IEEE80211_SCAN(9) | Kernel Developer's Manual | IEEE80211_SCAN(9) |
ieee80211_scan
—
802.11 scanning support
#include
<net80211/ieee80211_var.h>
int
ieee80211_start_scan
(struct
ieee80211vap *, int flags, u_int
duration, u_int mindwell, u_int
maxdwell, u_int nssid, const
struct ieee80211_scan_ssid ssids[]);
int
ieee80211_check_scan
(struct
ieee80211vap *, int flags, u_int
duration, u_int mindwell, u_int
maxdwell, u_int nssid, const
struct ieee80211_scan_ssid ssids[]);
int
ieee80211_check_scan_current
(struct
ieee80211vap *);
int
ieee80211_bg_scan
(struct
ieee80211vap *,
int);
int
ieee80211_cancel_scan
(struct
ieee80211vap *);
int
ieee80211_cancel_scan_any
(struct
ieee80211vap *);
int
ieee80211_scan_next
(struct
ieee80211vap *);
int
ieee80211_scan_done
(struct
ieee80211vap *);
int
ieee80211_probe_curchan
(struct
ieee80211vap *,
int);
void
ieee80211_add_scan
(struct ieee80211vap
*, const struct ieee80211_scanparams *,
const struct ieee80211_frame *, int
subtype, int rssi, int
noise);
void
ieee80211_scan_timeout
(struct
ieee80211com *);
void
ieee80211_scan_assoc_fail
(struct
ieee80211vap *, const uint8_t
mac[IEEE80211_ADDR_LEN], int reason);
void
ieee80211_scan_flush
(struct
ieee80211vap *);
void
ieee80211_scan_iterate
(struct
ieee80211vap *, ieee80211_scan_iter_func,
void *);
void
ieee80211_scan_dump_channels
(const
struct ieee80211_scan_state *);
void
ieee80211_scanner_register
(enum
ieee80211_opmode, const struct ieee80211_scanner
*);
void
ieee80211_scanner_unregister
(enum
ieee80211_opmode, const struct ieee80211_scanner
*);
void
ieee80211_scanner_unregister_all
(const
struct ieee80211_scanner *);
const struct ieee80211_scanner *
ieee80211_scanner_get
(enum
ieee80211_opmode);
The net80211
software layer provides an
extensible framework for scanning. Scanning is the procedure by which a
station locates a BSS to join (in infrastructure and IBSS mode), or a
channel to use (when operating as an AP or an IBSS master). Scans are either
“active” or “passive”. An active scan causes one
or more ProbeRequest frames to be sent on visiting each channel. A passive
request causes each channel in the scan set to be visited but no frames to
be transmitted; the station only listens for traffic. Note that active
scanning may still need to listen for traffic before sending ProbeRequest
frames depending on regulatory constraints.
A scan operation involves constructing a set of channels to
inspect (the scan set), visiting each channel and collecting information
(e.g. what BSS are present), and then analyzing the results to make
decisions such as which BSS to join. This process needs to be as fast as
possible so net80211
does things like intelligently
construct scan sets and dwell on a channel only as long as necessary. Scan
results are cached and the scan cache is used to avoid scanning when
possible and to enable roaming between access points when operating in
infrastructure mode.
Scanning is handled by pluggable modules that
implement policy
per-operating mode. The core scanning support provides an infrastructure to
support these modules and exports a common API to the rest of the
net80211
layer. Policy modules decide what channels
to visit, what state to record to make decisions, and selects the final
station/channel to return as the result of a scan.
Scanning is done synchronously when
initially bringing a vap to an operational state and optionally in the
background to maintain the scan cache for doing roaming and rogue AP
monitoring. Scanning is not tied to the net80211
state machine that governs vaps except for linkage to the
IEEE80211_S_SCAN
state. Only one vap at a time may
be scanning; this scheduling policy is handled in
ieee80211_new_state
()
and is transparent to scanning code.
Scanning is controlled by a set of parameters that (potentially)
constrains the channel set and any desired SSID's and BSSID's.
net80211
comes with a standard scanner module that
works with all available operating modes and supports “background
scanning” and “roaming” operation.
Scanning modules use a registration mechanism to hook into the
net80211
layer. Use
ieee80211_scanner_register
()
to register a scan module for a particular operating mode and
ieee80211_scanner_unregister
()
or
ieee80211_scanner_unregister_all
()
to clear entries (typically on module unload). Only one scanner module can
be registered at any time for an operating mode.
Scanning operations are usually managed by the
net80211
layer. Drivers must provide
ic_scan_start and ic_scan_stop
methods that are called at the start of a scan and when the work is done;
these should handle work such as enabling receive of Beacon and
ProbeResponse frames and disable any BSSID matching. The
ic_set_channel method is used to change channels while
scanning. net80211
will generate ProbeRequest frames
and transmit them using the ic_raw_xmit
method.
Frames received while scanning are dispatched to
net80211
using the normal receive path. Devices that
off-load scan work to firmware most easily mesh with
net80211
by operating on a channel-at-a-time basis
as this defers control to net80211's
scan machine
scheduler. But multi-channel scanning is supported if the driver manually
dispatches results using ieee80211_add_scan
()
routine to enter results into the scan cache.
Scan requests occur by way of the
IEEE80211_SCAN_REQUEST
ioctl or through a change in
a vap's state machine that requires scanning. In both cases the scan cache
can be checked first and, if it is deemed suitably “warm” then
it's contents are used without leaving the current channel. To start a scan
without checking the cache
ieee80211_start_scan
()
can be called; otherwise
ieee80211_check_scan
()
can be used to first check the scan cache, kicking off a scan if the cache
contents are out of date. There is also
ieee80211_check_scan_current
()
which is a shorthand for using previously set scan parameters for checking
the scan cache and then scanning.
Background scanning is done using
ieee80211_bg_scan
()
in a co-routine fashion. The first call to this routine will start a
background scan that runs for a limited period of time before returning to
the BSS channel. Subsequent calls advance through the scan set until all
channels are visited. Typically these later calls are timed to allow receipt
of frames buffered by an access point for the station.
A scan operation can be canceled using
ieee80211_cancel_scan
()
if it was initiated by the specified vap, or
ieee80211_cancel_scan_any
()
to force termination regardless which vap started it. These requests are
mostly used by net80211
in the transmit path to
cancel background scans when frames are to be sent. Drivers should not need
to use these calls (or most of the calls described on this page).
The
ieee80211_scan_next
()
and
ieee80211_scan_done
()
routines do explicit iteration through the scan set and should not normally
be used by drivers.
ieee80211_probe_curchan
()
handles the work of transmitting ProbeRequest frames when visiting a channel
during an active scan. When the channel attributes are marked with
IEEE80211_CHAN_PASSIVE
this function will arrange
that before any frame is transmitted 802.11 traffic is first received (in
order to comply with regulatory constraints).
Min/max dwell time parameters are used to constrain time spent visiting a channel. The maximum dwell time constrains the time spent listening for traffic. The minimum dwell time is used to reduce this time--when it is reached and one or more frames have been received then an immediate channel change will be done. Drivers can override this behaviour through the iv_scan_mindwell method.
The scan cache contents are managed by the scan policy module and
are opaque outside this module. The net80211
scan
framework defines API's for interacting. The validity of the scan cache
contents are controlled by iv_scanvalid which is
exported to user space through the
IEEE80211_SCAN_VALID
request.
The cache contents can be explicitly
flushed with
ieee80211_scan_flush
()
or by setting the IEEE80211_SCAN_FLUSH
flag when
starting a scan operation.
Scan cache entries are created with the
ieee80211_add_scan
()
routine; usually on receipt of Beacon or ProbeResponse frames. Existing
entries are typically updated based on the latest information though some
information such as RSSI and noise floor readings may be combined to present
an average.
The cache contents is aged through
ieee80211_scan_timeout
()
calls. Typically these happen together with other station table activity;
every IEEE80211_INACT_WAIT
seconds (default 15).
Individual cache entries are
marked usable with
ieee80211_scan_assoc_success
()
and faulty with
ieee80211_scan_assoc_fail
()
with the latter taking an argument to identify if there was no response to
Authentication/Association requests or if a negative response was received
(which might hasten cache eviction or blacklist the entry).
The cache contents can be viewed using
the
ieee80211_scan_iterate
()
call. Cache entries are exported in a public format that is exported to user
applications through the IEEE80211_SCAN_RESULTS
request.
March 29, 2010 | Debian |