xref: /freebsd/share/man/man9/mod_cc.9 (revision 1f4bcc459a76b7aa664f3fd557684cd0ba6da352)
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2.\" Copyright (c) 2008-2009 Lawrence Stewart <lstewart@FreeBSD.org>
3.\" Copyright (c) 2010-2011 The FreeBSD Foundation
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32.\" $FreeBSD$
33.\"
34.Dd January 21, 2016
35.Dt MOD_CC 9
36.Os
37.Sh NAME
38.Nm mod_cc ,
39.Nm DECLARE_CC_MODULE ,
40.Nm CCV
41.Nd Modular Congestion Control
42.Sh SYNOPSIS
43.In netinet/tcp.h
44.In netinet/cc/cc.h
45.In netinet/cc/cc_module.h
46.Fn DECLARE_CC_MODULE "ccname" "ccalgo"
47.Fn CCV "ccv" "what"
48.Sh DESCRIPTION
49The
50.Nm
51framework allows congestion control algorithms to be implemented as dynamically
52loadable kernel modules via the
53.Xr kld 4
54facility.
55Transport protocols can select from the list of available algorithms on a
56connection-by-connection basis, or use the system default (see
57.Xr mod_cc 4
58for more details).
59.Pp
60.Nm
61modules are identified by an
62.Xr ascii 7
63name and set of hook functions encapsulated in a
64.Vt "struct cc_algo" ,
65which has the following members:
66.Bd -literal -offset indent
67struct cc_algo {
68	char	name[TCP_CA_NAME_MAX];
69	int	(*mod_init) (void);
70	int	(*mod_destroy) (void);
71	int	(*cb_init) (struct cc_var *ccv);
72	void	(*cb_destroy) (struct cc_var *ccv);
73	void	(*conn_init) (struct cc_var *ccv);
74	void	(*ack_received) (struct cc_var *ccv, uint16_t type);
75	void	(*cong_signal) (struct cc_var *ccv, uint32_t type);
76	void	(*post_recovery) (struct cc_var *ccv);
77	void	(*after_idle) (struct cc_var *ccv);
78	int	(*ctl_output)(struct cc_var *, struct sockopt *, void *);
79};
80.Ed
81.Pp
82The
83.Va name
84field identifies the unique name of the algorithm, and should be no longer than
85TCP_CA_NAME_MAX-1 characters in length (the TCP_CA_NAME_MAX define lives in
86.In netinet/tcp.h
87for compatibility reasons).
88.Pp
89The
90.Va mod_init
91function is called when a new module is loaded into the system but before the
92registration process is complete.
93It should be implemented if a module needs to set up some global state prior to
94being available for use by new connections.
95Returning a non-zero value from
96.Va mod_init
97will cause the loading of the module to fail.
98.Pp
99The
100.Va mod_destroy
101function is called prior to unloading an existing module from the kernel.
102It should be implemented if a module needs to clean up any global state before
103being removed from the kernel.
104The return value is currently ignored.
105.Pp
106The
107.Va cb_init
108function is called when a TCP control block
109.Vt struct tcpcb
110is created.
111It should be implemented if a module needs to allocate memory for storing
112private per-connection state.
113Returning a non-zero value from
114.Va cb_init
115will cause the connection set up to be aborted, terminating the connection as a
116result.
117.Pp
118The
119.Va cb_destroy
120function is called when a TCP control block
121.Vt struct tcpcb
122is destroyed.
123It should be implemented if a module needs to free memory allocated in
124.Va cb_init .
125.Pp
126The
127.Va conn_init
128function is called when a new connection has been established and variables are
129being initialised.
130It should be implemented to initialise congestion control algorithm variables
131for the newly established connection.
132.Pp
133The
134.Va ack_received
135function is called when a TCP acknowledgement (ACK) packet is received.
136Modules use the
137.Fa type
138argument as an input to their congestion management algorithms.
139The ACK types currently reported by the stack are CC_ACK and CC_DUPACK.
140CC_ACK indicates the received ACK acknowledges previously unacknowledged data.
141CC_DUPACK indicates the received ACK acknowledges data we have already received
142an ACK for.
143.Pp
144The
145.Va cong_signal
146function is called when a congestion event is detected by the TCP stack.
147Modules use the
148.Fa type
149argument as an input to their congestion management algorithms.
150The congestion event types currently reported by the stack are CC_ECN, CC_RTO,
151CC_RTO_ERR and CC_NDUPACK.
152CC_ECN is reported when the TCP stack receives an explicit congestion notification
153(RFC3168).
154CC_RTO is reported when the retransmission time out timer fires.
155CC_RTO_ERR is reported if the retransmission time out timer fired in error.
156CC_NDUPACK is reported if N duplicate ACKs have been received back-to-back,
157where N is the fast retransmit duplicate ack threshold (N=3 currently as per
158RFC5681).
159.Pp
160The
161.Va post_recovery
162function is called after the TCP connection has recovered from a congestion event.
163It should be implemented to adjust state as required.
164.Pp
165The
166.Va after_idle
167function is called when data transfer resumes after an idle period.
168It should be implemented to adjust state as required.
169.Pp
170The
171.Va ctl_output
172function is called when
173.Xr getsockopt 2
174or
175.Xr setsockopt 2
176is called on a
177.Xr tcp 4
178socket with the
179.Va struct sockopt
180pointer forwarded unmodified from the TCP control, and a
181.Va void *
182pointer to algorithm specific argument.
183.Pp
184The
185.Fn DECLARE_CC_MODULE
186macro provides a convenient wrapper around the
187.Xr DECLARE_MODULE 9
188macro, and is used to register a
189.Nm
190module with the
191.Nm
192framework.
193The
194.Fa ccname
195argument specifies the module's name.
196The
197.Fa ccalgo
198argument points to the module's
199.Vt struct cc_algo .
200.Pp
201.Nm
202modules must instantiate a
203.Vt struct cc_algo ,
204but are only required to set the name field, and optionally any of the function
205pointers.
206The stack will skip calling any function pointer which is NULL, so there is no
207requirement to implement any of the function pointers.
208Using the C99 designated initialiser feature to set fields is encouraged.
209.Pp
210Each function pointer which deals with congestion control state is passed a
211pointer to a
212.Vt struct cc_var ,
213which has the following members:
214.Bd -literal -offset indent
215struct cc_var {
216	void		*cc_data;
217	int		bytes_this_ack;
218	tcp_seq		curack;
219	uint32_t	flags;
220	int		type;
221	union ccv_container {
222		struct tcpcb		*tcp;
223		struct sctp_nets	*sctp;
224	} ccvc;
225};
226.Ed
227.Pp
228.Vt struct cc_var
229groups congestion control related variables into a single, embeddable structure
230and adds a layer of indirection to accessing transport protocol control blocks.
231The eventual goal is to allow a single set of
232.Nm
233modules to be shared between all congestion aware transport protocols, though
234currently only
235.Xr tcp 4
236is supported.
237.Pp
238To aid the eventual transition towards this goal, direct use of variables from
239the transport protocol's data structures is strongly discouraged.
240However, it is inevitable at the current time to require access to some of these
241variables, and so the
242.Fn CCV
243macro exists as a convenience accessor.
244The
245.Fa ccv
246argument points to the
247.Vt struct cc_var
248passed into the function by the
249.Nm
250framework.
251The
252.Fa what
253argument specifies the name of the variable to access.
254.Pp
255Apart from the
256.Va type
257and
258.Va ccv_container
259fields, the remaining fields in
260.Vt struct cc_var
261are for use by
262.Nm
263modules.
264.Pp
265The
266.Va cc_data
267field is available for algorithms requiring additional per-connection state to
268attach a dynamic memory pointer to.
269The memory should be allocated and attached in the module's
270.Va cb_init
271hook function.
272.Pp
273The
274.Va bytes_this_ack
275field specifies the number of new bytes acknowledged by the most recently
276received ACK packet.
277It is only valid in the
278.Va ack_received
279hook function.
280.Pp
281The
282.Va curack
283field specifies the sequence number of the most recently received ACK packet.
284It is only valid in the
285.Va ack_received ,
286.Va cong_signal
287and
288.Va post_recovery
289hook functions.
290.Pp
291The
292.Va flags
293field is used to pass useful information from the stack to a
294.Nm
295module.
296The CCF_ABC_SENTAWND flag is relevant in
297.Va ack_received
298and is set when appropriate byte counting (RFC3465) has counted a window's worth
299of bytes has been sent.
300It is the module's responsibility to clear the flag after it has processed the
301signal.
302The CCF_CWND_LIMITED flag is relevant in
303.Va ack_received
304and is set when the connection's ability to send data is currently constrained
305by the value of the congestion window.
306Algorithms should use the absence of this flag being set to avoid accumulating
307a large difference between the congestion window and send window.
308.Sh SEE ALSO
309.Xr cc_cdg 4 ,
310.Xr cc_chd 4 ,
311.Xr cc_cubic 4 ,
312.Xr cc_hd 4 ,
313.Xr cc_htcp 4 ,
314.Xr cc_newreno 4 ,
315.Xr cc_vegas 4 ,
316.Xr mod_cc 4 ,
317.Xr tcp 4
318.Sh ACKNOWLEDGEMENTS
319Development and testing of this software were made possible in part by grants
320from the FreeBSD Foundation and Cisco University Research Program Fund at
321Community Foundation Silicon Valley.
322.Sh FUTURE WORK
323Integrate with
324.Xr sctp 4 .
325.Sh HISTORY
326The modular Congestion Control (CC) framework first appeared in
327.Fx 9.0 .
328.Pp
329The framework was first released in 2007 by James Healy and Lawrence Stewart
330whilst working on the NewTCP research project at Swinburne University of
331Technology's Centre for Advanced Internet Architectures, Melbourne, Australia,
332which was made possible in part by a grant from the Cisco University Research
333Program Fund at Community Foundation Silicon Valley.
334More details are available at:
335.Pp
336http://caia.swin.edu.au/urp/newtcp/
337.Sh AUTHORS
338.An -nosplit
339The
340.Nm
341framework was written by
342.An Lawrence Stewart Aq Mt lstewart@FreeBSD.org ,
343.An James Healy Aq Mt jimmy@deefa.com
344and
345.An David Hayes Aq Mt david.hayes@ieee.org .
346.Pp
347This manual page was written by
348.An David Hayes Aq Mt david.hayes@ieee.org
349and
350.An Lawrence Stewart Aq Mt lstewart@FreeBSD.org .
351