MOD_CC(9) | Kernel Developer's Manual | MOD_CC(9) |
mod_cc
,
DECLARE_CC_MODULE
, CCV
— Modular Congestion Control
#include
<netinet/tcp.h>
#include <netinet/cc/cc.h>
#include
<netinet/cc/cc_module.h>
DECLARE_CC_MODULE
(ccname,
ccalgo);
CCV
(ccv,
what);
The mod_cc
framework allows congestion
control algorithms to be implemented as dynamically loadable kernel modules
via the kld(4) facility. Transport protocols can select
from the list of available algorithms on a connection-by-connection basis,
or use the system default (see mod_cc(4) for more
details).
mod_cc
modules are identified by an
ascii(7) name and set of hook functions encapsulated in a
struct cc_algo, which has the following members:
struct cc_algo { char name[TCP_CA_NAME_MAX]; int (*mod_init) (void); int (*mod_destroy) (void); int (*cb_init) (struct cc_var *ccv); void (*cb_destroy) (struct cc_var *ccv); void (*conn_init) (struct cc_var *ccv); void (*ack_received) (struct cc_var *ccv, uint16_t type); void (*cong_signal) (struct cc_var *ccv, uint32_t type); void (*post_recovery) (struct cc_var *ccv); void (*after_idle) (struct cc_var *ccv); int (*ctl_output)(struct cc_var *, struct sockopt *, void *); };
The name field identifies the unique name of
the algorithm, and should be no longer than TCP_CA_NAME_MAX-1 characters in
length (the TCP_CA_NAME_MAX define lives in
<netinet/tcp.h>
for
compatibility reasons).
The mod_init function is called when a new module is loaded into the system but before the registration process is complete. It should be implemented if a module needs to set up some global state prior to being available for use by new connections. Returning a non-zero value from mod_init will cause the loading of the module to fail.
The mod_destroy function is called prior to unloading an existing module from the kernel. It should be implemented if a module needs to clean up any global state before being removed from the kernel. The return value is currently ignored.
The cb_init function is called when a TCP control block struct tcpcb is created. It should be implemented if a module needs to allocate memory for storing private per-connection state. Returning a non-zero value from cb_init will cause the connection set up to be aborted, terminating the connection as a result.
The cb_destroy function is called when a TCP control block struct tcpcb is destroyed. It should be implemented if a module needs to free memory allocated in cb_init.
The conn_init function is called when a new connection has been established and variables are being initialised. It should be implemented to initialise congestion control algorithm variables for the newly established connection.
The ack_received function is called when a TCP acknowledgement (ACK) packet is received. Modules use the type argument as an input to their congestion management algorithms. The ACK types currently reported by the stack are CC_ACK and CC_DUPACK. CC_ACK indicates the received ACK acknowledges previously unacknowledged data. CC_DUPACK indicates the received ACK acknowledges data we have already received an ACK for.
The cong_signal function is called when a congestion event is detected by the TCP stack. Modules use the type argument as an input to their congestion management algorithms. The congestion event types currently reported by the stack are CC_ECN, CC_RTO, CC_RTO_ERR and CC_NDUPACK. CC_ECN is reported when the TCP stack receives an explicit congestion notification (RFC3168). CC_RTO is reported when the retransmission time out timer fires. CC_RTO_ERR is reported if the retransmission time out timer fired in error. CC_NDUPACK is reported if N duplicate ACKs have been received back-to-back, where N is the fast retransmit duplicate ack threshold (N=3 currently as per RFC5681).
The post_recovery function is called after the TCP connection has recovered from a congestion event. It should be implemented to adjust state as required.
The after_idle function is called when data transfer resumes after an idle period. It should be implemented to adjust state as required.
The ctl_output function is called when getsockopt(2) or setsockopt(2) is called on a tcp(4) socket with the struct sockopt pointer forwarded unmodified from the TCP control, and a void * pointer to algorithm specific argument.
The
DECLARE_CC_MODULE
()
macro provides a convenient wrapper around the
DECLARE_MODULE(9) macro, and is used to register a
mod_cc
module with the
mod_cc
framework. The ccname
argument specifies the module's name. The ccalgo
argument points to the module's struct cc_algo.
mod_cc
modules must instantiate a
struct cc_algo, but are only required to set the name
field, and optionally any of the function pointers. The stack will skip
calling any function pointer which is NULL, so there is no requirement to
implement any of the function pointers. Using the C99 designated initialiser
feature to set fields is encouraged.
Each function pointer which deals with congestion control state is passed a pointer to a struct cc_var, which has the following members:
struct cc_var { void *cc_data; int bytes_this_ack; tcp_seq curack; uint32_t flags; int type; union ccv_container { struct tcpcb *tcp; struct sctp_nets *sctp; } ccvc; };
struct cc_var groups congestion control
related variables into a single, embeddable structure and adds a layer of
indirection to accessing transport protocol control blocks. The eventual
goal is to allow a single set of mod_cc
modules to
be shared between all congestion aware transport protocols, though currently
only tcp(4) is supported.
To aid the eventual transition towards this goal, direct
use of variables from the transport protocol's data structures is strongly
discouraged. However, it is inevitable at the current time to require access
to some of these variables, and so the
CCV
() macro
exists as a convenience accessor. The ccv argument
points to the struct cc_var passed into the function
by the mod_cc
framework. The
what argument specifies the name of the variable to
access.
Apart from the type and
ccv_container fields, the remaining fields in
struct cc_var are for use by
mod_cc
modules.
The cc_data field is available for algorithms requiring additional per-connection state to attach a dynamic memory pointer to. The memory should be allocated and attached in the module's cb_init hook function.
The bytes_this_ack field specifies the number of new bytes acknowledged by the most recently received ACK packet. It is only valid in the ack_received hook function.
The curack field specifies the sequence number of the most recently received ACK packet. It is only valid in the ack_received, cong_signal and post_recovery hook functions.
The flags field is used to pass useful
information from the stack to a mod_cc
module. The
CCF_ABC_SENTAWND flag is relevant in ack_received and
is set when appropriate byte counting (RFC3465) has counted a window's worth
of bytes has been sent. It is the module's responsibility to clear the flag
after it has processed the signal. The CCF_CWND_LIMITED flag is relevant in
ack_received and is set when the connection's ability
to send data is currently constrained by the value of the congestion window.
Algorithms should use the absence of this flag being set to avoid
accumulating a large difference between the congestion window and send
window.
cc_cdg(4), cc_chd(4), cc_cubic(4), cc_hd(4), cc_htcp(4), cc_newreno(4), cc_vegas(4), mod_cc(4), tcp(4)
Development and testing of this software were made possible in part by grants from the FreeBSD Foundation and Cisco University Research Program Fund at Community Foundation Silicon Valley.
Integrate with sctp(4).
The modular Congestion Control (CC) framework first appeared in FreeBSD 9.0.
The framework was first released in 2007 by James Healy and Lawrence Stewart whilst working on the NewTCP research project at Swinburne University of Technology's Centre for Advanced Internet Architectures, Melbourne, Australia, which was made possible in part by a grant from the Cisco University Research Program Fund at Community Foundation Silicon Valley. More details are available at:
http://caia.swin.edu.au/urp/newtcp/
The mod_cc
framework was written by
Lawrence Stewart
<lstewart@FreeBSD.org>,
James Healy
<jimmy@deefa.com> and
David Hayes
<david.hayes@ieee.org>.
This manual page was written by David Hayes <david.hayes@ieee.org> and Lawrence Stewart <lstewart@FreeBSD.org>.
January 21, 2016 | Debian |