openssl/ssl/quic/quic_channel_local.h
Hugo Landau 2031c0e928 QLOG: Wiring: QUIC CHANNEL
Reviewed-by: Matt Caswell <matt@openssl.org>
Reviewed-by: Neil Horman <nhorman@openssl.org>
(Merged from https://github.com/openssl/openssl/pull/22037)
2024-02-02 11:49:34 +00:00

445 lines
17 KiB
C

#ifndef OSSL_QUIC_CHANNEL_LOCAL_H
# define OSSL_QUIC_CHANNEL_LOCAL_H
# include "internal/quic_channel.h"
# ifndef OPENSSL_NO_QUIC
# include <openssl/lhash.h>
# include "internal/list.h"
# include "internal/quic_predef.h"
# include "internal/quic_fc.h"
# include "internal/quic_stream_map.h"
/*
* QUIC Channel Structure
* ======================
*
* QUIC channel internals. It is intended that only the QUIC_CHANNEL
* implementation and the RX depacketiser be allowed to access this structure
* directly. As the RX depacketiser has no state of its own and computes over a
* QUIC_CHANNEL structure, it can be viewed as an extension of the QUIC_CHANNEL
* implementation. While the RX depacketiser could be provided with adequate
* accessors to do what it needs, this would weaken the abstraction provided by
* the QUIC_CHANNEL to other components; moreover the coupling of the RX
* depacketiser to QUIC_CHANNEL internals is too deep and bespoke to make this
* desirable.
*
* Other components should not include this header.
*/
struct quic_channel_st {
QUIC_PORT *port;
/*
* QUIC_PORT keeps the channels which belong to it on a list for bookkeeping
* purposes.
*/
OSSL_LIST_MEMBER(ch, struct quic_channel_st);
/*
* The associated TLS 1.3 connection data. Used to provide the handshake
* layer; its 'network' side is plugged into the crypto stream for each EL
* (other than the 0-RTT EL).
*/
QUIC_TLS *qtls;
SSL *tls;
/* Port LCIDM we use to register LCIDs. */
QUIC_LCIDM *lcidm;
/* SRTM we register SRTs with. */
QUIC_SRTM *srtm;
/* Optional QLOG instance (or NULL). */
QLOG *qlog;
/*
* The transport parameter block we will send or have sent.
* Freed after sending or when connection is freed.
*/
unsigned char *local_transport_params;
/* Our current L4 peer address, if any. */
BIO_ADDR cur_peer_addr;
/*
* Subcomponents of the connection. All of these components are instantiated
* and owned by us.
*/
OSSL_QUIC_TX_PACKETISER *txp;
QUIC_TXPIM *txpim;
QUIC_CFQ *cfq;
/*
* Connection level FC. The stream_count RXFCs is used to manage
* MAX_STREAMS signalling.
*/
QUIC_TXFC conn_txfc;
QUIC_RXFC conn_rxfc, crypto_rxfc[QUIC_PN_SPACE_NUM];
QUIC_RXFC max_streams_bidi_rxfc, max_streams_uni_rxfc;
QUIC_STREAM_MAP qsm;
OSSL_STATM statm;
OSSL_CC_DATA *cc_data;
const OSSL_CC_METHOD *cc_method;
OSSL_ACKM *ackm;
/* Record layers in the TX and RX directions. */
OSSL_QTX *qtx;
OSSL_QRX *qrx;
/* Message callback related arguments */
ossl_msg_cb msg_callback;
void *msg_callback_arg;
SSL *msg_callback_ssl;
/*
* Send and receive parts of the crypto streams.
* crypto_send[QUIC_PN_SPACE_APP] is the 1-RTT crypto stream. There is no
* 0-RTT crypto stream.
*/
QUIC_SSTREAM *crypto_send[QUIC_PN_SPACE_NUM];
QUIC_RSTREAM *crypto_recv[QUIC_PN_SPACE_NUM];
/* Internal state. */
/*
* Client: The DCID used in the first Initial packet we transmit as a client.
* Server: The DCID used in the first Initial packet the client transmitted.
* Randomly generated and required by RFC to be at least 8 bytes.
*/
QUIC_CONN_ID init_dcid;
/*
* Client: The SCID found in the first Initial packet from the server.
* Not valid for servers.
* Valid if have_received_enc_pkt is set.
*/
QUIC_CONN_ID init_scid;
/*
* Client only: The SCID found in an incoming Retry packet we handled.
* Not valid for servers.
*/
QUIC_CONN_ID retry_scid;
/*
* The DCID we currently use to talk to the peer and its sequence num.
*/
QUIC_CONN_ID cur_remote_dcid;
uint64_t cur_remote_seq_num;
uint64_t cur_retire_prior_to;
/* Server only: The DCID we currently expect the peer to use to talk to us. */
QUIC_CONN_ID cur_local_cid;
/* Transport parameter values we send to our peer. */
uint64_t tx_init_max_stream_data_bidi_local;
uint64_t tx_init_max_stream_data_bidi_remote;
uint64_t tx_init_max_stream_data_uni;
uint64_t tx_max_ack_delay; /* ms */
/* Transport parameter values received from server. */
uint64_t rx_init_max_stream_data_bidi_local;
uint64_t rx_init_max_stream_data_bidi_remote;
uint64_t rx_init_max_stream_data_uni;
uint64_t rx_max_ack_delay; /* ms */
unsigned char rx_ack_delay_exp;
/*
* Temporary staging area to store information about the incoming packet we
* are currently processing.
*/
OSSL_QRX_PKT *qrx_pkt;
/*
* Current limit on number of streams we may create. Set by transport
* parameters initially and then by MAX_STREAMS frames.
*/
uint64_t max_local_streams_bidi;
uint64_t max_local_streams_uni;
/* The negotiated maximum idle timeout in milliseconds. */
uint64_t max_idle_timeout;
/*
* Maximum payload size in bytes for datagrams sent to our peer, as
* negotiated by transport parameters.
*/
uint64_t rx_max_udp_payload_size;
/* Maximum active CID limit, as negotiated by transport parameters. */
uint64_t rx_active_conn_id_limit;
/*
* Used to allocate stream IDs. This is a stream ordinal, i.e., a stream ID
* without the low two bits designating type and initiator. Shift and or in
* the type bits to convert to a stream ID.
*/
uint64_t next_local_stream_ordinal_bidi;
uint64_t next_local_stream_ordinal_uni;
/*
* Used to track which stream ordinals within a given stream type have been
* used by the remote peer. This is an optimisation used to determine
* which streams should be implicitly created due to usage of a higher
* stream ordinal.
*/
uint64_t next_remote_stream_ordinal_bidi;
uint64_t next_remote_stream_ordinal_uni;
/*
* Application error code to be used for STOP_SENDING/RESET_STREAM frames
* used to autoreject incoming streams.
*/
uint64_t incoming_stream_auto_reject_aec;
/*
* Override packet count threshold at which we do a spontaneous TXKU.
* Usually UINT64_MAX in which case a suitable value is chosen based on AEAD
* limit advice from the QRL utility functions. This is intended for testing
* use only. Usually set to UINT64_MAX.
*/
uint64_t txku_threshold_override;
/* Diagnostic counters for testing purposes only. May roll over. */
uint16_t diag_num_rx_ack; /* Number of ACK frames received */
/* Valid if we are in the TERMINATING or TERMINATED states. */
QUIC_TERMINATE_CAUSE terminate_cause;
/*
* Deadline at which we move to TERMINATING state. Valid if in the
* TERMINATING state.
*/
OSSL_TIME terminate_deadline;
/*
* Deadline at which connection dies due to idle timeout if no further
* events occur.
*/
OSSL_TIME idle_deadline;
/*
* Deadline at which we should send an ACK-eliciting packet to ensure
* idle timeout does not occur.
*/
OSSL_TIME ping_deadline;
/*
* The deadline at which the period in which it is RECOMMENDED that we not
* initiate any spontaneous TXKU ends. This is zero if no such deadline
* applies.
*/
OSSL_TIME txku_cooldown_deadline;
/*
* The deadline at which we take the QRX out of UPDATING and back to NORMAL.
* Valid if rxku_in_progress in 1.
*/
OSSL_TIME rxku_update_end_deadline;
/*
* The first (application space) PN sent with a new key phase. Valid if the
* QTX key epoch is greater than 0. Once a packet we sent with a PN p (p >=
* txku_pn) is ACKed, the TXKU is considered completed and txku_in_progress
* becomes 0. For sanity's sake, such a PN p should also be <= the highest
* PN we have ever sent, of course.
*/
QUIC_PN txku_pn;
/*
* The (application space) PN which triggered RXKU detection. Valid if
* rxku_pending_confirm.
*/
QUIC_PN rxku_trigger_pn;
/*
* State tracking. QUIC connection-level state is best represented based on
* whether various things have happened yet or not, rather than as an
* explicit FSM. We do have a coarse state variable which tracks the basic
* state of the connection's lifecycle, but more fine-grained conditions of
* the Active state are tracked via flags below. For more details, see
* doc/designs/quic-design/connection-state-machine.md. We are in the Open
* state if the state is QUIC_CHANNEL_STATE_ACTIVE and handshake_confirmed is
* set.
*/
unsigned int state : 3;
/*
* Have we received at least one encrypted packet from the peer?
* (If so, Retry and Version Negotiation messages should no longer
* be received and should be ignored if they do occur.)
*/
unsigned int have_received_enc_pkt : 1;
/*
* Have we successfully processed any packet, including a Version
* Negotiation packet? If so, further Version Negotiation packets should be
* ignored.
*/
unsigned int have_processed_any_pkt : 1;
/*
* Have we sent literally any packet yet? If not, there is no point polling
* RX.
*/
unsigned int have_sent_any_pkt : 1;
/*
* Are we currently doing proactive version negotiation?
*/
unsigned int doing_proactive_ver_neg : 1;
/* We have received transport parameters from the peer. */
unsigned int got_remote_transport_params : 1;
/*
* This monotonically transitions to 1 once the TLS state machine is
* 'complete', meaning that it has both sent a Finished and successfully
* verified the peer's Finished (see RFC 9001 s. 4.1.1). Note that it
* does not transition to 1 at both peers simultaneously.
*
* Handshake completion is not the same as handshake confirmation (see
* below).
*/
unsigned int handshake_complete : 1;
/*
* This monotonically transitions to 1 once the handshake is confirmed.
* This happens on the client when we receive a HANDSHAKE_DONE frame.
* At our option, we may also take acknowledgement of any 1-RTT packet
* we sent as a handshake confirmation.
*/
unsigned int handshake_confirmed : 1;
/*
* We are sending Initial packets based on a Retry. This means we definitely
* should not receive another Retry, and if we do it is an error.
*/
unsigned int doing_retry : 1;
/*
* We don't store the current EL here; the TXP asks the QTX which ELs
* are provisioned to determine which ELs to use.
*/
/* Have statm, qsm been initialised? Used to track cleanup. */
unsigned int have_statm : 1;
unsigned int have_qsm : 1;
/*
* Preferred ELs for transmission and reception. This is not strictly needed
* as it can be inferred from what keys we have provisioned, but makes
* determining the current EL simpler and faster. A separate EL for
* transmission and reception is not strictly necessary but makes things
* easier for interoperation with the handshake layer, which likes to invoke
* the yield secret callback at different times for TX and RX.
*/
unsigned int tx_enc_level : 3;
unsigned int rx_enc_level : 3;
/* If bit n is set, EL n has been discarded. */
unsigned int el_discarded : 4;
/*
* While in TERMINATING - CLOSING, set when we should generate a connection
* close frame.
*/
unsigned int conn_close_queued : 1;
/* Are we in server mode? Never changes after instantiation. */
unsigned int is_server : 1;
/*
* Set temporarily when the handshake layer has given us a new RX secret.
* Used to determine if we need to check our RX queues again.
*/
unsigned int have_new_rx_secret : 1;
/* Have we ever called QUIC_TLS yet during RX processing? */
unsigned int did_tls_tick : 1;
/* Has any CRYPTO frame been processed during this tick? */
unsigned int did_crypto_frame : 1;
/*
* Have we sent an ack-eliciting packet since the last successful packet
* reception? Used to determine when to bump idle timer (see RFC 9000 s.
* 10.1).
*/
unsigned int have_sent_ack_eliciting_since_rx : 1;
/* Should incoming streams automatically be rejected? */
unsigned int incoming_stream_auto_reject : 1;
/*
* 1 if a key update sequence was locally initiated, meaning we sent the
* TXKU first and the resultant RXKU shouldn't result in our triggering
* another TXKU. 0 if a key update sequence was initiated by the peer,
* meaning we detect a RXKU first and have to generate a TXKU in response.
*/
unsigned int ku_locally_initiated : 1;
/*
* 1 if we have triggered TXKU (whether spontaneous or solicited) but are
* waiting for any PN using that new KP to be ACKed. While this is set, we
* are not allowed to trigger spontaneous TXKU (but solicited TXKU is
* potentially still possible).
*/
unsigned int txku_in_progress : 1;
/*
* We have received an RXKU event and currently are going through
* UPDATING/COOLDOWN on the QRX. COOLDOWN is currently not used. Since RXKU
* cannot be detected in this state, this doesn't cause a protocol error or
* anything similar if a peer tries TXKU in this state. That traffic would
* simply be dropped. It's only used to track that our UPDATING timer is
* active so we know when to take the QRX out of UPDATING and back to
* NORMAL.
*/
unsigned int rxku_in_progress : 1;
/*
* We have received an RXKU but have yet to send an ACK for it, which means
* no further RXKUs are allowed yet. Note that we cannot detect further
* RXKUs anyway while the QRX remains in the UPDATING/COOLDOWN states, so
* this restriction comes into play if we take more than PTO time to send
* an ACK for it (not likely).
*/
unsigned int rxku_pending_confirm : 1;
/* Temporary variable indicating rxku_pending_confirm is to become 0. */
unsigned int rxku_pending_confirm_done : 1;
/*
* If set, RXKU is expected (because we initiated a spontaneous TXKU).
*/
unsigned int rxku_expected : 1;
/* Permanent net error encountered */
unsigned int net_error : 1;
/*
* Protocol error encountered. Note that you should refer to the state field
* rather than this. This is only used so we can ignore protocol errors
* after the first protocol error, but still record the first protocol error
* if it happens during the TERMINATING state.
*/
unsigned int protocol_error : 1;
/* Are we using addressed mode? */
unsigned int addressed_mode : 1;
/* Are we on the QUIC_PORT linked list of channels? */
unsigned int on_port_list : 1;
/* Has QLOG been requested? */
unsigned int use_qlog : 1;
/* Saved error stack in case permanent error was encountered */
ERR_STATE *err_state;
/* Scratch area for use by RXDP to store decoded ACK ranges. */
OSSL_QUIC_ACK_RANGE *ack_range_scratch;
size_t num_ack_range_scratch;
};
# endif
#endif