litespeed-quic/APIs.txt

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# Copyright (c) 2017 - 2019 LiteSpeed Technologies Inc. See LICENSE.
LSQUIC APIs
===========
LSQUIC exposes the following object types to the user:
- Engine Settings (struct lsquic_engine_settings)
- Stream Interface (struct lsquic_stream_if)
- Engine API (struct lsquic_engine_api)
- Engine
- Connection
- Stream
The first three -- engine settings, engine APIs, and stream interface --
are used to instantiate the engine. After engine is instantiated, the
user code need only concern itself with engine, connections, and streams.
Engine Settings
---------------
Engine settings is the struct lsquic_engine_settings. It contains various
QUIC settings and LSQUIC parameters. The usual way to use it is to initialize
it to default values using lsquic_engine_init_settings(), modify any values
if necessary, and pass it as parameter to lsquic_engine_new().
QUIC settings are specified by the following members:
lsquic_engine_settings QUIC
member parameter
---------------------- ---------
es_cfcw CFCW
es_sfcw SFCW
es_max_streams_in MIDS
es_ua UAID
es_versions VER
es_idle_conn_to ICSL
es_silent_close SCLS
es_support_srej COPT/SREJ
es_support_nstp COPT/NSTP
es_support_tcid0 TCID
The following parameters affect run-time behavior:
es_rw_once Important: affects event dispatch
es_handshake_to
es_support_push
es_pace_packets
Other noteworthy settings:
es_max_header_list_size
es_progress_check
To be sure your settings are good (in other words, passing this struct won't
trip up the engine constructor), use lsquic_engine_check_settings().
Stream Interface
----------------
The stream interface, lsquic_stream_if, specifies callbacks LSQUIC engine
will call for connections and streams.
The following callbacks should be specified for connection:
on_new_conn This is called when connection is created.
on_goaway_received This function is called when we receive GOAWAY
frame from peer. This callback is optional.
on_conn_closed Connection is closed: all streams have been
destroyed.
The streams have four callbacks:
on_new_stream Stream has been created.
on_read Stream can be read from (see Events).
on_write Stream can be written to (see Events).
on_close Stream has been closed.
For both connections and streams, the "on new" callback return value can
be use to specify user-supplied data. This data pointer is optional and
can be NULL. It can also refer to the same data for the connection and
its streams. "on close" callbacks should be used to free user-supplied
data.
Engine API
----------
The engine API, struct lsquic_engine_api, is a combination structure to
make calling lsquic_engine_new() manageable. It holds references to
struct lsquic_engine_settings and struct lsquic_stream_if, as well as:
- Interface for sending outgoing packets, ea_packets_out
- Interface for allocating memory for outgoing packet buffers
(optional).
- Interface for share memory hash, ea_shi
- Optional interface for reporting connections whose handshake
did not complete (ea_bad_handshake)
ea_packets_out is a pointer to a function of type lsquic_packets_out_f.
The engine calls this function when it is appropriate to send out packets
for one or more connections, which it gives to the function in a batch.
This batch is an array of struct lsquic_out_spec.
Engine
------
The engine is instantiated using lsquic_engine_new(). The first parameter
is a list flags and the second parameter is the reference to the engine
api. The engine settings are specified, they are copied; changing
the setting after the engine has been created will not affect engine's
behavior. If the settings are not specified, the engine will use default
settings created by lsquic_engine_init_settings().
Once the engine is instantiated, there are four main ways to use it to
drive QUIC connections:
1. Create a connection using lsquic_engine_connect().
2. Feed it incoming packets using lsquic_engine_packet_in() function.
3. Process connections using one of the connection queue functions
(see Connection Queues).
4. Accept outgoing packets for sending (and send them!) using
ea_packets_out callback.
[API Change, OPTIMIZATION] Only process conns that need to be processed The API is simplified: do not expose the user code to several queues. A "connection queue" is now an internal concept. The user processes connections using the single function lsquic_engine_process_conns(). When this function is called, only those connections are processed that need to be processed. A connection needs to be processed when: 1. New incoming packets have been fed to the connection. 2. User wants to read from a stream that is readable. 3. User wants to write to a stream that is writeable. 4. There are buffered packets that can be sent out. (This means that the user wrote to a stream outside of the lsquic library callback.) 5. A control frame (such as BLOCKED) needs to be sent out. 6. A stream needs to be serviced or delayed stream needs to be created. 7. An alarm rings. 8. Pacer timer expires. To achieve this, the library places the connections into two priority queues (min heaps): 1. Tickable Queue; and 2. Advisory Tick Time queue (ATTQ). Each time lsquic_engine_process_conns() is called, the Tickable Queue is emptied. After the connections have been ticked, they are queried again: if a connection is not being closed, it is placed either in the Tickable Queue if it is ready to be ticked again or it is placed in the Advisory Tick Time Queue. It is assumed that a connection always has at least one timer set (the idle alarm). The connections in the Tickable Queue are arranged in the least recently ticked order. This lets connections that have been quiet longer to get their packets scheduled first. This change means that the library no longer needs to be ticked periodically. The user code can query the library when is the next tick event and schedule it exactly. When connections are processed, only the tickable connections are processed, not *all* the connections. When there are no tick events, it means that no timer event is necessary -- only the file descriptor READ event is active. The following are improvements and simplifications that have been triggered: - Queue of connections with incoming packets is gone. - "Pending Read/Write Events" Queue is gone (along with its history and progress checks). This queue has become the Tickable Queue. - The connection hash no longer needs to track the connection insertion order.
2018-04-09 13:39:38 +00:00
Connection Management
---------------------
[API Change, OPTIMIZATION] Only process conns that need to be processed The API is simplified: do not expose the user code to several queues. A "connection queue" is now an internal concept. The user processes connections using the single function lsquic_engine_process_conns(). When this function is called, only those connections are processed that need to be processed. A connection needs to be processed when: 1. New incoming packets have been fed to the connection. 2. User wants to read from a stream that is readable. 3. User wants to write to a stream that is writeable. 4. There are buffered packets that can be sent out. (This means that the user wrote to a stream outside of the lsquic library callback.) 5. A control frame (such as BLOCKED) needs to be sent out. 6. A stream needs to be serviced or delayed stream needs to be created. 7. An alarm rings. 8. Pacer timer expires. To achieve this, the library places the connections into two priority queues (min heaps): 1. Tickable Queue; and 2. Advisory Tick Time queue (ATTQ). Each time lsquic_engine_process_conns() is called, the Tickable Queue is emptied. After the connections have been ticked, they are queried again: if a connection is not being closed, it is placed either in the Tickable Queue if it is ready to be ticked again or it is placed in the Advisory Tick Time Queue. It is assumed that a connection always has at least one timer set (the idle alarm). The connections in the Tickable Queue are arranged in the least recently ticked order. This lets connections that have been quiet longer to get their packets scheduled first. This change means that the library no longer needs to be ticked periodically. The user code can query the library when is the next tick event and schedule it exactly. When connections are processed, only the tickable connections are processed, not *all* the connections. When there are no tick events, it means that no timer event is necessary -- only the file descriptor READ event is active. The following are improvements and simplifications that have been triggered: - Queue of connections with incoming packets is gone. - "Pending Read/Write Events" Queue is gone (along with its history and progress checks). This queue has become the Tickable Queue. - The connection hash no longer needs to track the connection insertion order.
2018-04-09 13:39:38 +00:00
A connections needs to be processed once in a while. It needs to be
processed when one of the following is true:
- There are incoming packets;
- A stream is both readable by the user code and the user code wants
to read from it;
- A stream is both writeable by the user code and the user code wants
to write to it;
- User has written to stream outside of on_write() callbacks (that is
allowed) and now there are packets ready to be sent;
- A timer (pacer, retransmission, idle, etc) has expired;
- A control frame needs to be sent out;
- A stream needs to be serviced or created.
Each of these use cases is handled by a single function:
lsquic_engine_process_conns()
The connections to which the conditions above apply are processed (or
"ticked") in the least recently ticked order. After calling this function,
you can see when is the next time a connection needs to be processed using
lsquic_engine_earliest_adv_tick()
Based on this value, next event can be scheduled (in the event loop of
your choice).
Connection
----------
A connection is created using lsquic_engine_connect(). When on_new_conn()
is called, the client code should call lsquic_conn_make_stream() one or
more times. One new stream will be created for each one of those calls.
Several auxiliary functions are available:
- lsquic_conn_id()
- lsquic_conn_going_away()
- lsquic_conn_get_peer_ctx()
- lsquic_conn_get_stream_by_id()
- lsquic_conn_get_ctx()
Stream
------
LSQUIC stream hides QUIC and HTTP/2 framing complexities from the user.
What it presents is a way to send HTTP headers and, optionally, body to
peer. On read side, the user gets what looks like HTTP/1.1 stream.
Expected usage for client is to express the desire to write to stream
using lsquic_stream_wantwrite() call. Once on_write() is called:
1. Write headers using lsquic_stream_send_headers()
2. Optionally write payload body using of of lsquic_stream_write(),
lsquic_stream_writev(), or lsquic_stream_writef().
That done, shutdown write side using lsquic_stream_shutdown(), unregister
for write events and register for read events using lsquic_stream_wantread().
Read and parse HTTP/1.1 stream from on_read() callback until end-of-stream
or an error is encountered.
Then unregister the read event and shutdown the read side. The stream will
be closed after that at some point and on_close() callback will be called,
at which point resources can be freed. (Internally, the stream object is
not destroyed until either all the packets carrying its data are ACKed or
the connection is destroyed).
on_read() and on_write() callbacks are dispatched differently based on the
value of es_rw_once:
If es_rw_once is false, then the callbacks are dispatched in a loop until
the user unregisters the event or the stream becomes unreadable (or
unwriteable).
If es_rw_once is true, on_read() and on_write() are called once "per tick".
It is the up to the user to read and write enough data.
Events
------
Stream events are persistent: once call lsquic_stream_wantwrite() or
lsquic_stream_wantread(), the event stays active until turned off.
Note that when an error is encountered (such as a stream reset), the
stream becomes readable and writeable: this allows user code to collect
the error.
Versions
--------
QUIC version are listed in enum lsquic_version. To specify a list of
versions, they are usually placed in a bitmask, e.g. es_versions.