This document sets out the objectives of the QUIC API design process, describes the new and changed APIs, and the design constraints motivating those API designs and the relevant design decisions.
SSL_set_connect_state
SSL_set_accept_state
SSL_is_server
SSL_connect
SSL_accept
SSL_do_handshake
SSL_read
, SSL_read_ex
, SSL_peek
, SSL_peek_ex
SSL_write
, SSL_write_ex
SSL_pending
SSL_has_pending
SSL_shutdown
SSL_clear
SSL_free
SSL_set0_rbio
, SSL_set0_wbio
, SSL_set_bio
SSL_set_[rw]fd
SSL_get_[rw]fd
SSL_CTRL_MODE
, SSL_CTRL_CLEAR_MODE
SSL_handle_events
SSL_get_event_timeout
SSL_set_blocking_mode
, SSL_get_blocking_mode
SSL_get_rpoll_descriptor
, SSL_get_wpoll_descriptor
SSL_net_read_desired
, SSL_net_write_desired
SSL_want
, SSL_want_read
, SSL_want_write
SSL_set1_initial_peer_addr
SSL_shutdown_ex
SSL_stream_conclude
SSL_stream_reset
SSL_get_stream_state
SSL_get_stream_read_error_code
, SSL_get_stream_write_error_code
SSL_get_conn_close_info
SSL_get0_connection
SSL_is_connection
SSL_get_stream_type
SSL_get_stream_id
SSL_is_stream_local
SSL_new_stream
SSL_accept_stream
SSL_get_accept_stream_queue_len
SSL_set_incoming_stream_policy
SSL_set_default_stream_mode
A listing of all SSL object APIs and their implications for QUIC, including current implementation status, can be found in quic-api-ssl-funcs.md.
Non-SSL object APIs which are new or changed, or otherwise discussed in this document are listed below, along with their implementation status. SSL object APIs are not listed here; see quic-api-ssl-funcs.md for details on SSL object APIs.
Semantics | API | Status |
---|---|---|
Changed | BIO_s_connect |
Done |
Unchanged | BIO_set_conn_hostname |
Done |
N/A | BIO_new_bio_pair |
N/A (see BIO_new_bio_dgram_pair ) |
New | BIO_s_dgram_pair |
Done |
Unchanged | BIO_dgram_get_mtu |
Done |
Unchanged | BIO_dgram_set_mtu |
Done |
New | BIO_sendmmsg |
Done |
New | BIO_recvmmsg |
Done |
New | BIO_dgram_set_no_trunc |
Done |
New | BIO_dgram_get_no_trunc |
Done |
New | BIO_dgram_set_caps |
Done |
New | BIO_dgram_get_caps |
Done |
New | BIO_dgram_get_effective_caps |
Done |
New | BIO_dgram_get_local_addr_cap |
Done |
New | BIO_dgram_set_local_addr_enable |
Done |
New | BIO_dgram_get_local_addr_enable |
Done |
New | BIO_get_rpoll_descriptor |
Done |
New | BIO_get_wpoll_descriptor |
Done |
New | BIO_err_is_non_fatal |
Done |
The objectives of the QUIC API design are:
to provide an API suitable for use with QUIC, now and in the future;
to reuse the existing libssl APIs to the extent feasible;
to enable existing applications to adapt to using QUIC with only minimal API changes.
Each API listed below has an information table with the following fields:
Semantics: This can be one of:
SSL_get_error
: Can this API, when used with QUIC, change the
state returned by SSL_get_error
? This can be any combination of:
SSL_get_error
.WANT_READ
/WANT_WRITE
errors can be raised.WANT_READ
/WANT_WRITE
can be raised.Can Tick?: Whether this function is allowed to perform event processing for the QUIC state machine and potentially perform network I/O.
CSHL: Connection/Stream/Handshake Layer classification. This can be one of:
HL: This is a handshake layer related call. It should be supported on a QUIC connection SSL object, forwarding to the handshake layer SSL object. QUIC stream SSL objects do not allow these calls to be forwarded.
HL-Forbidden: This is a handshake layer related call, but it is inapplicable to QUIC, so it is not supported.
C: Not handshake-layer related. QUIC connection SSL object usage only. Fails on a QUIC stream SSL object.
CS: Not handshake-layer related. Can be used on any QUIC SSL object.
S: Requires a QUIC stream SSL object or a QUIC connection SSL object with a default stream attached.
SSL_set_connect_state
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Never | No | HL |
SSL_set_accept_state
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Never | No | HL |
Note: Attempting to proceed in this state will not function for now because we do not implement server support at this time. However, the semantics of this function as such are unchanged.
SSL_is_server
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Never | No | HL |
SSL_connect
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Error/Want | Yes | HL |
Simple composition of SSL_set_connect_state
and SSL_do_handshake
.
SSL_accept
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Error/Want | Yes | HL |
Simple composition of SSL_set_accept_state
and SSL_do_handshake
.
SSL_do_handshake
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Error/Want | Yes | HL |
Note: Idempotent if handshake already completed.
Blocking Considerations: Blocks until handshake completed if in blocking mode.
SSL_read
, SSL_read_ex
, SSL_peek
, SSL_peek_ex
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Error/Want | Yes | CS |
Blocking Considerations: Blocks until at least one byte is available or an error occurs if in blocking mode (including the peek functions).
If the read part of the stream has been finished by the peer, calls to
SSL_read
will fail with SSL_ERROR_ZERO_RETURN
.
If a stream has terminated in a non-normal fashion (for example because the
stream has been reset, or the connection has terminated), calls to SSL_read
will fail with SSL_ERROR_SSL
.
SSL_get_stream_read_state
can be used to clarify the stream state when an
error occurs.
SSL_write
, SSL_write_ex
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Error/Want | Yes | CS |
We have to implement all of the following modes:
SSL_MODE_ENABLE_PARTIAL_WRITE
on or offSSL_MODE_ACCEPT_MOVING_WRITE_BUFFER
on or offBlocking Considerations: Blocks until libssl has accepted responsibility for (i.e., copied) all data provided, or an error occurs, if in blocking mode. In other words, it blocks until it can buffer the data. This does not necessarily mean that the data has actually been sent.
SSL_get_stream_write_state
can be used to clarify the stream state when an
error occurs.
SSL_pending
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Never | No | CS |
SSL_has_pending
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Never | No | CS |
TBD. Options:
SSL_pending() || any RXE
queued || any URXE queued
).SSL_shutdown
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Error | Yes | CS |
See SSL_shutdown_ex
below for discussion of how this will work for QUIC.
Calling SSL_shutdown
is always exactly identical in function to calling
SSL_shutdown_ex
with flags
set to 0 and args
set to NULL
.
SSL_clear
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
TBD | TBD | No | C |
There are potential implementation hazards:
SSL_clear() resets the SSL object to allow for another connection. The reset operation however keeps several settings of the last sessions (some of these settings were made automatically during the last handshake). It only makes sense for a new connection with the exact same peer that shares these settings, and may fail if that peer changes its settings between connections.
TBD: How should SSL_clear
be implemented? Either:
SSL_clear
semantics at the handshake layer, reset all QUIC state
(QUIC_CHANNEL
torn down, CSM reset).TBD: Semantics of this on stream objects.
SSL_free
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Changed | Never | No | CS |
QUIC stream SSL objects. When used on a QUIC stream SSL object, parts of the stream state may continue to exist internally, managed inside the QUIC connection SSL object, until they can be correctly torn down, or until the QUIC connection SSL object is freed.
If a QUIC stream SSL object is freed for a stream which has not reached a
terminal state for all of its parts (both send and receive, as applicable), the
stream is automatically reset (non-normal termination) with an application error
code of 0. To explicitly reset a stream with a different application error code,
call SSL_stream_reset
before calling this function.
If the peer continues to send data on the stream before it processes the notification of the stream's termination, that incoming data will be discarded. However, the peer will be reliably notified of the non-normal termination of the stream assuming that the connection remains healthy.
When freeing a QUIC stream SSL object which was terminated in a non-normal
fashion, or which was terminated automatically due to a call to this function,
any data which was appended to the stream via SSL_write
may or may not have
already been transmitted, and even if already transmitted, may or may not be
retransmitted in the event of loss.
When freeing a QUIC stream SSL object which was terminated normally (for example
via SSL_stream_conclude
), data appended to the stream via SSL_write
will
still be transmitted or retransmitted as necessary, assuming that the QUIC
connection SSL object is not freed and that the connection remains healthy.
QUIC connection SSL objects. SSL_free
is largely unchanged for QUIC
connection SSL objects on the client side. When freeing a QUIC connection SSL
object being used in client mode, there is immediate termination of any QUIC
network I/O processing as the resources needed to handle the connection are
immediately freed. This means that, if a QUIC connection SSL object which has
not been shutdown properly is freed using this function:
Any data which was pending transmission or retransmission will not be transmitted, including in streams which were terminated normally;
The connection closure process will not function correctly or in an RFC-compliant manner. Connection closure will not be signalled to the peer and the connection will simply disappear from the perspective of the peer. The connection will appear to remain active until the connection's idle timeout (if negotiated) takes effect.
For further discussion of this issue, see SSL_shutdown_ex
and the Q&A.
SSL_set0_rbio
, SSL_set0_wbio
, SSL_set_bio
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Changed | Never | No | C |
Sets network-side BIO.
The changes to the semantics of these calls are as follows:
The BIO MUST be a BIO with datagram semantics (this is a change relative to TLS, though not to DTLS).
If the BIO is non-pollable (see below), application-level blocking mode will be forced off.
SSL_set_[rw]fd
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Changed | Never | No | C |
Sets network-side socket FD.
Existing behaviour: Instantiates a BIO_s_socket
, sets an FD on it, and sets it
as the BIO.
New proposed behaviour:
BIO_s_dgram
instead for a QUIC connection SSL object.SSL_get_[rw]fd
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Never | No | C |
Should not require any changes.
SSL_CTRL_MODE
, SSL_CTRL_CLEAR_MODE
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
Unchanged | Never | No | CS |
SSL_MODE_ENABLE_PARTIAL_WRITE
: Implemented. If this mode is set during a
non-partial-write SSL_write
operation spanning multiple SSL_write
calls,
this mode does not take effect until the non-partial write operation is
completed.
SSL_MODE_ACCEPT_MOVING_WRITE_BUFFER
: Implemented.
SSL_MODE_AUTO_RETRY
: TBD.
SSL_MODE_RELEASE_BUFFERS
: Ignored. This is an optimization and if it has
any sensible semantic correspondence to QUIC, this can be considered later.
SSL_MODE_SEND_FALLBACK_SCSV
: TBD: Either ignore or fail if the client
attempts to set this prior to handshake. The latter is probably safer.
Ignored if set after handshake (existing behaviour).
SSL_MODE_ASYNC
: TBD.SSL_handle_events
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | Yes | CS |
Advances the QUIC state machine to the extent feasible, potentially performing
network I/O. Also compatible with DTLSv1 and supersedes DTLSv1_handle_timeout
for all use cases.
SSL_get_event_timeout
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | CS |
Gets the time until the QUIC state machine next wants to receive a timeout event, if any.
This is similar to the existing DTLSv1_get_timeout
function, but it is not
specific to DTLSv1. It is also usable for DTLSv1 and can become a
protocol-agnostic API for this purpose, superseding DTLSv1_get_timeout
for all
use cases.
The design is similar to that of DTLSv1_get_timeout
and uses a struct
timeval
. However, this function can also output an infinite timeout using the
is_infinite
argument, whereas whereas DTLSv1_get_timeout
represents an
infinite timeout using a 0 return value, which does not allow a failure
condition to be distinguished.
SSL_set_blocking_mode
, SSL_get_blocking_mode
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | CS |
Turns blocking mode on or off. This is necessary because up until now libssl has operated in blocking or non-blocking mode automatically as an emergent consequence of whether the underlying network socket is blocking. For QUIC, this is no longer viable, thus blocking semantics at the application level must be explicitly configured.
Use on stream objects: It may be feasible to implement this such that different QUIC stream SSL objects can have different settings for this option.
Not supported for non-QUIC SSL objects.
SSL_get_rpoll_descriptor
, SSL_get_wpoll_descriptor
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | CS |
These functions output poll descriptors which can be used to determine when the
QUIC state machine next needs to have events handled. SSL_get_rpoll_descriptor
is relevant if SSL_net_read_desired
returns 1, and SSL_get_wpoll_descriptor
is relevant if SSL_net_write_desired
returns 1.
The implementation of these functions is a simple forward to
BIO_get_rpoll_descriptor
and BIO_get_wpoll_descriptor
on the underlying
network BIOs.
TODO: Support these for non-QUIC SSL objects
SSL_net_read_desired
, SSL_net_write_desired
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | CS |
These calls return 1 if the QUIC state machine is interested in receiving
further data from the network, or writing to the network, respectively. The
return values of these calls should be used to determine which wakeup events
should cause an application to call SSL_handle_events
. These functions do not
mutate any state, and their return values may change after a call to any SSL
function other than SSL_net_read_desired
, SSL_net_write_desired
,
SSL_get_rpoll_descriptor
, SSL_get_wpoll_descriptor
and
SSL_get_event_timeout
.
TODO: Support these for non-QUIC SSL objects, turning this into a unified
replacement for SSL_want
SSL_want
, SSL_want_read
, SSL_want_write
The existing API SSL_want
, and the macros defined in terms of it, are
traditionally used to determine if the SSL state machine has exited in
non-blocking mode due to a desire to read from or write to the underlying
network BIO. However, this API is unsuitable for use with QUIC because the
return value of SSL_want
can only express one I/O direction at a time (read or
write), not both. This call will not be implemented for QUIC (e.g. always
returns SSL_NOTHING
) and SSL_net_read_desired
and SSL_net_write_desired
will be used instead.
SSL_set1_initial_peer_addr
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | CS |
SSL_set1_initial_peer_addr
sets the initial L4 UDP peer address for an outgoing
QUIC connection.
The initial peer address may be autodetected if no peer address has already been
set explicitly and the QUIC connection SSL object is provided with a
BIO_s_dgram
with a peer set.
SSL_set1_initial_peer_addr
cannot be called after a connection is established.
SSL_shutdown_ex
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Error | Yes | C |
typedef struct ssl_shutdown_ex_args_st {
/* These arguments pertain only to QUIC connections. */
uint64_t quic_error_code; /* [0, 2**62-1] */
const char *quic_reason;
} SSL_SHUTDOWN_EX_ARGS;
#define SSL_SHUTDOWN_FLAG_RAPID (1U << 0)
#define SSL_SHUTDOWN_FLAG_IMMEDIATE (1U << 1)
int SSL_shutdown_ex(SSL *ssl,
uint64_t flags,
const SSL_SHUTDOWN_EX_ARGS *args,
size_t args_len);
SSL_shutdown_ex
is an extended version of SSL_shutdown
.
args
specifies arguments which control how the SSL object is shut down. args
are read only on the first call to SSL_shutdown_ex
for a given SSL object and
subsequent calls to SSL_shutdown_ex
ignore the args
argument. args_len
should be set to sizeof(*args)
. This function is idempotent; once the shutdown
process for a SSL object is complete, further calls are a no-op and return 1.
Calling SSL_shutdown_ex
on a QUIC connection SSL object causes the immediate
close of the QUIC connection. “Immediate close” is as defined by RFC 9000.
If no QUIC connection attempt was ever initiated using the given SSL object, the QUIC connection transitions immediately to the Terminated state. Otherwise, the connection closure process is initiated if it has not already begun.
Any application stream data on a non-terminated or normally terminated stream
which has yet to be transmitted is flushed to the network before the termination
process begins. This ensures that where an application which calls SSL_write
and performs a connection closure in a way which is considered normal to the
application protocol being used, all of the data written is delivered to the
peer. This behaviour may be skipped by setting the SSL_SHUTDOWN_FLAG_IMMEDIATE
flag, in which case any data appended to streams via SSL_write
(or any
end-of-stream conditions) may not be transmitted to the peer. This flag may be
useful where a non-normal application condition has occurred and the delivery of
data written to streams via SSL_write
is no longer relevant. Application
stream data on streams which were terminated non-normally (for example via
SSL_stream_reset
) is not transmitted by this function.
A QUIC connection can be shut down using this function in two different ways:
In blocking mode, the function will return once the closure process is
complete. In non-blocking mode, SSL_shutdown_ex
should be called until it
returns 1, indicating the closure process is complete and the connection is
now terminated.
CONNECTION_CLOSE
frame is sent in a
best-effort manner and the connection is terminated immediately. If the
CONNECTION_CLOSE
frame sent is lost, the peer will not know that the
connection has terminated until the negotiated idle timeout (if any) expires.This will generally return 0 on success, indicating that the connection has not yet reached the Terminating state (unless it has already done so, in which case it will return 1).
In blocking mode, this blocks until at least one CONNECTION_CLOSE
frame is
sent but does not otherwise block. In non-blocking mode, this should be called
until it returns a non-negative value. A negative value indicates failure or
an I/O would-block condition.
It is permissible for an application to implement a hybrid approach, for example
by initiating a rapid or non-blocking shutdown and continuing to call
SSL_handle_events
for a duration it chooses.
If SSL_SHUTDOWN_FLAG_RAPID
is specified in flags
, a rapid shutdown is
performed, otherwise an RFC-compliant shutdown is performed. The principal
effect of this flag is to partially disable blocking behaviour in blocking mode,
and the QUIC implementation will still attempt to implement the Terminating
state semantics if the application happens to call SSL_handle_events
, until it
reaches the Terminated state or is freed. An application can change its mind
about performing a rapid shutdown by making a subsequent call to
SSL_shutdown_ex
without the flag set.
Calling SSL_shutdown_ex
on a QUIC stream SSL object is not valid; such a call
will fail and has no effect. The rationale for this is that an application may
well want to pass around SSL objects for individual QUIC streams to existing
parts of its own code which expect something which behaves like a typical SSL
object (i.e., a single bytestream); those components may well already call
SSL_shutdown
and it is not desired for such calls to affect the whole
connection.
The args->quic_error_code
and args->reason
fields allow the application
error code and reason string for the closure of a QUIC connection to be
specified. If args
or args->reason
is NULL
, a zero-length string is used
for the reason. If args
is NULL
, an error code of 0 is used.
args->quic_error_code
must be in the range [0, 2**62-1]
, else this function
fails. These fields are ignored for SSL objects which do not represent QUIC
connections.
SSL_stream_conclude
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Error | Yes | S |
int SSL_stream_conclude(SSL *ssl, uint64_t flags);
SSL_stream_conclude
signals the normal end-of-stream condition to the send
part of a QUIC stream. If called on a QUIC connection SSL object with a default
stream, it signals the end of that stream to the peer. If called on a QUIC
stream SSL object, it signals the end of that stream to the peer.
This function may only be called for bidirectional streams and for outgoing unidirectional streams. It is a no-op if it has already been called for a given stream, or if either the stream or connection have entered an error state.
Any data already queued for transmission via a call to SSL_write()
will still
be written in a reliable manner before the end-of-stream is signalled, assuming
the connection remains healthy. This function can be thought of as appending a
logical end-of-stream marker after any data which has previously been written to
the stream via calls to SSL_write
. Further attempts to call SSL_write
after
calling this function will fail.
When calling this on a bidirectional stream, the receive part of the stream
remains unaffected, and the peer may continue to send data via it until the peer
also signals the end of the stream. Thus, SSL_read()
can still be used.
This function is used to conclude the send part of a stream in a normal manner.
To perform non-normal termination of both the sending and receiving parts of a
stream, see SSL_stream_reset
.
flags
is reserved and should be set to 0.
SSL_stream_reset
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Error | Yes | S |
typedef struct ssl_stream_reset_args_st {
uint64_t quic_error_code; /* [0, 2**62-1] */
} SSL_STREAM_RESET_ARGS;
int SSL_stream_reset(SSL *ssl,
const SSL_STREAM_RESET_ARGS *args,
size_t args_len);
Conducts a non-normal termination of a bidirectional or outgoing unidirectional
stream. For QUIC, this corresponds to a stream reset using a RESET_STREAM
frame.
It may be called on either a QUIC stream SSL object or a QUIC connection SSL object with a default stream; the given stream is reset. The QUIC connection is not affected.
For bidirectional streams, this terminates both sending and receiving parts of the stream. It may not be called on an incoming unidirectional stream.
If args
is NULL
, an application error code of 0 is used. Otherwise, the
application error code to use is specified in args->quic_error_code
, which
must be in the range [0, 2**62-1]
. args_len
must be set to sizeof(*args)
if args
is non-NULL.
Only the first call to this function has any effect; subsequent calls are no-ops. This is considered a success case.
SSL_get_stream_state
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | S |
/*
* e.g. Non-QUIC SSL object, or QUIC connection SSL object without a default
* stream.
*/
#define SSL_STREAM_STATE_NONE 0
/*
* The read or write part of the stream is still available and has not been
* terminated in a normal or non-normal manner.
*/
#define SSL_STREAM_STATE_OK 1
/*
* The stream is a unidirectional stream and this direction cannot be used; for
* example, a remotely initiated unidirectional stream where
* SSL_get_stream_write_state is called, or a locally initiated unidirectional
* stream where SSL_get_stream_read_state is
called.
*/
#define SSL_STREAM_STATE_WRONG_DIR 2
/*
* The read or write part of the stream has been finished in a normal manner.
*
* For SSL_get_stream_read_state, this means that there is no more data to read,
* and that any future SSL_read calls will return any residual data waiting to
* be read followed by a SSL_ERROR_ZERO_RETURN condition.
*
* For SSL_get_stream_write_state, this means that the local application has
* already indicated the end of the stream by calling SSL_stream_conclude,
* and that future calls to SSL_write will fail.
*/
#define SSL_STREAM_STATE_FINISHED 3
/*
* The stream was reset by the local party.
*
* For SSL_get_stream_read_state, this means that the stream was aborted using a
* locally transmitted STOP_SENDING frame. Attempts to read from the stream via
* SSL_read will fail, though SSL_read may allow any residual data waiting to
* be read to be read first.
*
* For SSL_get_stream_write_state, this means that the stream was aborted
* using a locally transmitted RESET_STREAM frame. Attempts to write to
* the stream will fail.
*/
#define SSL_STREAM_STATE_RESET_LOCAL 4
/*
* The stream was reset by the remote party.
*
* For SSL_get_stream_read_state, this means the peer sent a STREAM_RESET
* frame for the stream.
*
* For SSL_get_stream_write_state, this means the peer sent a STOP_SENDING
* frame for the stream.
*/
#define SSL_STREAM_STATE_RESET_REMOTE 5
/*
* The underlying connection supporting the stream has closed or otherwise
* failed.
*
* For SSL_get_stream_read_state, this means that attempts to read from the
* stream via SSL_read will fail, though SSL_read may allow any residual
* data waiting to be read to be read first.
*
* For SSL_get_stream_write_state, this means that attempts to write to the
* stream will fail.
*/
#define SSL_STREAM_STATE_CONN_CLOSED 6
int SSL_get_stream_read_state(SSL *ssl);
int SSL_get_stream_write_state(SSL *ssl);
This API allows the current state of a stream to be queried. This allows an application to determine whether a stream is still usable and why a stream has reached an error state.
SSL_get_stream_read_error_code
, SSL_get_stream_write_error_code
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | S |
int SSL_get_stream_read_error_code(SSL *ssl, uint64_t *app_error_code);
int SSL_get_stream_write_error_code(SSL *ssl, uint64_t *app_error_code);
SSL_get_stream_read_error_code
gets the error code for the read part of the
stream.
SSL_get_stream_write_error_code
gets the error code for the write part of
the stream.
If a stream has been terminated normally, returns 0.
If a stream has been terminated non-normally, returns 1 and writes the
applicable application error code to *app_error_code
.
If a stream is still healthy, or was healthy at the time the connection was closed, or the respective part of the stream does not exist (e.g. for a unidirectional stream), returns -1.
SSL_get_conn_close_info
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | C |
#define SSL_CONN_CLOSE_FLAG_LOCAL
#define SSL_CONN_CLOSE_FLAG_TRANSPORT
typedef struct ssl_conn_close_info_st {
uint64_t error_code;
char *reason;
size_t reason_len;
uint32_t flags;
} SSL_CONN_CLOSE_INFO;
int SSL_get_conn_close_info(SSL *ssl,
SSL_CONN_CLOSE_INFO *info,
size_t info_len);
If a connection is still healthy, returns 0. Otherwise, fills *info
with
information about the error causing connection termination and returns 1.
info_len
must be set to sizeof(*info)
. Returns -1 if called on a non-QUIC
SSL object or if the connection status cannot be determined.
info->reason
is set to point to a buffer containing a reason string. The
buffer is valid for the lifetime of the SSL object. The reason string will
always be zero terminated, but since it is received from a potentially untrusted
peer, may also contain zero bytes. info->reason_len
is the true length of the
reason string in bytes.
info->flags
has SSL_CONN_CLOSE_FLAG_LOCAL
set if the connection closure was
locally initiated.
info->flags
has SSL_CONN_CLOSE_FLAG_TRANSPORT
if the connection closure was
initiated by QUIC, and 0 if it was initiated by the application. The namespace
of info->error_code
is determined by this parameter.
The above new APIs are built on constructively to facilitate multi-stream operation.
The concept of a QUIC stream SSL object is introduced. A QUIC SSL object is either a QUIC connection SSL object or a QUIC stream SSL object. A QUIC stream SSL object belongs to a QUIC connection SSL object. A QUIC connection SSL object may or may not have an associated default stream. There may only be at most one default stream for a QUIC connection SSL object. Reading or writing application data to a QUIC connection SSL object with a default stream is equivalent to reading or writing to that stream. It is an error to attempt to read or write application data, or perform other stream-specific operations, on a QUIC connection SSL object without a default stream associated.
Initially these APIs will not be thread safe over the same connection, but in the longer term we intend to support multiple threads using different QUIC stream SSL objects on different threads over the same connection without the application having to do any locking. This is referred to as multi-stream multi-thread (MSMT) operation. Only APIs explicitly denoted below will eventually be MSMT-safe.
The blocking mode can be configured on each SSL object individually. When a QUIC
stream SSL object is created it inherits its blocking state from the currently
configured blocking state of the QUIC connection SSL object at the time the
stream is created. This can be changed independently. For example, a QUIC
connection SSL object can be in blocking mode to allow for blocking
SSL_accept_stream
calls, yet have some or all QUIC stream SSL objects be in
non-blocking mode concurrently.
An API may be added in the future to allow applications to poll multiple QUIC connection SSL objects efficiently for new stream and stream readability events. This is not yet urgent but will be more relevant for concurrent server applications.
SSL_get0_connection
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | CS |
/*
* Get the SSL object representing the connection associated with this object.
*
* If the SSL object represents a non-QUIC method or a QUIC connection, this
* returns the same object passed.
*
* If the SSL object represents a QUIC stream returns the QUIC connection
* object.
*/
SSL *SSL_get0_connection(SSL *ssl);
SSL_is_connection
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | CS |
/*
* Returns 1 if the object represents a connection. This always returns 1 for
* non-QUIC methods, but returns 0 for SSL objects for QUIC streams which are
* not also the QUIC connection object.
*
* This is exactly equivalent to (SSL_get0_connection(ssl) == ssl).
*/
int SSL_is_connection(SSL *ssl);
SSL_get_stream_type
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | S |
/*
* If the object represents a stream, returns a SSL_STREAM_TYPE value
* designating whether the stream can be used for transmission, reception,
* or both.
*
* This always returns SSL_STREAM_TYPE_BIDI for non-QUIC methods.
*
* It returns SSL_STREAM_TYPE_NONE for a QUIC connection object if it
* does not have a default stream.
*/
#define SSL_STREAM_TYPE_NONE 0
#define SSL_STREAM_TYPE_READ 1
#define SSL_STREAM_TYPE_WRITE 2
#define SSL_STREAM_TYPE_BIDI (SSL_STREAM_TYPE_READ | SSL_STREAM_TYPE_WRITE)
__owur int SSL_get_stream_type(SSL *ssl);
SSL_get_stream_id
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | S |
/*
* QUIC: Returns the unique stream ID for the stream, an integer in range [0, 2**62-1],
* or UINT64_MAX if the stream ID is not available. If called on a QUIC
* connection, returns the unique stream ID for the default stream if there is
* one, and otherwise returns UINT64_MAX.
*
* TLS, DTLS: Returns UINT64_MAX.
*/
__owur uint64_t SSL_get_stream_id(SSL *ssl);
SSL_is_stream_local
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | S |
/*
* QUIC: Returns 1 if the stream was locally initiated, or 0 otherwise.
*
* TLS, DTLS: Returns -1.
*/
__owur int SSL_is_stream_local(SSL *ssl);
SSL_new_stream
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | C |
/*
* Create a new SSL object representing a single additional stream.
*
* There is no need to call SSL_connect on the resulting object, and
* any such call is a no-op.
*
* For QUIC:
* Creates a new stream. Must be called only on a QUIC connection SSL object.
* Can be used on client or server. If the SSL_STREAM_FLAG_UNI flag is set,
* the created stream is unidirectional, otherwise it is bidirectional.
*
* To be MSMT-safe.
*
* For TLS and DTLS SSL objects:
* Always fails.
*/
#define SSL_STREAM_FLAG_UNI 1
SSL *SSL_new_stream(SSL *ssl, uint64_t flags);
SSL_accept_stream
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | Yes | C |
/*
* Create a new SSL object representing an additional stream which was created
* by the peer.
*
* There is no need to call SSL_accept on the resulting object, and
* any such call is a no-op.
*
* For QUIC:
* Must be called only on a QUIC connection SSL object. Fails if called on a
* stream object. Checks if a new stream has been created by the peer. If it
* has, creates a new SSL object to represent it and returns it. Otherwise,
* returns NULL. If multiple streams are available to be accepted, the oldest
* stream (that is, the stream with the lowest stream ID) is accepted.
*
* For all other methods:
* Returns NULL.
*
* The flags argument is unused and should be set to zero.
*
* To be MSMT-safe (i.e., can be called from multiple threads).
*
* If the QUIC connection SSL object is configured in blocking mode, this
* function will block unless the SSL_ACCEPT_STREAM_NO_BLOCK flag is passed.
*
* This function returns NULL if the effective incoming stream reject policy is
* `REJECT`.
*/
#define SSL_ACCEPT_STREAM_NO_BLOCK 1
SSL *SSL_accept_stream(SSL *ssl, uint64_t flags);
SSL_get_accept_stream_queue_len
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | C |
/*
* Determine the number of streams waiting to be returned on a subsequent call
* to SSL_accept_stream. If this returns a non-zero value, the next call to
* SSL_accept_stream (on any thread) is guaranteed to work. Returns 0 for
* non-QUIC objects, or for QUIC stream objects.
*
* To be MSMT-safe.
*/
size_t SSL_get_accept_stream_queue_len(SSL *ssl);
SSL_set_incoming_stream_policy
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | C |
/*
* Sets the policy for incoming streams. If `policy` is `AUTO` (the default):
*
* - if the default stream mode is
* `SSL_DEFAULT_STREAM_MODE_AUTO_BIDI` or
* `SSL_DEFAULT_STREAM_MODE_AUTO_UNI`, this is equivalent to `REJECT`;
*
* - otherwise, this is equivalent to `ACCEPT`.
*
* If configured to `ACCEPT`, incoming streams are placed on the accept queue
* for application consumption. `aec` is ignored in this case.
*
* If configured to `REJECT`, incoming streams automatically have both their
* receiving and sending parts handled via non-normal termination. `aec` is an
* application error code used for the `STOP_SENDING` and `RESET_STREAM` frames
* used for the purposes of this termination. The default AEC value used if this
* function is never called is 0.
*/
#define SSL_INCOMING_STREAM_POLICY_AUTO 0
#define SSL_INCOMING_STREAM_POLICY_ACCEPT 1
#define SSL_INCOMING_STREAM_POLICY_REJECT 2
int SSL_set_incoming_stream_policy(SSL *ssl, int policy, uint64_t aec);
SSL_set_default_stream_mode
Semantics | SSL_get_error |
Can Tick? | CSHL |
---|---|---|---|
New | Never | No | C |
/*
* Used to control single stream operation. Calling this function determines the
* nature of the default stream which will automatically be created on the QUIC
* connection SSL object.
*
* The default mode is `SSL_DEFAULT_STREAM_MODE_AUTO_BIDI`.
*
* The modes are as follows:
*
* - `SSL_DEFAULT_STREAM_MODE_NONE`: No default stream will ever be created.
* The application is assumed to understand multi-stream operation.
* Remotely-initiated streams are placed in the accept queue for application
* consumption. `SSL_read` and `SSL_write` calls must be made on a QUIC
* stream SSL object, not the QUIC connection SSL object, as no default
* stream will be associated with it.
*
* - `SSL_DEFAULT_STREAM_MODE_AUTO_BIDI`: "First stream wins" mode of
* operation for single-stream usage. If `SSL_write` is called before the
* peer opens a remotely-initiated stream, a locally-initiated bidirectional
* stream is created and bound as the default stream. If the peer opens a
* remotely-initiated stream before the local application calls `SSL_write`
* (with `len > 0`) for the first time, that stream is bound as the default
* stream, which may be bidirectional or unidirectional; if it is
* unidirectional, calls to `SSL_write` will fail. Attempts to create
* additional streams by the peer are automatically rejected unless
* the application opts in (API TBD).
*
* - `SSL_DEFAULT_STREAM_MODE_AUTO_UNI`: "First stream wins" mode of
* operation for single-stream usage, with a unidirectional stream. This
* functions identically to `SSL_DEFAULT_STREAM_MODE_AUTO_BIDI`, but if the
* local application calls `SSL_write` prior to the peer creating a
* remotely-initiated stream, a unidirectional TX-only stream is created and
* bound as the default stream. Thereafter, calls to `SSL_read` will fail.
* If the peer creates a remotely-initiated stream prior to the first call
* to `SSL_write` (with `len > 0`), that stream will be bound as the default
* stream; note that a bidirectional stream may be bound in this case.
* Attempts to create additional streams by the peer are automatically
* rejected unless the application opts in (API TBD).
*
* This function must be called before a default stream object is created, for
* example before initiating a connection. If the function is too late to have
* an effect, this function fails and returns 0.
*/
#define SSL_DEFAULT_STREAM_MODE_NONE 0
#define SSL_DEFAULT_STREAM_MODE_AUTO_BIDI 1
#define SSL_DEFAULT_STREAM_MODE_AUTO_UNI 2
__owur int SSL_set_default_stream_mode(SSL *ssl, uint32_t mode);
A custom poller interface may be provided in the future. For more information, see the QUIC I/O Architecture design document.
BIO_s_connect
, BIO_new_ssl_connect
, BIO_set_conn_hostname
We are aiming to support use of the existing BIO_new_ssl_connect
API with only
minimal changes. This will require internal changes to BIO_s_connect
, which
should automatically detect when it is being used with a QUIC SSL_CTX
and act
accordingly.
BIO_new_bio_pair
Unsuitable for use with QUIC on the network side; instead, applications can
make use of the new BIO_s_dgram_pair
which provides equivalent functionality
with datagram semantics.
BIO_f_buffer
Existing applications sometimes combine a network socket BIO with a
BIO_f_buffer
. This is problematic because the datagram semantics of writes are
not preserved, therefore the BIO provided to libssl is, as provided, unusable
for the purposes of implementing QUIC. Moreover, output buffering is not a
relevant or desirable performance optimisation for the transmission of UDP
datagrams and will actually undermine QUIC performance by causing incorrect
calculation of ACK delays and consequently inaccurate RTT calculation.
Options:
BIO_f_buffer
.BIO_f_buffer
is part of a BIO stack and bypass it
(yucky and surprising).See also: BIO_s_dgram_pair(3)
BIO_dgram_get_mtu
(BIO_CTRL_DGRAM_GET_MTU
) and BIO_dgram_set_mtu
(BIO_CTRL_DGRAM_SET_MTU
) already exist for BIO_s_dgram
and are implemented
on a BIO_s_dgram_pair
to allow the MTU to be determined and configured. One
side of a pair can configure the MTU to allow the other side to detect it.
BIO_s_dgram
also has pre-existing support for getting the correct MTU value
from the OS using BIO_CTRL_DGRAM_QUERY_MTU
.
BIO_sendmmsg
and BIO_recvmmsg
See also: BIO_sendmmsg(3)
The BIO interface features a new high-performance API for the execution of multiple read or write operations in a single system call, on supported OSes. On other OSes, a compatible fallback implementation is used.
Unlike all other BIO APIs, this API is intended for concurrent threaded use and as such operates in a stateless fashion with regards to a BIO. This means, for example, that retry indications are made using explicit API inputs and outputs rather than setting an internal flag on the BIO.
This new BIO API includes:
The following functionality was intentionally left out of this design because not all OSes can provide support:
MSG_DONTWAIT
, etc.This BIO API is intended to be extensible. For more information on this API, see BIO_sendmmsg(3) and BIO_recvmmsg(3).
Custom BIO implementers may set their own implementation of these APIs via
corresponding BIO_meth
getter/setter functions.
See also: BIO_s_dgram_pair(3)
The controls BIO_dgram_set_no_trunc
(BIO_CTRL_DGRAM_SET_NO_TRUNC
) and
BIO_dgram_get_no_trunc
(BIO_CTRL_DGRAM_GET_NO_TRUNC
) are introduced. This is
a boolean value which may be implemented by BIOs with datagram semantics. When
enabled, attempting to receive a datagram such that the datagram would
ordinarily be truncated (as per the design of the Berkeley sockets API) instead
results in a failure. This is intended for implementation by BIO_s_dgram_pair
.
For compatibility, the default behaviour is off.
See also: BIO_s_dgram_pair(3)
Where a BIO_s_dgram_pair
is used, there is the potential for such a memory BIO
to be used by existing application code which is being adapted for use with
QUIC. A problem arises whereby one end of a BIO_s_dgram_pair
(for example, the
side being used by OpenSSL's QUIC implementation) may assume that the other end
supports certain capabilities (for example, specifying a peer address), when in
actual fact the opposite end of the BIO_s_dgram_pair
does not.
A capability signalling mechanism is introduced which allows one end of a
BIO_s_dgram_pair
to indicate to the user of the opposite BIO the following
capabilities and related information:
The usage is as follows:
BIO_dgram_set_caps
with zero or
more of the following flags to advertise its capabilities:
BIO_DGRAM_CAP_HANDLES_SRC_ADDR
BIO_DGRAM_CAP_HANDLES_DST_ADDR
BIO_DGRAM_CAP_PROVIDES_SRC_ADDR
BIO_DGRAM_CAP_PROVIDES_DST_ADDR
BIO_dgram_get_effective_caps
to learn the effective capabilities of the BIO. These are the capabilities set
by the opposite BIO.See also: BIO_s_dgram_pair(3)
Support for local addressing (the reception of destination addresses for incoming packets, and the specification of source addresses for outgoing packets) varies by OS. Thus, it may not be available in all circumstances. A feature negotiation mechanism is introduced to facilitate this.
BIO_dgram_get_local_addr_cap
(BIO_CTRL_DGRAM_GET_LOCAL_ADDR_CAP
) determines
if a BIO is potentially capable of supporting local addressing on the current
platform. If it determines that support is available, local addressing support
must then be explicitly enabled via BIO_dgram_set_local_addr_enable
(BIO_CTRL_DGRAM_SET_LOCAL_ADDR_ENABLE
). If local addressing support has not
been enabled, attempts to use local addressing (for example via BIO_sendmmsg
or BIO_recvmmsg
with a BIO_MSG
with a non-NULL local
field) fails.
An explicit enablement call is required because setting up local addressing
support requires system calls on most operating systems prior to sending or
receiving packets and we do not wish to do this automatically inside the
BIO_sendmmsg
/BIO_recvmmsg
fastpaths, particularly since the process of
enabling support could fail due to lack of OS support, etc.
BIO_dgram_get_local_addr_enable
(BIO_CTRL_DGRAM_GET_LOCAL_ADDR_ENABLE
) is
also available.
It is important to note that BIO_dgram_get_local_addr_cap
is entirely distinct
from the application capability negotiation mechanism discussed above. Whereas
the capability negotiation mechanism discussed above allows applications to
signal what they are capable of handling in their usage of a given BIO,
BIO_dgram_local_addr_cap
allows a BIO implementation to indicate to the
users of that BIO whether it is able to support local addressing (where
enabled).
BIO_s_dgram_pair
See also: BIO_s_dgram_pair(3)
A new BIO implementation, BIO_s_dgram_pair
, is provided. This is similar to
the existing BIO pair but provides datagram semantics. It provides full support
for the new APIs BIO_sendmmsg
, BIO_recvmmsg
, the capability negotiation
mechanism described above, local address support and the MTU signalling
mechanism described above.
It can be instantiated using the new API BIO_new_dgram_pair
.
BIO_POLL_DESCRIPTOR
The concept of poll descriptors are introduced. A poll descriptor is a tagged union structure which represents an abstraction over some unspecified kind of OS descriptor which can be used for synchronization and waiting.
The most commonly used kind of poll descriptor is one which describes a network socket (i.e., on POSIX-like platforms, a file descriptor), however other kinds of poll descriptor may be defined.
A BIO may be queried for whether it has a poll descriptor for read or write operations respectively:
BIO_get_rpoll_descriptor
(BIO_CTRL_GET_RPOLL_DESCRIPTOR
) is called,
the BIO should output a poll descriptor which describes a resource which can
be used to determine when the BIO will next become readable via a call to
BIO_read
or, if supported by the BIO, BIO_recvmmsg
.BIO_get_wpoll_descriptor
(BIO_CTRL_GET_WPOLL_DESCRIPTOR
) is called, the
BIO should output a poll descriptor which describes a resource which can be
used to determine when the BIO will next become writeable via a call to
BIO_write
or, if supported by the BIO, BIO_sendmmsg
.A BIO may not necessarily be able to provide a poll descriptor. For example,
memory-based BIOs such as BIO_s_dgram_pair
do not correspond to any OS
synchronisation resource, and thus the BIO_get_rpoll_descriptor
and
BIO_get_wpoll_descriptor
calls are not supported for such BIOs.
A BIO which supports these functions is known as pollable, and a BIO which does
not is known as non-pollable. BIO_s_dgram
supports these functions.
The implementation of these functions for a BIO_f_ssl
forwards to
SSL_get_rpoll_descriptor
and SSL_get_wpoll_descriptor
respectively. The
BIO_s_dgram_mem
This is a basic memory buffer BIO with datagram semantics. Unlike
BIO_s_dgram_pair
, it is unidirectional and does not support peer addressing or
local addressing.
BIO_err_is_non_fatal
A new predicate function BIO_err_is_non_fatal
is defined which determines if
an error code represents a non-fatal or transient error. For details, see
BIO_sendmmsg(3).
To assist in understanding, when a “TBD” listed above is removed, or when a relevant question is raised, the resolution to the question will be placed here.
Q. Should SSL_do_handshake
wait until the handshake is completed, or until it
is confirmed?
A. SSL_do_handshake
should wait until the handshake is completed, because
handshake completion represents the completion of the cryptographic
authentication of the connection. When a connection's handshake is completed,
TLS 1.3 Finished messages have been exchanged by both parties, even if the
handshake has not yet been confirmed. Moreover, RFC 9001 s. 4.1.2 states:
Additionally, a client MAY consider the handshake to be confirmed when it receives an acknowledgment for a 1-RTT packet.
This logically implies that it is OK for a client to start transmitting 1-RTT packets prior to handshake confirmation, otherwise there would be no in-flight 1-RTT packets for the client to receive ACKs for.
Q. Does ENABLE_PARTIAL_WRITE
interact with blocking mode?
A. No; this mode is only relevant to non-blocking mode. In blocking mode,
SSL_write
always waits until all data is written unless an error occurs. The
semantics of SSL_write
are preserved unchanged.
Q. Does SSL_write
block until data is written to the network, or simply
until it is buffered?
A. SSL_write
blocks until it has accepted responsibility for the data passed
to it, just like write(2)
or send(2)
. In other words, it blocks until it can
buffer the data. This does not necessarily mean that the data has actually been
sent.
Q. How should connection closure work?
A. RFC requirements. After we begin terminating the connection by sending a
CONNECTION_CLOSE
frame, QUIC requires that we continue to process network I/O
for a certain period of time so that any further traffic from the peer results
in generation of a further CONNECTION_CLOSE
frame. This is necessary to handle
the possibility that the CONNECTION_CLOSE
frame which was initially sent may
be lost.
API issues. This creates a complication because it implies that the
connection closure process may take a fair amount of time, whereas existing API
users will generally expect to be able to call SSL_shutdown
and then
immediately free the SSL object.
However, if the caller immediately frees the SSL object, this precludes
our implementing the applicable logic, at least on the client side. Moreover,
existing API users are likely to tear down underlying network BIOs immediately
after calling SSL_free
anyway. In other words, any implementation based on
secretly keeping QUIC state around after a call to SSL_free
does not seem
particularly workable on the client side.
Server side considerations. There is more of a prospect here on the server side, since multiple connections will share the same socket, which will presumably be associated with some kind of enduring listener object. Thus when server support is implemented in the future connection teardown could be handled internally by maintaining the state of connections undergoing termination inside the listener object. However, similar caveats to those discussed here arise when the listener object itself is to be town down. (It is also possible we could optionally allow use of the server-style API to make multiple outgoing client connections with a non-zero-length client-side CID on the same underlying network BIO.)
There are only really two ways to handle this:
SSL_shutdown
only indicates that shutdown is
complete once the entire connection closure process is complete.This process consists of the Closing and Draining states. In some cases the
Closing state may last only briefly, namely if the peer chooses to respond to
our CONNECTION_CLOSE
frame with a CONNECTION_CLOSE
frame of its own. This
allows immediate progression to the Draining state. However, a peer is not
required to respond with such a frame. Thus in the worst case, this state can
be as long as 3*PTO
; for example a peer with a high estimated RTT of 300ms
would have us wait for 900ms.
In the Draining state we simply ignore all incoming traffic and do not generate outgoing traffic. The purpose of this state is to simply tie up the socket and ensure any data still in flight is discarded. However, RFC 9000 states:
Disposing of connection state prior to exiting the closing or draining state
could result in an endpoint generating a Stateless Reset unnecessarily when
it receives a late-arriving packet. Endpoints that have some alternative
means to ensure that late-arriving packets do not induce a response, such as
those that are able to close the UDP socket, MAY end these states earlier to
allow for faster resource recovery. Servers that retain an open socket for
accepting new connections SHOULD NOT end the closing or draining state early
Because our client mode implementation uses one socket per connection, it appears to be reasonable based on the above text to omit the implementation of the draining state (the same may not be the case for the server role when implemented in the future).
Thus, in general, SSL_shutdown
can be expected to take about one round
trip's time to complete when dealing with a peer whose QUIC implementation
happens to respond to a CONNECTION_CLOSE
frame with a CONNECTION_CLOSE
frame of its own, and about three round trips otherwise.
SSL_shutdown
sends a CONNECTION_CLOSE
frame once
and completes immediately. The Closing and Draining states are not used, and
if the CONNECTION_CLOSE
frame was lost, the peer will have to wait for idle
timeout to determine that the connection is gone (there is also the
possibility that, if the socket is closed by the application after teardown, a
peer will make something of ICMP Port Unreachable messages, but this is
unlikely to be reliable and since this message is not authenticated, QUIC
implementations probably shouldn't pay much attention to it anyway.)There is little problem with SSL_shutdown
taking as long as it needs to for
some long-running applications, but for others it poses a real issue. For
example, a command-line tool which makes one connection, performs one
application-specific transaction, and then tears down the connection. In this
case an RFC-conformant connection termination would essentially require the
process to hang around for a substantial amount of time after the work of the
process is done.
For this reason, it is concluded that both of these shutdown modes need to be offered.
Where connection closure is initiated remotely rather than locally, only the draining state is relevant. Since we conclude above that we do not need to implement the draining state on the client side, this means that connection closure can be completed immediately in the case of a remote closure.
Q. Should we just map SSL_handle_events
to DTLS_CTRL_HANDLE_TIMEOUT
internally?
A. No, since the infinite time representation is different between the two calls.
Q. How should STOP_SENDING
be supported?
We trigger STOP_SENDING
automatically if an application frees the associated
QUIC stream SSL object.
Q. Can data be received on a locally initiated bidirectional stream before any data is sent on that stream?
This is an interesting question without a clear answer to be found in the QUIC RFCs. A close reading of RFC 9000 suggests that the answer is, in principle, yes; however the RFC also grants explicit permission to make design choices in implementations which would preclude this:
An implementation might choose to defer allocating a stream ID to a stream until it sends the first STREAM frame and enters this state, which can allow for better stream prioritization.
If an ID has not been allocated to a stream, obviously incoming data cannot be addressed to it. However, supposing that an implementation does not do this, RFC 9000 seems basically clear that it is valid for an application to create a stream locally, then receive data on it before sending anything:
The sending part of a stream that the endpoint initiates (types 0 and 2 for clients, 1 and 3 for servers) is opened by the application. The "Ready" state represents a newly created stream that is able to accept data from the application.
[...]
For a bidirectional stream, the receiving part enters the "Recv" state when the sending part initiated by the endpoint (type 0 for a client, type 1 for a server) enters the "Ready" state.
A peer is not generally notified of the creation of a stream which has not sent
any data yet, since the creation of a stream is signalled only implicitly via
the transmission of data in STREAM
frames. However, a zero-length STREAM frame
could presumably be used to effect such a notification. RFC 9000 contains no
specific discussion of this possibility but does not preclude it. As such, in
order to receive data on a locally-initiated bidirectional stream before sending
any data on that stream, it would be necessary to either
Use a QUIC implementation which signals a bidirectional stream which has not yet sent any data via a zero-length stream frame, or
Use an application protocol which can inform the peer of the stream ID of the created stream in some application protocol-specific way. This is somewhat less plausible because it would require an API between the application and its QUIC library to inform the QUIC library that the peer has in fact created a stream with a given ID and to take its word for it. This is unlikely to be commonly available, especially as application errors in usage of such an API would lead to internal inconsistencies in QUIC connection state.
Of course this discussion is somewhat esoteric as it is unclear why an application would want to create a locally-initiated stream and then have the peer transmit on it first, rather than simply use a remotely-initiated stream. Thus this discussion of this edge case is more of a curiosity, however for completeness it needs to be thought about in the API design.
Q. How should single-stream operation support locally and remotely-initiated streams?
Note that the ID of a stream depends on whether it is bidirectional and whether it is initiated by the client or server. Therefore, in single stream operation, it is necessary to know whether single-stream QUIC is being used with client-initiated or server-initiated stream initiation, and whether a bidirectional or unidirectional stream is being used; otherwise, we do not know which stream ID to bind to.
The object of single stream operation is to support simple uses cases for simple applications. There seems no need to support esoteric usage of streams such as receiving first on a locally initiated stream here, thus we avoid supporting this to simplify the API.
As such, an application which calls SSL_write
on a QUIC connection SSL object
before it calls SSL_read
by definition is using a locally-initiated stream,
and an application which does the opposite is using a remotely-initiated stream.
We can use the ordering of initial calls to SSL_read
and SSL_write
to infer
the desired stream type.
Supporting locally-initiated streams (SSL_write
called first) is simple;
we automatically create the stream and queue data for transmission.
Supporting remotely-initiated streams (SSL_read
called first) is a little
stranger. We could create the stream with the correct ID when cued to by the
initial call to SSL_read
implying use of a remotely-initiated stream. However,
this would mean we are creating state tracking a remotely-initiated stream
before the peer has signalled it. This would work in the happy case where the
client is connected to a compatible server but may result in strange
inconsistencies of QUIC internal state if a client is accidentally connected to
an incompatible peer. Since the peer ought to be the authority on the streams it
creates, this seems like an undesirable approach.
Ergo, creation of a default remotely-initiated stream needs to be deferred until the peer signals such a stream.
This leads naturally to a "first stream wins" model of implementation:
When a QUIC connection SSL object is created, default stream mode is enabled, meaning that a default stream will be bound to the QUIC connection SSL object at the earliest available opportunity. However, no default stream is bound yet.
One of the following events happened — whichever happens first wins:
The local application calls SSL_write()
(len > 0
). A locally-initiated
stream with ordinal 0 is created. The stream is bidirectional by default but
this can be changed. This stream is bound as the default stream.
The peer creates a stream. This stream is bound as the default stream.
If the local application calls SSL_read()
before either of the above
occur, SSL_read()
fails as though no data is available until one
of the above events occurs.
Once one of the above events occurs, any additional stream created by the peer
is automatically terminated using both STOP_SENDING
and STREAM_RESET
frames
(to terminate both the receiving and sending parts respectively) and there is no
API-visible effect to the local application (unless the application explicitly
opts into supporting additional streams).