 'R'); // Tail loss probe delay of
// 0.5RTT.
const QuicTag kMAD0 = TAG('M', 'A', 'D', '0'); // Ignore ack delay
const QuicTag kMAD1 = TAG('M', 'A', 'D', '1'); // 25ms initial max ack delay
const QuicTag kMAD2 = TAG('M', 'A', 'D', '2'); // No min TLP
const QuicTag kMAD3 = TAG('M', 'A', 'D', '3'); // No min RTO
const QuicTag kMAD4 = TAG('M', 'A', 'D', '4'); // IETF style TLP
const QuicTag kMAD5 = TAG('M', 'A', 'D', '5'); // IETF style TLP with 2x mult
const QuicTag k1ACK = TAG('1', 'A', 'C', 'K'); // 1 fast ack for reordering
const QuicTag kACD0 = TAG('A', 'D', 'D', '0'); // Disable ack decimation
const QuicTag kACKD = TAG('A', 'C', 'K', 'D'); // Ack decimation style acking.
const QuicTag kAKD2 = TAG('A', 'K', 'D', '2'); // Ack decimation tolerating
// out of order packets.
const QuicTag kAKD3 = TAG('A', 'K', 'D', '3'); // Ack decimation style acking
// with 1/8 RTT acks.
const QuicTag kAKD4 = TAG('A', 'K', 'D', '4'); // Ack decimation with 1/8 RTT
// tolerating out of order.
const QuicTag kAKDU = TAG('A', 'K', 'D', 'U'); // Unlimited number of packets
// received before acking
const QuicTag kACKQ = TAG('A', 'C', 'K', 'Q'); // Send an immediate ack after
// 1 RTT of not receiving.
const QuicTag kAFFE = TAG('A', 'F', 'F', 'E'); // Enable client receiving
// AckFrequencyFrame.
const QuicTag kAFF1 = TAG('A', 'F', 'F', '1'); // Use SRTT in building
// AckFrequencyFrame.
const QuicTag kAFF2 = TAG('A', 'F', 'F', '2'); // Send AckFrequencyFrame upon
// handshake completion.
const QuicTag kSSLR = TAG('S', 'S', 'L', 'R'); // Slow Start Large Reduction.
const QuicTag kNPRR = TAG('N', 'P', 'R', 'R'); // Pace at unity instead of PRR
const QuicTag k2RTO = TAG('2', 'R', 'T', 'O'); // Close connection on 2 RTOs
const QuicTag k3RTO = TAG('3', 'R', 'T', 'O'); // Close connection on 3 RTOs
const QuicTag k4RTO = TAG('4', 'R', 'T', 'O'); // Close connection on 4 RTOs
const QuicTag k5RTO = TAG('5', 'R', 'T', 'O'); // Close connection on 5 RTOs
const QuicTag k6RTO = TAG('6', 'R', 'T', 'O'); // Close connection on 6 RTOs
const QuicTag kCBHD = TAG('C', 'B', 'H', 'D'); // Client only blackhole
// detection.
const QuicTag kNBHD = TAG('N', 'B', 'H', 'D'); // No blackhole detection.
const QuicTag kCONH = TAG('C', 'O', 'N', 'H'); // Conservative Handshake
// Retransmissions.
const QuicTag kLFAK = TAG('L', 'F', 'A', 'K'); // Don't invoke FACK on the
// first ack.
const QuicTag kSTMP = TAG('S', 'T', 'M', 'P'); // Send and process timestamps
const QuicTag kEACK = TAG('E', 'A', 'C', 'K'); // Bundle ack-eliciting frame
// with an ACK after PTO/RTO
const QuicTag kILD0 = TAG('I', 'L', 'D', '0'); // IETF style loss detection
// (default with 1/8 RTT time
// threshold)
const QuicTag kILD1 = TAG('I', 'L', 'D', '1'); // IETF style loss detection
// with 1/4 RTT time threshold
const QuicTag kILD2 = TAG('I', 'L', 'D', '2'); // IETF style loss detection
// with adaptive packet
// threshold
const QuicTag kILD3 = TAG('I', 'L', 'D', '3'); // IETF style loss detection
// with 1/4 RTT time threshold
// and adaptive packet
// threshold
const QuicTag kILD4 = TAG('I', 'L', 'D', '4'); // IETF style loss detection
// with both adaptive time
// threshold (default 1/4 RTT)
// and adaptive packet
// threshold
const QuicTag kRUNT = TAG('R', 'U', 'N', 'T'); // No packet threshold loss
// detection for "runt" packet.
const QuicTag kNSTP = TAG('N', 'S', 'T', 'P'); // No stop waiting frames.
const QuicTag kNRTT = TAG('N', 'R', 'T', 'T'); // Ignore initial RTT
const QuicTag k1PTO = TAG('1', 'P', 'T', 'O'); // Send 1 packet upon PTO.
const QuicTag k2PTO = TAG('2', 'P', 'T', 'O'); // Send 2 packets upon PTO.
const QuicTag k6PTO = TAG('6', 'P', 'T', 'O'); // Closes connection on 6
// consecutive PTOs.
const QuicTag k7PTO = TAG('7', 'P', 'T', 'O'); // Closes connection on 7
// consecutive PTOs.
const QuicTag k8PTO = TAG('8', 'P', 'T', 'O'); // Closes connection on 8
// consecutive PTOs.
const QuicTag kPTOS = TAG('P', 'T', 'O', 'S'); // Skip packet number before
// sending the last PTO.
const QuicTag kPTOA = TAG('P', 'T', 'O', 'A'); // Do not add max ack delay
// when computing PTO timeout
// if an immediate ACK is
// expected.
const QuicTag kPEB1 = TAG('P', 'E', 'B', '1'); // Start exponential backoff
// since 1st PTO.
const QuicTag kPEB2 = TAG('P', 'E', 'B', '2'); // Start exponential backoff
// since 2nd PTO.
const QuicTag kPVS1 = TAG('P', 'V', 'S', '1'); // Use 2 * rttvar when
// calculating PTO timeout.
const QuicTag kPAG1 = TAG('P', 'A', 'G', '1'); // Make 1st PTO more aggressive
const QuicTag kPAG2 = TAG('P', 'A', 'G', '2'); // Make first 2 PTOs more
// aggressive
const QuicTag kPSDA = TAG('P', 'S', 'D', 'A'); // Use standard deviation when
// calculating PTO timeout.
const QuicTag kPLE1 = TAG('P', 'L', 'E', '1'); // Arm the 1st PTO with
// earliest in flight sent time
// and at least 0.5*srtt from
// last sent packet.
const QuicTag kPLE2 = TAG('P', 'L', 'E', '2'); // Arm the 1st PTO with
// earliest in flight sent time
// and at least 1.5*srtt from
// last sent packet.
const QuicTag kAPTO = TAG('A', 'P', 'T', 'O'); // Use 1.5 * initial RTT before
// any RTT sample is available.
const QuicTag kELDT = TAG('E', 'L', 'D', 'T'); // Enable Loss Detection Tuning
const QuicTag kRVCM = TAG('R', 'V', 'C', 'M'); // Validate the new address
// upon client address change.
// Optional support of truncated Connection IDs. If sent by a peer, the value
// is the minimum number of bytes allowed for the connection ID sent to the
// peer.
const QuicTag kTCID = TAG('T', 'C', 'I', 'D'); // Connection ID truncation.
// Multipath option.
const QuicTag kMPTH = TAG('M', 'P', 'T', 'H'); // Enable multipath.
const QuicTag kNCMR = TAG('N', 'C', 'M', 'R'); // Do not attempt connection
// migration.
// Allows disabling defer_send_in_response_to_packets in QuicConnection.
const QuicTag kDFER = TAG('D', 'F', 'E', 'R'); // Do not defer sending.
// Disable Pacing offload option.
const QuicTag kNPCO = TAG('N', 'P', 'C', 'O'); // No pacing offload.
// Enable bandwidth resumption experiment.
const QuicTag kBWRE = TAG('B', 'W', 'R', 'E'); // Bandwidth resumption.
const QuicTag kBWMX = TAG('B', 'W', 'M', 'X'); // Max bandwidth resumption.
const QuicTag kBWRS = TAG('B', 'W', 'R', 'S'); // Server bandwidth resumption.
const QuicTag kBWS2 = TAG('B', 'W', 'S', '2'); // Server bw resumption v2.
const QuicTag kBWS3 = TAG('B', 'W', 'S', '3'); // QUIC Initial CWND - Control.
const QuicTag kBWS4 = TAG('B', 'W', 'S', '4'); // QUIC Initial CWND - Enabled.
const QuicTag kBWS5 = TAG('B', 'W', 'S', '5'); // QUIC Initial CWND up and down
const QuicTag kBWS6 = TAG('B', 'W', 'S', '6'); // QUIC Initial CWND - Enabled
// with 0.5 * default
// multiplier.
const QuicTag kBWP0 = TAG('B', 'W', 'P', '0'); // QUIC Initial CWND - SPDY
// priority 0.
const QuicTag kBWP1 = TAG('B', 'W', 'P', '1'); // QUIC Initial CWND - SPDY
// priorities 0 and 1.
const QuicTag kBWP2 = TAG('B', 'W', 'P', '2'); // QUIC Initial CWND - SPDY
// priorities 0, 1 and 2.
const QuicTag kBWP3 = TAG('B', 'W', 'P', '3'); // QUIC Initial CWND - SPDY
// priorities 0, 1, 2 and 3.
const QuicTag kBWP4 = TAG('B', 'W', 'P', '4'); // QUIC Initial CWND - SPDY
// priorities >= 0, 1, 2, 3 and
// 4.
const QuicTag kBWG4 = TAG('B', 'W', 'G', '4'); // QUIC Initial CWND -
// Bandwidth model 1.
const QuicTag kBWG7 = TAG('B', 'W', 'G', '7'); // QUIC Initial CWND -
// Bandwidth model 2.
const QuicTag kBWG8 = TAG('B', 'W', 'G', '8'); // QUIC Initial CWND -
// Bandwidth model 3.
const QuicTag kBWS7 = TAG('B', 'W', 'S', '7'); // QUIC Initial CWND - Enabled
// with 0.75 * default
// multiplier.
const QuicTag kBWM3 = TAG('B', 'W', 'M', '3'); // Consider overshooting if
// bytes lost after bandwidth
// resumption * 3 > IW.
const QuicTag kBWM4 = TAG('B', 'W', 'M', '4'); // Consider overshooting if
// bytes lost after bandwidth
// resumption * 4 > IW.
const QuicTag kICW1 = TAG('I', 'C', 'W', '1'); // Max initial congestion window
// 100.
const QuicTag kDTOS = TAG('D', 'T', 'O', 'S'); // Enable overshooting
// detection.
const QuicTag kFIDT = TAG('F', 'I', 'D', 'T'); // Extend idle timer by PTO
// instead of the whole idle
// timeout.
const QuicTag k3AFF = TAG('3', 'A', 'F', 'F'); // 3 anti amplification factor.
const QuicTag k10AF = TAG('1', '0', 'A', 'F'); // 10 anti amplification factor.
// Enable path MTU discovery experiment.
const QuicTag kMTUH = TAG('M', 'T', 'U', 'H'); // High-target MTU discovery.
const QuicTag kMTUL = TAG('M', 'T', 'U', 'L'); // Low-target MTU discovery.
const QuicTag kNSLC = TAG('N', 'S', 'L', 'C'); // Always send connection close
// for idle timeout.
const QuicTag kNCHP = TAG('N', 'C', 'H', 'P'); // No chaos protection.
const QuicTag kNBPE = TAG('N', 'B', 'P', 'E'); // No BoringSSL Permutes
// TLS Extensions.
// Proof types (i.e. certificate types)
// NOTE: although it would be silly to do so, specifying both kX509 and kX59R
// is allowed and is equivalent to specifying only kX509.
const QuicTag kX509 = TAG('X', '5', '0', '9'); // X.509 certificate, all key
// types
const QuicTag kX59R = TAG('X', '5', '9', 'R'); // X.509 certificate, RSA keys
// only
const QuicTag kCHID = TAG('C', 'H', 'I', 'D'); // Channel ID.
// Client hello tags
const QuicTag kVER = TAG('V', 'E', 'R', '\0'); // Version
const QuicTag kNONC = TAG('N', 'O', 'N', 'C'); // The client's nonce
const QuicTag kNONP = TAG('N', 'O', 'N', 'P'); // The client's proof nonce
const QuicTag kKEXS = TAG('K', 'E', 'X', 'S'); // Key exchange methods
const QuicTag kAEAD = TAG('A', 'E', 'A', 'D'); // Authenticated
// encryption algorithms
const QuicTag kCOPT = TAG('C', 'O', 'P', 'T'); // Connection options
const QuicTag kCLOP = TAG('C', 'L', 'O', 'P'); // Client connection options
const QuicTag kICSL = TAG('I', 'C', 'S', 'L'); // Idle network timeout
const QuicTag kMIBS = TAG('M', 'I', 'D', 'S'); // Max incoming bidi streams
const QuicTag kMIUS = TAG('M', 'I', 'U', 'S'); // Max incoming unidi streams
const QuicTag kADE = TAG('A', 'D', 'E', 0); // Ack Delay Exponent (IETF
// QUIC ACK Frame Only).
const QuicTag kIRTT = TAG('I', 'R', 'T', 'T'); // Estimated initial RTT in us.
const QuicTag kSNI = TAG('S', 'N', 'I', '\0'); // Server name
// indication
const QuicTag kPUBS = TAG('P', 'U', 'B', 'S'); // Public key values
const QuicTag kSCID = TAG('S', 'C', 'I', 'D'); // Server config id
const QuicTag kORBT = TAG('O', 'B', 'I', 'T'); // Server orbit.
const QuicTag kPDMD = TAG('P', 'D', 'M', 'D'); // Proof demand.
const QuicTag kPROF = TAG('P', 'R', 'O', 'F'); // Proof (signature).
const QuicTag kCCS = TAG('C', 'C', 'S', 0); // Common certificate set
const QuicTag kCCRT = TAG('C', 'C', 'R', 'T'); // Cached certificate
const QuicTag kEXPY = TAG('E', 'X', 'P', 'Y'); // Expiry
const QuicTag kSTTL = TAG('S', 'T', 'T', 'L'); // Server Config TTL
const QuicTag kSFCW = TAG('S', 'F', 'C', 'W'); // Initial stream flow control
// receive window.
const QuicTag kCFCW = TAG('C', 'F', 'C', 'W'); // Initial session/connection
// flow control receive window.
const QuicTag kUAID = TAG('U', 'A', 'I', 'D'); // Client's User Agent ID.
const QuicTag kXLCT = TAG('X', 'L', 'C', 'T'); // Expected leaf certificate.
const QuicTag kQLVE = TAG('Q', 'L', 'V', 'E'); // Legacy Version
// Encapsulation.
const QuicTag kPDP2 = TAG('P', 'D', 'P', '2'); // Path degrading triggered
// at 2PTO.
const QuicTag kPDP3 = TAG('P', 'D', 'P', '3'); // Path degrading triggered
// at 3PTO.
const QuicTag kPDP4 = TAG('P', 'D', 'P', '4'); // Path degrading triggered
// at 4PTO.
const QuicTag kPDP5 = TAG('P', 'D', 'P', '5'); // Path degrading triggered
// at 5PTO.
const QuicTag kQNZ2 = TAG('Q', 'N', 'Z', '2'); // Turn off QUIC crypto 0-RTT.
const QuicTag kMAD = TAG('M', 'A', 'D', 0); // Max Ack Delay (IETF QUIC)
const QuicTag kIGNP = TAG('I', 'G', 'N', 'P'); // Do not use PING only packet
// for RTT measure or
// congestion control.
const QuicTag kSRWP = TAG('S', 'R', 'W', 'P'); // Enable retransmittable on
// wire PING (ROWP) on the
// server side.
// Rejection tags
const QuicTag kRREJ = TAG('R', 'R', 'E', 'J'); // Reasons for server sending
// Server hello tags
const QuicTag kCADR = TAG('C', 'A', 'D', 'R'); // Client IP address and port
const QuicTag kASAD = TAG('A', 'S', 'A', 'D'); // Alternate Server IP address
// and port.
const QuicTag kSRST = TAG('S', 'R', 'S', 'T'); // Stateless reset token used
// in IETF public reset packet
// CETV tags
const QuicTag kCIDK = TAG('C', 'I', 'D', 'K'); // ChannelID key
const QuicTag kCIDS = TAG('C', 'I', 'D', 'S'); // ChannelID signature
// Public reset tags
const QuicTag kRNON = TAG('R', 'N', 'O', 'N'); // Public reset nonce proof
const QuicTag kRSEQ = TAG('R', 'S', 'E', 'Q'); // Rejected packet number
// Universal tags
const QuicTag kPAD = TAG('P', 'A', 'D', '\0'); // Padding
// Stats collection tags
const QuicTag kEPID = TAG('E', 'P', 'I', 'D'); // Endpoint identifier.
// clang-format on
// These tags have a special form so that they appear either at the beginning
// or the end of a handshake message. Since handshake messages are sorted by
// tag value, the tags with 0 at the end will sort first and those with 255 at
// the end will sort last.
//
// The certificate chain should have a tag that will cause it to be sorted at
// the end of any handshake messages because it's likely to be large and the
// client might be able to get everything that it needs from the small values at
// the beginning.
//
// Likewise tags with random values should be towards the beginning of the
// message because the server mightn't hold state for a rejected client hello
// and therefore the client may have issues reassembling the rejection message
// in the event that it sent two client hellos.
const QuicTag kServerNonceTag = TAG('S', 'N', 'O', 0); // The server's nonce
const QuicTag kSourceAddressTokenTag =
TAG('S', 'T', 'K', 0); // Source-address token
const QuicTag kCertificateTag = TAG('C', 'R', 'T', 255); // Certificate chain
const QuicTag kCertificateSCTTag =
TAG('C', 'S', 'C', 'T'); // Signed cert timestamp (RFC6962) of leaf cert.
#undef TAG
const size_t kMaxEntries = 128; // Max number of entries in a message.
const size_t kNonceSize = 32; // Size in bytes of the connection nonce.
const size_t kOrbitSize = 8; // Number of bytes in an orbit value.
// kProofSignatureLabel is prepended to the CHLO hash and server configs before
// signing to avoid any cross-protocol attacks on the signature.
const char kProofSignatureLabel[] = "QUIC CHLO and server config signature";
// kClientHelloMinimumSize is the minimum size of a client hello. Client hellos
// will have PAD tags added in order to ensure this minimum is met and client
// hellos smaller than this will be an error. This minimum size reduces the
// amplification factor of any mirror DoS attack.
//
// A client may pad an inchoate client hello to a size larger than
// kClientHelloMinimumSize to make it more likely to receive a complete
// rejection message.
const size_t kClientHelloMinimumSize = 1024;
} // namespace quic
#endif // QUICHE_QUIC_CORE_CRYPTO_CRYPTO_PROTOCOL_H_