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// Copyright (c) 2013 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_QUIC_CONFIG_H_
#define QUICHE_QUIC_CORE_QUIC_CONFIG_H_
#include <cstddef>
#include <cstdint>
#include <string>
#include "absl/types/optional.h"
#include "quic/core/crypto/transport_parameters.h"
#include "quic/core/quic_connection_id.h"
#include "quic/core/quic_packets.h"
#include "quic/core/quic_time.h"
#include "quic/core/quic_types.h"
#include "quic/platform/api/quic_export.h"
namespace quic {
namespace test {
class QuicConfigPeer;
} // namespace test
class CryptoHandshakeMessage;
// Describes whether or not a given QuicTag is required or optional in the
// handshake message.
enum QuicConfigPresence : uint8_t {
// This negotiable value can be absent from the handshake message. Default
// value is selected as the negotiated value in such a case.
PRESENCE_OPTIONAL,
// This negotiable value is required in the handshake message otherwise the
// Process*Hello function returns an error.
PRESENCE_REQUIRED,
};
// Whether the CryptoHandshakeMessage is from the client or server.
enum HelloType {
CLIENT,
SERVER,
};
// An abstract base class that stores a value that can be sent in CHLO/SHLO
// message. These values can be OPTIONAL or REQUIRED, depending on |presence_|.
class QUIC_EXPORT_PRIVATE QuicConfigValue {
public:
QuicConfigValue(QuicTag tag, QuicConfigPresence presence);
virtual ~QuicConfigValue();
// Serialises tag name and value(s) to |out|.
virtual void ToHandshakeMessage(CryptoHandshakeMessage* out) const = 0;
// Selects a mutually acceptable value from those offered in |peer_hello|
// and those defined in the subclass.
virtual QuicErrorCode ProcessPeerHello(
const CryptoHandshakeMessage& peer_hello,
HelloType hello_type,
std::string* error_details) = 0;
protected:
const QuicTag tag_;
const QuicConfigPresence presence_;
};
// Stores uint32_t from CHLO or SHLO messages that are not negotiated.
class QUIC_EXPORT_PRIVATE QuicFixedUint32 : public QuicConfigValue {
public:
QuicFixedUint32(QuicTag name, QuicConfigPresence presence);
~QuicFixedUint32() override;
bool HasSendValue() const;
uint32_t GetSendValue() const;
void SetSendValue(uint32_t value);
bool HasReceivedValue() const;
uint32_t GetReceivedValue() const;
void SetReceivedValue(uint32_t value);
// If has_send_value is true, serialises |tag_| and |send_value_| to |out|.
void ToHandshakeMessage(CryptoHandshakeMessage* out) const override;
// Sets |value_| to the corresponding value from |peer_hello_| if it exists.
QuicErrorCode ProcessPeerHello(const CryptoHandshakeMessage& peer_hello,
HelloType hello_type,
std::string* error_details) override;
private:
bool has_send_value_;
bool has_receive_value_;
uint32_t send_value_;
uint32_t receive_value_;
};
// Stores 62bit numbers from handshake messages that unilaterally shared by each
// endpoint. IMPORTANT: these are serialized as 32-bit unsigned integers when
// using QUIC_CRYPTO versions and CryptoHandshakeMessage.
class QUIC_EXPORT_PRIVATE QuicFixedUint62 : public QuicConfigValue {
public:
QuicFixedUint62(QuicTag name, QuicConfigPresence presence);
~QuicFixedUint62() override;
bool HasSendValue() const;
uint64_t GetSendValue() const;
void SetSendValue(uint64_t value);
bool HasReceivedValue() const;
uint64_t GetReceivedValue() const;
void SetReceivedValue(uint64_t value);
// If has_send_value is true, serialises |tag_| and |send_value_| to |out|.
// IMPORTANT: this method serializes |send_value_| as an unsigned 32bit
// integer.
void ToHandshakeMessage(CryptoHandshakeMessage* out) const override;
// Sets |value_| to the corresponding value from |peer_hello_| if it exists.
QuicErrorCode ProcessPeerHello(const CryptoHandshakeMessage& peer_hello,
HelloType hello_type,
std::string* error_details) override;
private:
bool has_send_value_;
bool has_receive_value_;
uint64_t send_value_;
uint64_t receive_value_;
};
// Stores StatelessResetToken from CHLO or SHLO messages that are not
// negotiated.
class QUIC_EXPORT_PRIVATE QuicFixedStatelessResetToken
: public QuicConfigValue {
public:
QuicFixedStatelessResetToken(QuicTag tag, QuicConfigPresence presence);
~QuicFixedStatelessResetToken() override;
bool HasSendValue() const;
const StatelessResetToken& GetSendValue() const;
void SetSendValue(const StatelessResetToken& value);
bool HasReceivedValue() const;
const StatelessResetToken& GetReceivedValue() const;
void SetReceivedValue(const StatelessResetToken& value);
// If has_send_value is true, serialises |tag_| and |send_value_| to |out|.
void ToHandshakeMessage(CryptoHandshakeMessage* out) const override;
// Sets |value_| to the corresponding value from |peer_hello_| if it exists.
QuicErrorCode ProcessPeerHello(const CryptoHandshakeMessage& peer_hello,
HelloType hello_type,
std::string* error_details) override;
private:
bool has_send_value_;
bool has_receive_value_;
StatelessResetToken send_value_;
StatelessResetToken receive_value_;
};
// Stores tag from CHLO or SHLO messages that are not negotiated.
class QUIC_EXPORT_PRIVATE QuicFixedTagVector : public QuicConfigValue {
public:
QuicFixedTagVector(QuicTag name, QuicConfigPresence presence);
QuicFixedTagVector(const QuicFixedTagVector& other);
~QuicFixedTagVector() override;
bool HasSendValues() const;
const QuicTagVector& GetSendValues() const;
void SetSendValues(const QuicTagVector& values);
bool HasReceivedValues() const;
const QuicTagVector& GetReceivedValues() const;
void SetReceivedValues(const QuicTagVector& values);
// If has_send_value is true, serialises |tag_vector_| and |send_value_| to
// |out|.
void ToHandshakeMessage(CryptoHandshakeMessage* out) const override;
// Sets |receive_values_| to the corresponding value from |client_hello_| if
// it exists.
QuicErrorCode ProcessPeerHello(const CryptoHandshakeMessage& peer_hello,
HelloType hello_type,
std::string* error_details) override;
private:
bool has_send_values_;
bool has_receive_values_;
QuicTagVector send_values_;
QuicTagVector receive_values_;
};
// Stores QuicSocketAddress from CHLO or SHLO messages that are not negotiated.
class QUIC_EXPORT_PRIVATE QuicFixedSocketAddress : public QuicConfigValue {
public:
QuicFixedSocketAddress(QuicTag tag, QuicConfigPresence presence);
~QuicFixedSocketAddress() override;
bool HasSendValue() const;
const QuicSocketAddress& GetSendValue() const;
void SetSendValue(const QuicSocketAddress& value);
bool HasReceivedValue() const;
const QuicSocketAddress& GetReceivedValue() const;
void SetReceivedValue(const QuicSocketAddress& value);
void ToHandshakeMessage(CryptoHandshakeMessage* out) const override;
QuicErrorCode ProcessPeerHello(const CryptoHandshakeMessage& peer_hello,
HelloType hello_type,
std::string* error_details) override;
private:
bool has_send_value_;
bool has_receive_value_;
QuicSocketAddress send_value_;
QuicSocketAddress receive_value_;
};
// QuicConfig contains non-crypto configuration options that are negotiated in
// the crypto handshake.
class QUIC_EXPORT_PRIVATE QuicConfig {
public:
QuicConfig();
QuicConfig(const QuicConfig& other);
~QuicConfig();
void SetConnectionOptionsToSend(const QuicTagVector& connection_options);
bool HasReceivedConnectionOptions() const;
// Sets initial received connection options. All received connection options
// will be initialized with these fields. Initial received options may only be
// set once per config, prior to the setting of any other options. If options
// have already been set (either by previous calls or via handshake), this
// function does nothing and returns false.
bool SetInitialReceivedConnectionOptions(const QuicTagVector& tags);
const QuicTagVector& ReceivedConnectionOptions() const;
bool HasSendConnectionOptions() const;
const QuicTagVector& SendConnectionOptions() const;
// Returns true if the client is sending or the server has received a
// connection option.
// TODO(ianswett): Rename to HasClientRequestedSharedOption
bool HasClientSentConnectionOption(QuicTag tag,
Perspective perspective) const;
void SetClientConnectionOptions(
const QuicTagVector& client_connection_options);
// Returns true if the client has requested the specified connection option.
// Checks the client connection options if the |perspective| is client and
// connection options if the |perspective| is the server.
bool HasClientRequestedIndependentOption(QuicTag tag,
Perspective perspective) const;
const QuicTagVector& ClientRequestedIndependentOptions(
Perspective perspective) const;
void SetIdleNetworkTimeout(QuicTime::Delta idle_network_timeout);
QuicTime::Delta IdleNetworkTimeout() const;
// Sets the max bidirectional stream count that this endpoint supports.
void SetMaxBidirectionalStreamsToSend(uint32_t max_streams);
uint32_t GetMaxBidirectionalStreamsToSend() const;
bool HasReceivedMaxBidirectionalStreams() const;
// Gets the max bidirectional stream limit imposed by the peer.
uint32_t ReceivedMaxBidirectionalStreams() const;
// Sets the max unidirectional stream count that this endpoint supports.
void SetMaxUnidirectionalStreamsToSend(uint32_t max_streams);
uint32_t GetMaxUnidirectionalStreamsToSend() const;
bool HasReceivedMaxUnidirectionalStreams() const;
// Gets the max unidirectional stream limit imposed by the peer.
uint32_t ReceivedMaxUnidirectionalStreams() const;
void set_max_time_before_crypto_handshake(
QuicTime::Delta max_time_before_crypto_handshake) {
max_time_before_crypto_handshake_ = max_time_before_crypto_handshake;
}
QuicTime::Delta max_time_before_crypto_handshake() const {
return max_time_before_crypto_handshake_;
}
void set_max_idle_time_before_crypto_handshake(
QuicTime::Delta max_idle_time_before_crypto_handshake) {
max_idle_time_before_crypto_handshake_ =
max_idle_time_before_crypto_handshake;
}
QuicTime::Delta max_idle_time_before_crypto_handshake() const {
return max_idle_time_before_crypto_handshake_;
}
void set_max_undecryptable_packets(size_t max_undecryptable_packets) {
max_undecryptable_packets_ = max_undecryptable_packets;
}
size_t max_undecryptable_packets() const {
return max_undecryptable_packets_;
}
// Peer's connection id length, in bytes. Only used in Q043 and Q046.
bool HasSetBytesForConnectionIdToSend() const;
void SetBytesForConnectionIdToSend(uint32_t bytes);
bool HasReceivedBytesForConnectionId() const;
uint32_t ReceivedBytesForConnectionId() const;
// Estimated initial round trip time in us.
void SetInitialRoundTripTimeUsToSend(uint64_t rtt_us);
bool HasReceivedInitialRoundTripTimeUs() const;
uint64_t ReceivedInitialRoundTripTimeUs() const;
bool HasInitialRoundTripTimeUsToSend() const;
uint64_t GetInitialRoundTripTimeUsToSend() const;
// Sets an initial stream flow control window size to transmit to the peer.
void SetInitialStreamFlowControlWindowToSend(uint64_t window_bytes);
uint64_t GetInitialStreamFlowControlWindowToSend() const;
bool HasReceivedInitialStreamFlowControlWindowBytes() const;
uint64_t ReceivedInitialStreamFlowControlWindowBytes() const;
// Specifies the initial flow control window (max stream data) for
// incoming bidirectional streams. Incoming means streams initiated by our
// peer. If not set, GetInitialMaxStreamDataBytesIncomingBidirectionalToSend
// returns the value passed to SetInitialStreamFlowControlWindowToSend.
void SetInitialMaxStreamDataBytesIncomingBidirectionalToSend(
uint64_t window_bytes);
uint64_t GetInitialMaxStreamDataBytesIncomingBidirectionalToSend() const;
bool HasReceivedInitialMaxStreamDataBytesIncomingBidirectional() const;
uint64_t ReceivedInitialMaxStreamDataBytesIncomingBidirectional() const;
// Specifies the initial flow control window (max stream data) for
// outgoing bidirectional streams. Outgoing means streams initiated by us.
// If not set, GetInitialMaxStreamDataBytesOutgoingBidirectionalToSend
// returns the value passed to SetInitialStreamFlowControlWindowToSend.
void SetInitialMaxStreamDataBytesOutgoingBidirectionalToSend(
uint64_t window_bytes);
uint64_t GetInitialMaxStreamDataBytesOutgoingBidirectionalToSend() const;
bool HasReceivedInitialMaxStreamDataBytesOutgoingBidirectional() const;
uint64_t ReceivedInitialMaxStreamDataBytesOutgoingBidirectional() const;
// Specifies the initial flow control window (max stream data) for
// unidirectional streams. If not set,
// GetInitialMaxStreamDataBytesUnidirectionalToSend returns the value passed
// to SetInitialStreamFlowControlWindowToSend.
void SetInitialMaxStreamDataBytesUnidirectionalToSend(uint64_t window_bytes);
uint64_t GetInitialMaxStreamDataBytesUnidirectionalToSend() const;
bool HasReceivedInitialMaxStreamDataBytesUnidirectional() const;
uint64_t ReceivedInitialMaxStreamDataBytesUnidirectional() const;
// Sets an initial session flow control window size to transmit to the peer.
void SetInitialSessionFlowControlWindowToSend(uint64_t window_bytes);
uint64_t GetInitialSessionFlowControlWindowToSend() const;
bool HasReceivedInitialSessionFlowControlWindowBytes() const;
uint64_t ReceivedInitialSessionFlowControlWindowBytes() const;
// Disable connection migration.
void SetDisableConnectionMigration();
bool DisableConnectionMigration() const;
// Key update support.
void SetKeyUpdateSupportedLocally();
bool KeyUpdateSupportedForConnection() const;
bool KeyUpdateSupportedLocally() const;
bool KeyUpdateSupportedRemotely() const;
// IPv6 alternate server address.
void SetIPv6AlternateServerAddressToSend(
const QuicSocketAddress& alternate_server_address_ipv6);
void SetIPv6AlternateServerAddressToSend(
const QuicSocketAddress& alternate_server_address_ipv6,
const QuicConnectionId& connection_id,
const StatelessResetToken& stateless_reset_token);
bool HasReceivedIPv6AlternateServerAddress() const;
const QuicSocketAddress& ReceivedIPv6AlternateServerAddress() const;
// IPv4 alternate server address.
void SetIPv4AlternateServerAddressToSend(
const QuicSocketAddress& alternate_server_address_ipv4);
void SetIPv4AlternateServerAddressToSend(
const QuicSocketAddress& alternate_server_address_ipv4,
const QuicConnectionId& connection_id,
const StatelessResetToken& stateless_reset_token);
bool HasReceivedIPv4AlternateServerAddress() const;
const QuicSocketAddress& ReceivedIPv4AlternateServerAddress() const;
// Preferred Address Connection ID and Token.
bool HasReceivedPreferredAddressConnectionIdAndToken() const;
const std::pair<QuicConnectionId, StatelessResetToken>&
ReceivedPreferredAddressConnectionIdAndToken() const;
// Original destination connection ID.
void SetOriginalConnectionIdToSend(
const QuicConnectionId& original_destination_connection_id);
bool HasReceivedOriginalConnectionId() const;
QuicConnectionId ReceivedOriginalConnectionId() const;
// Stateless reset token.
void SetStatelessResetTokenToSend(
const StatelessResetToken& stateless_reset_token);
bool HasReceivedStatelessResetToken() const;
const StatelessResetToken& ReceivedStatelessResetToken() const;
// Manage the IETF QUIC Max ACK Delay transport parameter.
// The sent value is the delay that this node uses
// (QuicSentPacketManager::local_max_ack_delay_).
// The received delay is the value received from
// the peer (QuicSentPacketManager::peer_max_ack_delay_).
void SetMaxAckDelayToSendMs(uint32_t max_ack_delay_ms);
uint32_t GetMaxAckDelayToSendMs() const;
bool HasReceivedMaxAckDelayMs() const;
uint32_t ReceivedMaxAckDelayMs() const;
// Manage the IETF QUIC extension Min Ack Delay transport parameter.
// An endpoint uses min_ack_delay to advsertise its support for
// AckFrequencyFrame sent by peer.
void SetMinAckDelayMs(uint32_t min_ack_delay_ms);
uint32_t GetMinAckDelayToSendMs() const;
bool HasReceivedMinAckDelayMs() const;
uint32_t ReceivedMinAckDelayMs() const;
void SetAckDelayExponentToSend(uint32_t exponent);
uint32_t GetAckDelayExponentToSend() const;
bool HasReceivedAckDelayExponent() const;
uint32_t ReceivedAckDelayExponent() const;
// IETF QUIC max_udp_payload_size transport parameter.
void SetMaxPacketSizeToSend(uint64_t max_udp_payload_size);
uint64_t GetMaxPacketSizeToSend() const;
bool HasReceivedMaxPacketSize() const;
uint64_t ReceivedMaxPacketSize() const;
// IETF QUIC max_datagram_frame_size transport parameter.
void SetMaxDatagramFrameSizeToSend(uint64_t max_datagram_frame_size);
uint64_t GetMaxDatagramFrameSizeToSend() const;
bool HasReceivedMaxDatagramFrameSize() const;
uint64_t ReceivedMaxDatagramFrameSize() const;
// IETF QUIC active_connection_id_limit transport parameter.
void SetActiveConnectionIdLimitToSend(uint64_t active_connection_id_limit);
uint64_t GetActiveConnectionIdLimitToSend() const;
bool HasReceivedActiveConnectionIdLimit() const;
uint64_t ReceivedActiveConnectionIdLimit() const;
// Initial source connection ID.
void SetInitialSourceConnectionIdToSend(
const QuicConnectionId& initial_source_connection_id);
bool HasReceivedInitialSourceConnectionId() const;
QuicConnectionId ReceivedInitialSourceConnectionId() const;
// Retry source connection ID.
void SetRetrySourceConnectionIdToSend(
const QuicConnectionId& retry_source_connection_id);
bool HasReceivedRetrySourceConnectionId() const;
QuicConnectionId ReceivedRetrySourceConnectionId() const;
bool negotiated() const;
void SetCreateSessionTagIndicators(QuicTagVector tags);
const QuicTagVector& create_session_tag_indicators() const;
// ToHandshakeMessage serialises the settings in this object as a series of
// tags /value pairs and adds them to |out|.
void ToHandshakeMessage(CryptoHandshakeMessage* out,
QuicTransportVersion transport_version) const;
// Calls ProcessPeerHello on each negotiable parameter. On failure returns
// the corresponding QuicErrorCode and sets detailed error in |error_details|.
QuicErrorCode ProcessPeerHello(const CryptoHandshakeMessage& peer_hello,
HelloType hello_type,
std::string* error_details);
// FillTransportParameters writes the values to send for ICSL, MIDS, CFCW, and
// SFCW to |*params|, returning true if the values could be written and false
// if something prevents them from being written (e.g. a value is too large).
bool FillTransportParameters(TransportParameters* params) const;
// ProcessTransportParameters reads from |params| which were received from a
// peer. If |is_resumption|, some configs will not be processed.
// On failure, it returns a QuicErrorCode and puts a detailed error in
// |*error_details|.
QuicErrorCode ProcessTransportParameters(const TransportParameters& params,
bool is_resumption,
std::string* error_details);
TransportParameters::ParameterMap& custom_transport_parameters_to_send() {
return custom_transport_parameters_to_send_;
}
const TransportParameters::ParameterMap&
received_custom_transport_parameters() const {
return received_custom_transport_parameters_;
}
private:
friend class test::QuicConfigPeer;
// SetDefaults sets the members to sensible, default values.
void SetDefaults();
// Whether we've received the peer's config.
bool negotiated_;
// Configurations options that are not negotiated.
// Maximum time the session can be alive before crypto handshake is finished.
QuicTime::Delta max_time_before_crypto_handshake_;
// Maximum idle time before the crypto handshake has completed.
QuicTime::Delta max_idle_time_before_crypto_handshake_;
// Maximum number of undecryptable packets stored before CHLO/SHLO.
size_t max_undecryptable_packets_;
// Connection options which affect the server side. May also affect the
// client side in cases when identical behavior is desirable.
QuicFixedTagVector connection_options_;
// Connection options which only affect the client side.
QuicFixedTagVector client_connection_options_;
// Maximum idle network timeout.
// Uses the max_idle_timeout transport parameter in IETF QUIC.
// Note that received_max_idle_timeout_ is only populated if we receive the
// peer's value, which isn't guaranteed in IETF QUIC as sending is optional.
QuicTime::Delta max_idle_timeout_to_send_;
absl::optional<QuicTime::Delta> received_max_idle_timeout_;
// Maximum number of dynamic streams that a Google QUIC connection
// can support or the maximum number of bidirectional streams that
// an IETF QUIC connection can support.
// The SendValue is the limit on peer-created streams that this endpoint is
// advertising.
// The ReceivedValue is the limit on locally-created streams that
// the peer advertised.
// Uses the initial_max_streams_bidi transport parameter in IETF QUIC.
QuicFixedUint32 max_bidirectional_streams_;
// Maximum number of unidirectional streams that the connection can
// support.
// The SendValue is the limit on peer-created streams that this endpoint is
// advertising.
// The ReceivedValue is the limit on locally-created streams that the peer
// advertised.
// Uses the initial_max_streams_uni transport parameter in IETF QUIC.
QuicFixedUint32 max_unidirectional_streams_;
// The number of bytes required for the connection ID. This is only used in
// the legacy header format used only by Q043 at this point.
QuicFixedUint32 bytes_for_connection_id_;
// Initial round trip time estimate in microseconds.
QuicFixedUint62 initial_round_trip_time_us_;
// Initial IETF QUIC stream flow control receive windows in bytes.
// Incoming bidirectional streams.
// Uses the initial_max_stream_data_bidi_{local,remote} transport parameter
// in IETF QUIC, depending on whether we're sending or receiving.
QuicFixedUint62 initial_max_stream_data_bytes_incoming_bidirectional_;
// Outgoing bidirectional streams.
// Uses the initial_max_stream_data_bidi_{local,remote} transport parameter
// in IETF QUIC, depending on whether we're sending or receiving.
QuicFixedUint62 initial_max_stream_data_bytes_outgoing_bidirectional_;
// Unidirectional streams.
// Uses the initial_max_stream_data_uni transport parameter in IETF QUIC.
QuicFixedUint62 initial_max_stream_data_bytes_unidirectional_;
// Initial Google QUIC stream flow control receive window in bytes.
QuicFixedUint62 initial_stream_flow_control_window_bytes_;
// Initial session flow control receive window in bytes.
// Uses the initial_max_data transport parameter in IETF QUIC.
QuicFixedUint62 initial_session_flow_control_window_bytes_;
// Whether active connection migration is allowed.
// Uses the disable_active_migration transport parameter in IETF QUIC.
QuicFixedUint32 connection_migration_disabled_;
// Whether key update is supported by the peer. Uses key_update_not_yet
// supported transport parameter in IETF QUIC.
bool key_update_supported_remotely_;
// Whether key update is supported locally.
bool key_update_supported_locally_;
// Alternate server addresses the client could connect to.
// Uses the preferred_address transport parameter in IETF QUIC.
// Note that when QUIC_CRYPTO is in use, only one of the addresses is sent.
QuicFixedSocketAddress alternate_server_address_ipv6_;
QuicFixedSocketAddress alternate_server_address_ipv4_;
// Connection Id data to send from the server or receive at the client as part
// of the preferred address transport parameter.
absl::optional<std::pair<QuicConnectionId, StatelessResetToken>>
preferred_address_connection_id_and_token_;
// Stateless reset token used in IETF public reset packet.
// Uses the stateless_reset_token transport parameter in IETF QUIC.
QuicFixedStatelessResetToken stateless_reset_token_;
// List of QuicTags whose presence immediately causes the session to
// be created. This allows for CHLOs that are larger than a single
// packet to be processed.
QuicTagVector create_session_tag_indicators_;
// Maximum ack delay. The sent value is the value used on this node.
// The received value is the value received from the peer and used by
// the peer.
// Uses the max_ack_delay transport parameter in IETF QUIC.
QuicFixedUint32 max_ack_delay_ms_;
// Minimum ack delay. Used to enable sender control of max_ack_delay.
// Uses the min_ack_delay transport parameter in IETF QUIC extension.
QuicFixedUint32 min_ack_delay_ms_;
// The sent exponent is the exponent that this node uses when serializing an
// ACK frame (and the peer should use when deserializing the frame);
// the received exponent is the value the peer uses to serialize frames and
// this node uses to deserialize them.
// Uses the ack_delay_exponent transport parameter in IETF QUIC.
QuicFixedUint32 ack_delay_exponent_;
// Maximum packet size in bytes.
// Uses the max_udp_payload_size transport parameter in IETF QUIC.
QuicFixedUint62 max_udp_payload_size_;
// Maximum DATAGRAM/MESSAGE frame size in bytes.
// Uses the max_datagram_frame_size transport parameter in IETF QUIC.
QuicFixedUint62 max_datagram_frame_size_;
// Maximum number of connection IDs from the peer.
// Uses the active_connection_id_limit transport parameter in IETF QUIC.
QuicFixedUint62 active_connection_id_limit_;
// The value of the Destination Connection ID field from the first
// Initial packet sent by the client.
// Uses the original_destination_connection_id transport parameter in
// IETF QUIC.
absl::optional<QuicConnectionId> original_destination_connection_id_to_send_;
absl::optional<QuicConnectionId> received_original_destination_connection_id_;
// The value that the endpoint included in the Source Connection ID field of
// the first Initial packet it sent.
// Uses the initial_source_connection_id transport parameter in IETF QUIC.
absl::optional<QuicConnectionId> initial_source_connection_id_to_send_;
absl::optional<QuicConnectionId> received_initial_source_connection_id_;
// The value that the server included in the Source Connection ID field of a
// Retry packet it sent.
// Uses the retry_source_connection_id transport parameter in IETF QUIC.
absl::optional<QuicConnectionId> retry_source_connection_id_to_send_;
absl::optional<QuicConnectionId> received_retry_source_connection_id_;
// Custom transport parameters that can be sent and received in the TLS
// handshake.
TransportParameters::ParameterMap custom_transport_parameters_to_send_;
TransportParameters::ParameterMap received_custom_transport_parameters_;
};
} // namespace quic
#endif // QUICHE_QUIC_CORE_QUIC_CONFIG_H_