to being more generic.
Other embedded SoCs also throw the configuration/PCI register
info into flash.
For now I'm just hard-coding the AR9280 option (for on-board AR9220's on
AP94 and commercial designs (eg D-Link DIR-825.))
TODO:
* Figure out how to support it for all 11n SoC NICs by doing it in
ar5416InitState();
* Don't hard-code the EEPROM size - add another field which is set
by the relevant chip initialisation code.
* 'owl_eep_start_loc' may need to be overridden in some cases to 0x0.
I need to do some further digging.
where they've disabled all the wireless devices/framework.
This is just a build workaround. If you're actively using wireless,
you must still define AH_SUPPORT_AR5416 as I'm not sure what else
will break!
The real solution is to make the module build depend if AH_SUPPORT_AR5416
is defined, as well as make the 11n code in if_ath_tx.c and if_ath_tx_ht.c
completely optional (maybe depend upon ATH_SUPPORT_11N.)
This shows that the majority of the weird traffic I see here are probe
frames that haven't been sent out, but I can also trigger this condition
by doing ICMP w/ -i 0.3 - enough to trigger the TX during actual scanning,
but not fast enough to stop scanning from occuring.
PR: kern/163689
doing split software/hardware LED configuration, we can now simply
treat "softled" as an "output" mux type.
This works fine on this DWA-552. Previous generation (pre-11n NICs) don't
have a GPIO mux - only input/output configuration - so they ignore this
field.
The hardware (MAC) LED blinking involves a few things:
* Selecting which GPIO pins map to the MAC "power" and "network" lines;
* Configuring the MAC LED state (associated, scanning, idle);
* Configuring the MAC LED blinking type and speed.
The AR5416 HAL configures the normal blinking setup - ie, blink rate based
on TX/RX throughput. The default AR5212 HAL doesn't program in any
specific blinking type, but the default of 0 is the same.
This code introduces a few things:
* The hardware led override is configured via sysctl 'hardled';
* The MAC network and power LED GPIO lines can be set, or left at -1
if needed. This is intended to allow only one of the hardware MUX
entries to be configured (eg for PCIe cards which only have one LED
exposed.)
TODO:
* For AR2417, the software LED blinking involves software blinking the
Network LED. For the AR5416 and later, this can just be configured
as a GPIO output line. I'll chase that up with a subsequent commit.
* Add another software LED blink for "Link", separate from "activity",
which blinks based on the association state. This would make my
D-Link DWA-552 have consistent and useful LED behaviour (as they're
marked "Link" and "Activity."
* Don't expose the hardware LED override unless it's an AR5416 or later,
as the previous generation hardware doesn't have this multiplexing
setup.
Some of the NICs I have here power up with the LEDs blinking, which is
incorrect. The blinking should only occur when the NIC is attempting
to associate.
* On powerup, set the state to HAL_LED_INIT, which turns on the "Power" MAC
LED but leaves the "Network" MAC LED the way it is.
* On resume, also init it to HAL_LED_INIT unless in station mode, where
it's forced to HAL_LED_RUN. Hopefully the net80211 state machine will
call newstate() at some point, which will refiddle the LEDs.
I've tested this on a handful of 11n and pre-11n NICs. The blinking
behaviour is slightly more sensible now.
relying on what the register defaults are.
This forces the blink mode to be proportional to the TX and RX frames
which match the RX filter.
This (along with a few tweaks to if_ath_led.c to configure the correct
GPIO pins) allows my DWA-552 AR5416 NIC to blink the LEDs in a useful
fashion, however those LEDs are marked "Link" and "Act(ivity)", which
don't really map well to the "power" / "network" LED interface which
the MAC provides. Some further tinkering is needed to see what other
useful operating modes are possible.
state from correctly updating things.
The reference driver directly enables/disables the LED state as required,
rather than nailing it up like it currently is. That'll have to come
later by adding some further HAL methods.
Obtained from: Atheros
* Bring the AR5416 GPIO mux mask code in line with the code from the
HAL.
* Add HAL_DEBUG_GPIO debugging statements, to track what's going on.
* Add Kiwi GPIO specific changes for reading values back.
Obtained from: Atheros
* As a preparation for AR9287 GPIO support, add in the AR9287 GPIO mask.
* Fix the association mask values; these are post-shift values but were
being shifted in twice. This resulted in some garbage being written
in the wrong place and the link LED (at least on my d-link AR5416
NIC) giving totally incorrect blink patterns.
Some users were reporting concurrent resets _were_ occuring - ie,
either two ath_reset()s ran at the same time (likely one on each CPU)
or ath_reset() versus ath_chan_change().
Instead, this now tries to grab the serialisation semaphore and will
pause() for a while if it fails. It will always eventually succeed though
and will log an error if it hits the recursion situation.
All of this stuff needs to die a horrible death at some point and be
replaced with a properly serialising method of programming this stuff
(eg using the net80211 taskqueue for all of this stuff.) The trouble
is figuring out how to handle the concurrent ioctl() based things without
introducing more LORs (which is another reason why I haven't just wrapped
all of this stuff in large, long-lived locks, a-la what Linux can get
away with.)
MFC after: Absolutely, positively never.
This doesn't fix compilation w/out AH_SUPPORT_AR5416 as all of the software
aggregation support in if_ath_tx.c and 11n code in if_ath_tx_ht.c touches
the 11n specific fields. I'll work on that later.
going on with the occasional garbage rs_antenna field reported by AR9285
users.
I've discovered that the 11n NICs only fill out the entire RX status
descriptor on the final descriptor in an aggregate. Some of the fields
(notably RSSI) are complete nonsense for A-MPDU subframes. This may
be another example of this.
The driver doesn't currently toss out statistics for non-final aggregate
frames. It's likely that this should be done.
If any users hit this particular debugging message they should report it
immediately to freebsd-wireless@freebsd.org - please ensure you have
ATH_DEBUG enabled so it prints out the full receive descriptor.
PR: kern/163312
There's currently no public code which uses this feature and the
current reference driver doesn't enable this feature at all.
It's possible it was used by a previous version of the driver and
that indeed it should return HAL_STATUS; but at this point I'm
happy to require that they complain and submit a patch.
This was found by LLVM compile-time type checking.
Submitted by: dim
and sys/dev/ath/ath_hal/ar5416/ar5416_misc.c:
sys/dev/ath/ath_hal/ar5212/ar5212_misc.c:577:24: warning: implicit conversion from enumeration type 'HAL_STATUS' to different enumeration type 'HAL_BOOL' [-Wconversion]
return HAL_EINVAL;
~~~~~~ ^~~~~~~~~~
and:
sys/dev/ath/ath_hal/ar5416/ar5416_misc.c:164:9: warning: implicit conversion from enumeration type 'HAL_STATUS' to different enumeration type 'HAL_BOOL' [-Wconversion]
return HAL_OK;
~~~~~~ ^~~~~~
In both cases, enums HAL_BOOL and HAL_STATUS are mixed up.
MFC after: 1 week
and sys/dev/ath/ath_hal/ar5211/ar5211_power.c:
sys/dev/ath/ath_hal/ar5210/ar5210_power.c:36:3: warning: signed shift result (0x200000000) requires 35 bits to represent, but 'int' only has 32 bits [-Wshift-overflow]
OS_REG_RMW_FIELD(ah, AR_SCR, AR_SCR_SLE, AR_SCR_SLE_ALLOW);
^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
sys/dev/ath/ath_hal/ah_internal.h:472:42: note: expanded from:
(OS_REG_READ(_a, _r) &~ (_f)) | (((_v) << _f##_S) & (_f)))
^
sys/dev/ath/ah_osdep.h:127:49: note: expanded from:
(bus_space_handle_t)(_ah)->ah_sh, (_reg), (_val))
^~~~
The AR_SCR_SLE_{WAKE,SLP,NORM} values are pre-shifted in ar5210reg.h and
ar5211reg.h, while they should be unshifted, like in ar5212reg.h. Then,
when the OS_REG_RMW_FIELD() macro shifts them again, the values will
overflow, becoming effectively zero.
MFC after: 1 week
attached this way.
The AR5212 based NICs have a variety of RF frontends, so there's a linker set
which the AR5212 attach routine calls. The same framework is used for the
AR5416 and later but as there's a fixed RF frontend for each 11n NIC, it
is just directly attached.
However in the case of compiling a cut down HAL (eg _just_ AR9130 WMAC support),
the linker set ends up being empty and this causes the compile to fail.
So this is just a workaround for that - it means those users who wish an 11n
only HAL can compile the 11n chipsets and RF frontend they need, and just
"ath_ar5212" for the AR5212/AR5416 common code, and it'll just work.
Sponsored by: Hobnob, Inc.
The calibrate callout is done with the sc lock held.
This only showed up when using an older NIC (AR5212) whose
radio/phy requires the rfgain adjustment.
Pointy-hat-to: adrian
Sponsored by: Hobnob, Inc.
* Failall is now named just that.
* Add TX ok and TX fail, for aggregate frame sub-frames.
This will break athstats; a followup commit wil resolve this.
Sponsored by: Hobnob, Inc.
This fixes panics that users have been seeing when operating in station mode,
where the interface undergoes a lot more resets then in hostap mode (ie whilst
doing channel scanning.)
Reported by: arundel, wblock@wonkity.com
Sponsored by: Hobnob, Inc.
mode configuration registers. This is apparently required for correct
behaviour, but also requires the chip to actually officially support it.
Sponsored by: Hobnob, Inc.
"correct" handling of frames in the RX pending queue during interface
transitions.
* ath_stoprecv() doesn't blank out the descriptor list - that's what
ath_startrecv() does. So, change a comment to reflect that.
* ath_stoprecv() does include a large (3ms) delay to let pending DMA
complete. However, I'm under the impression that the stopdma hal
method does check for a bit in the PCU to indicate DMA has stopped.
So, to help with fast abort and restart, modify ath_stoprecv() to take
a flag which indicates whether this is needed.
* Modify the uses of ath_stoprecv() to pass in a flag to support the
existing behaviour (ie, do the delay.)
* Remove some duplicate PCU teardown code (which wasn't shutting down DMA,
so it wasn't entirely correct..) and replace it with a call to
ath_stoprecv(sc, 0) - which disables the DELAY call.
The upshoot of this is now channel change doesn't simply drop completed
frames on the floor, but instead it cleanly handles those frames.
It still discards pending TX frames in the software and hardware queues
as there's no (current) logic which forcibly recalculates the rate control
information (or whether they're appropriate to be on the TX queue after
a channel change), that'll come later.
This still doesn't stop all the sources of queue stalls but it does
tidy up some of the code duplication.
To be complete, queue stalls now occur during normal behaviour -
they only occur after some kind of broken behaviour causes an interface
or node flush, upsetting the TX/RX BAW. Subsequent commits will
incrementally fix these and other related issues.
Sponsored by: Hobnob, Inc.
for the ath(4) driver.
Currently, there's nothing stopping reset, channel change and general
TX/RX from overlapping with each other. This wasn't a big deal with
pre-11n traffic as it just results in some dropped frames.
It's possible this may have also caused some inconsistencies and
badly-setup hardware.
Since locks can't be held across all of this (the Linux solution)
due to LORs with the network stack locks, some state counter
variables are used to track what parts of the code the driver is
currently in.
When the hardware is being reset, it disables the taskqueue and
waits for pending interrupts, tx, rx and tx completion before
it begins the reset or channel change.
TX and RX both abort if called during an active reset or channel
change.
Finally, the reset path now doesn't flush frames if ATH_RESET_NOLOSS
is set. Instead, completed TX and RX frames are passed back up to
net80211 before the reset occurs.
This is not without problems:
* Raw frame xmit are just dropped, rather than placed on a queue.
The net80211 stack should be the one which queues these frames
rather than the driver.
* It's all very messy. It'd be better if these hardware operations
were serialised on some kind of work queue, rather than hoping
they can be run in parallel.
* The taskqueue block/unblock may occur in parallel with the
newstate() function - which shuts down the taskqueue and restarts
it once the new state is known. It's likely these operations should
be refcounted so the taskqueue is restored once no other areas
in the code wish to suspend operations.
* .. interrupt disable/enable should likely be refcounted as well.
With this work, the driver does not drop frames during stuck beacon
or fatal errors and thus 11n traffic continues to run correctly.
Default and full resets however do still drop frames and it's possible
this may occur, causing traffic loss and session stalls.
Sponsored by: Hobnob, Inc.
I need to investigate this a little closer, but it seems that in noisy
environments the NF load takes longer than 5 * DELAY(10) and this is
messing up future NF calibrations. (The background: NF calibrations
begin at the value programmed in after the load has completed, so
if this is never loaded in, the NF calibrations only ever start at
the currently calibrated NF value, rather than starting at something
high (say -50.)
More investigation about the effect on 11n RX and calibration results
are needed.
Sponsored by: Hobnob, Inc.
The AR5416 MAC (which shows up in the AR5008, AR9001, AR9002 devices) has
issues with PCI transactions on SMP machines. This work-around enforces
that register access is serialised through a (global for now) spinlock.
This should stop the hangs people have seen with the AR5416 PCI devices
on SMP hosts.
Obtained by: Linux, Atheros
it's cloned and that clone is retransmitted. This means that the
ath_buf pointer squirreled away on the baw window array is suddenly
wrong and was causing all kinds of console output.
This updates the pointer in that particular BAW slot to the new
ath_buf after ensuring that:
* the new and old buffers have the same seqno;
* the current slot pointer matches the old buffer pointer.
This quietens the debugging output (again), restoring said debugging
to only signify when a broken condition has occured.
Sponsored by: Hobnob, Inc.