The AR5212 HAL didn't check this field; timers are enabled a different
way.
The AR5416 HAL however did, and since this field was uninitialised, it had
whatever was on the stack at the time. This lead to "unpredictable"
behaviour.
This allows TDMA to work on the AR5416 and later chipsets.
Thanks to: paradyse@gmail.com
Approved by: re (kib, blanket)
* Fix SLEEP1/SLEEP2 register definitions; the CAB/Beacon timeout
fields have changed in AR5416 and later
* The TIM_PERIOD and DTIM_PERIOD registers are now microsecond fields,
not TU.
Obtained from: Linux ath9k, Atheros reference
Approved by: re (kib, blanket)
or later. Previous hardware had some as TU, some as 1/8th
TU.
* Modify AR_NEXT_DBA and AR_NEXT_SWBA to use a new macro,
ONE_EIGHTH_TU_TO_USEC(), which converts the 1/8th TU
fields to USEC. This is just cosmetic and matches the
Atheros reference driver.
* Fix AR_NEXT_TBTT, which is USEC, not TU.
Submitted by: paradyse@gmail.com
Approved by: re (kib, blanket)
needing this particular modification.
It can be called during ath_dfs_radar_enable() and still achieve the
same functionality, so I am.
Approved by: re (kib, blanket)
Remove this debugging, it's not needed anymore and when not enabled,
those variables trigger a compiler warning.
Approved by: re (kib, blanket)
Pointy-hat-to: adrian, for not testing a non-debug compile of this code enough
allows it to be overridden at runtime.
Thus, add a function which updates ah_dfsDomain after a channel set
call to ath_hal_set_channels().
Approved by: re (kib, blanket)
and the Atheros reference code.
The radar detection code needs to know what the current DFS domain is.
Since net80211 doesn't currently know this information, it's extracted
from the HAL regulatory domain information.
The specifics:
* add a new ath_dfs API hook, ath_dfs_init_radar_filters(), which
updates the radar filters whenever the regulatory domain changes.
* add HAL_DFS_DOMAIN which describes the currently configured DFS domain .
* add a new HAL internal variable which tracks the currently configured
HAL DFS domain.
* add a new HAL capability, HAL_CAP_DFS_DMN, which returns the currently
configured HAL DFS domain setting.
* update the HAL DFS domain setting whenever the channel setting is
updated.
Since this isn't currently used by any radar code, these should all
be no-ops for existing users.
Obtained from: Atheros
Submitted by: KBC Networks, sibridge
Approved by: re (kib, blanket)
if 5ghz fast clock is enabled in the current operating mode.
It's slightly dirty, but it's part of the reference HAL and used by
the (currently closed-source) radar event code to map radar pulses
back to microsecond durations.
Obtained from: Atheros
Approved by: re (kib, blanket)
the ar9130 code.
Since at least one kernel config specifies individual ath HAL chips
rather than just "device ath_hal" (arm/AVILA), I'm doing this so people
aren't caught out when they update to -HEAD or 9.0 and discover their
ath setup doesn't compile.
I'll revisit this with a proper fix sometime before 9.0-RELEASE.
Approved by: re (kib, blanket)
Pointed out by: ray@
Pointy hat to: adrian@
systems, in the same way that AR9130 embedded systems work.
This isn't -everything- that is required - the PCI glue still
needs to be taught about the eepromdata hint, along the same
lines as the AHB glue.
Approved by: re (kib, blanket)
truly.
Before 802.11n, the RX descriptor list would employ the "self-linked tail
descriptor" trick which linked the last descriptor back to itself.
This way, the RX engine would never hit the "end" of the list and stop
processing RX (and assert RXEOL) as it never hit a descriptor whose next
pointer was 0. It would just keep overwriting the last descriptor until
the software freed up some more RX descriptors and chained them onto the
end.
For 802.11n, this needs to stop as a self-linked RX descriptor tickles the
block-ack logic into ACK'ing whatever frames are received into that
self-linked descriptor - so in very busy periods, you could end up with
A-MPDU traffic that is ACKed but never received by the 802.11 stack.
This would cause some confusion as the ADDBA windows would suddenly
be out of sync.
So when that occured here, the last descriptor would be hit and the PCU
logic would stop. It would only start again when the RX descriptor list
was updated and the PCU RX engine was re-tickled. That wasn't being done,
so RXEOL would be continuously asserted and no RX would continue.
This patch introduces a new flag - sc->sc_kickpcu - which when set,
signals the RX task to kick the PCU after its processed whatever packets
it can. This way completed packets aren't discarded.
In case some other task gets called which resets the hardware, don't
update sc->sc_imask - instead, just update the hardware interrupt mask
directly and let either ath_rx_proc() or ath_reset() restore the imask
to its former setting.
Note: this bug was only triggered when doing a whole lot of frame snooping
with serial console IO in the RX task. This would defer interrupt processing
enough to cause an RX descriptor overflow. It doesn't happen in normal
conditions.
Approved by: re (kib, blanket)
interrupt storm.
This is easily triggered by flipping on and off tcpdump -y IEEE802_11_RADIO
w/ witness enabled. This causes a whole lot of console IO and when you're
attached to a serial console (eg on my AR7161 embedded board), the RX
interrupt doesn't get called quickly enough and the RX queue fills up.
This wasn't a problem in the past because of the self-linked RX descriptor
trick - the RX would never hit the "end" of the RX descriptor list.
However this isn't possible for 802.11n (see previous commit history for
why.)
Both Linux ath9k and the Atheros reference driver code do this; I'm just
looking now for where they then restart the PCU receive. Right now the RX
will just stop until the interface is reset.
Obtained from: Linux, Atheros
Approved by: re (kib)
The AR9280 apparently has an issue with descriptors which straddle a page
boundary (4k). I'm not yet sure whether I should use PAGE_SIZE in the
calculations or whether I should use 4096; the reference code uses 4096.
This patch fiddles with descriptor allocation so a descriptor entry
doesn't straddle a 4kb address boundary. The descriptor memory allocation
is made larger to contain extra descriptors and then the descriptor
address is advanced to the next 4kb boundary where needed.
I've tested this both on Merlin (AR9280) and non-Merlin (in this case,
AR9160.)
Obtained from: Linux, Atheros
Approved by: re (kib)
This seems to indicate whether to program the NIC for fractional 5ghz
mode (ie, 5mhz spaced channels, rather than 10 or 20mhz spacing) or not.
The default (0) seems to mean "only program fractional mode if needed".
A different value (eg 1) seems to always enable fractional 5ghz mode
regardless of the frequency.
Obtained from: Atheros
Approved by: re (kib)
Calibration/PCI data that's written to flash (rather than EEPROM attached
to the NIC) is typically already in host-endian. The existing checks
end up swapping 16 bit words incorrectly - the correct solution would be
to read the magic value and determine the EEPROM endianness from that.
(This is what Linux does.)
This doesn't completely enable embedded use of the AR9285/AR9287 -
notably, the EEPROM read methods need to be made generic and available
to all EEPROM drivers. I'll worry about that later.
Approved by: re (kib)
* I messed up the order of parameter true/false; oops!
* AR_PHY_RADAR_1 was being written at the wrong place, and was writing
potential garbage to the hardware.
Approved by: re (kib)
* Teach the AR5212/AR5416 ANI code to use the RX filter methods, rather
than calling the RX filter routines directly.
* Make HAL_ANI_PRESENT and HAL_ANI_MODE unconditionally available,
regardless of whether ah_ani_function is masking it.
* (Mostly) fully disable ANI if interference mitigation is disabled.
When disabled, the ANI code doesn't touch any ANI/PHY registers,
leaving them the default value. This is in line with what the
Atheros reference driver does.
* Correctly set the ANI parameters during ANI reset, rather than
when ANI is enabled. In this way, if ANI is disabled or enabled
whilst the NIC is not active (and there's no current channel),
bogus parameters or a NULL pointer deference doesn't occur.
There's still some lingering issues - notably, the MIB events/interrupts
aren't fully disabled, so MIB interrupts still occur. I'll worry about
that later.
Approved by: re (kib)
This in particular fixes radar PHY handling - on the AR5212
NIC, one enables the AR_PHY_ERR_RADAR bit in AR_PHY_ERR;
the AR5416 and later also needs a bit set in AR_RX_FILTER.
A follow-up commit is needed to convert the AR5416 ANI code
to use this particular method, as it's currently using the
AR5212 methods directly.
Obtained from: Atheros
Approved by: re (kib)
the ADC calibrations if the NIC is in 5ghz 11a or 5ghz HT/20 modes.
I've been told that the dual-ADC is only engaged in turbo/40mhz modes.
Since Sowl (AR9160) seems to return valid-looking calibration data
in 5ghz 20MHz modes, I'm only disabling it for Merlin for now.
It may turn out I can disable it for all chipsets and only enable
it for 40MHz modes.
Approved by: re (kib)
It looks like this was mixed up with the AR9285 calibration code.
This code is now more in line with what Linux ath9k and Atheros
reference drivers do.
Obtained from: Atheros
Approved by: re (kib)
Although this may not be what the original sysctl was designed to do,
it feels a bit more "expected".
Before, if ANI is disabled, the initial ANI parameters are still written
to the hardware, even if they're not enabled. "ANI enabled" would then
adjust the noise immunity parameters dynamically. Disabling ANI would
simply leave the existing noise immunity parameters where they are,
and disable the dynamic part.
The problem is that disabling ANI doesn't leave the hardware in
a consistent, predictable state - so asking a user to disable ANI
wouldn't actually reset the NIC to a consistent set of PHY signal
detection parameters, resulting in an unpredictable/unreliable outcome.
This makes it difficult to get reliable debugging information from
the user.
Approved by: re (kib)
Since no actual radar data is ever handled, this won't
do anything. It's mostly here as a reference for those who
wish to experiment with radar detection.
Approved by: re (kib)
ioctl interface for DFS modules to use.
Since there's no open source dfs code yet, this doesn't introduce any
operational changes.
Approved by: re (kib)
tools.
* introduce pe_enabled, which (will) indicate whether the radar
detection stuff is enabled or not. Right now it's incorrectly
set, based on something previously written. I'll sort it out
later.
* Don't set HAL_PHYERR_PARAM_ENABLE in pe_relstep to say whether
radar detection is on.
* Return whether blockradar, fir128 and enmaxrssi is enabled.
* Change some of the phyerr params to be integers rather than
HAL_BOOL so they can be set to the NOPARAM value when the
setup function is called. This is in line with other radar
parameters.
* Add new configuration parameters for fir128, blockradar and
enmaxrssi, rather than defaulting to off, on and on respectively.
Approved by: re (kib)
polluting the AR5416 code with later chipset support.
Note: ar9280InitPLL() supports Merlin (AR9280) and later (AR9285, AR9287.)
Submitted by: ssgriffonuser@gmail.com
Approved by: re (kib)
These should be disabled for the AR5416 in hostap/mesh/ibss mode,
as the AR5416 doesn't have support for radar detection on the
ext channel of a HT40 setup. Later chips do.
Approved by: re (kib)
reference driver.
* Australia should use FCC3_WORLD
* Add some new SKUs; these are just the EEPROM values and haven't been
fully defined yet. As such they won't affect anything.
Obtained from: Atheros
Approved by: re (kib)
This was removed accidentally when the per HAL instance
code was added, and not reverted when I added back the
global debug variable (for early chip setup debugging.)
the AP doesn't transmit beacons.
If the AP requests a CSA (ie, a channel switch) and then enters CAC
(channel availability check) for 60 seconds, it doesn't send beacons
and it just listens for radar events (and other things which we don't
do yet.)
Now, ath_newstate() was not resetting the beacon timer config on
a transition to the RUN state when in STA mode - it was setting
sc_syncbeacon, which simply updates the beacon config from the
contents of the next received beacon.
This means the STA never generates beacon miss events.
If the AP goes into CAC for 60 seconds and recovers, the STA will
happily receive the first beacon and reconfigure timers.
But if it gets a radar event after that, it'll change channel
again, not notify the station that it's changed channel..
and since the station is happily waiting for the first beacon
to configure the beacon timer details from, it won't ever
generate a beacon miss interrupt and it'll sit there forever
(or until the AP appears on that channel once again.)
This change forces the last known beacon timer config to be
written to hardware on a transition from CSA->RUN in STA mode.
This forces bmiss events to occur and the STA will eventually
(after a handful of beacon miss events) begin scanning for
another access point.
The DFS code was tickling the channel set directly whilst going
through the state RUN -> CSA -> RUN. This only changed the channel;
it didn't go via ath_reset(). However in this driver, a channel
change always causes a chip reset, which resets the beacon timer
configuration and interrupt setup. This meant that data would go
out but as the beacon timers never fired, beacons would never
be queued.
The confusing part is that sometimes the state transition was
RUN -> SCAN -> CAC -> RUN (with CSA being in there sometimes);
going via SCAN would clear sc_beacons and thus the transition
to RUN would reprogram beacon transmission.
In case someone tries debugging why suspending a device currently
beaconing (versus just RX'ing beacons which is what occurs in STA
mode), add a silly comment which should hopefully land them at
this commit message. The call to ath_hal_reset() will be clearing
the beacon config and it may not be always reset.
can be tested.
This doesn't at all actually do radar detection! It's just
so developers who wish to test the net80211 DFS code can easily
do so. Without this flag, the DFS channels are never marked
DFS and thus the DFS stuff doesn't run.
to do about the few cases where the HAL state isn't available (regdomain)
or isn't yet setup (probe/attach.)
The global ath_hal_debug now affects all instances of the HAL.
This also restores the ability for probe/attach debugging to work; as
the sysctl tree may not be attached at that point. Users can just set
the global "hw.ath.hal.debug" to a suitable value to enable probe/attach
related debugging.