The HAL already included the STBC fields; it just needed to be exposed
to the driver and net80211 stack.
This should allow single-stream STBC TX and RX to be negotiated; however
the driver and rate control code currently don't do anything with it.
* Remove ar5416UpdateChainmasks();
* Remove the TX chainmask override code from the ar5416 TX descriptor
setup routines;
* Write a driver method to calculate the current chainmask based on the
operating mode and update the driver state;
* Call the HAL chainmask method before calling ath_hal_reset();
* Use the currently configured chainmask in the TX descriptors rather than
the hardware TX chainmasks.
Tested:
* AR5416, STA/AP mode - legacy and 11n modes
Right now the only way to set the chainmask is to set the hardware
configured chainmask through capabilities. This is fine for forcing
the chainmask to be something other than what the hardware is capable
of (eg to reduce TX/RX to one connected antenna) but it does change what
the HAL hardware chainmask configuration is.
For operational mode changes, it (may?) make sense to separately control
the TX/RX chainmask.
Right now it's done as part of ar5416_reset.c - ar5416UpdateChainMasks()
calculates which TX/RX chainmasks to enable based on the operating mode.
(1 for legacy and whatever is supported for 11n operation.) But doing
this in the HAL is suboptimal - the driver needs to know the currently
configured chainmask in order to correctly enable things for each
TX descriptor. This is currently done by overriding the chainmask
config in the ar5416 TX routines but this has to disappear - the AR9300
HAL support requires the driver to dynamically set the TX chainmask based
on the TX power and TX rate in order to meet mini-PCIe slot power
requirements.
So:
* Introduce a new HAL method to set the operational chainmask variables;
* Introduce null methods for the previous generation chipsets;
* Add new driver state to record the current chainmask separate from
the hardware configured chainmask.
Part #2 of this will involve disabling ar5416UpdateChainMasks() and moving
it into the driver; as well as properly programming the TX chainmask
based on the currently configured HAL chainmask.
Tested:
* AR5416, STA mode - both legacy (11a/11bg) and 11n rates - verified
that AR_SELFGEN_MASK (the chainmask used for self-generated frames like
ACKs and RTSes) is correct, as well as the TX descriptor contents is
correct.
an incorrectly calculated RTS duration value when transmitting aggregates.
These earlier 802.11n NICs incorrectly used the ACK duration time when
calculating what to put in the RTS of an aggregate frame. Instead it
should have used the block-ack time. The result is that other stations
may not reserve enough time and start transmitting _over_ the top of
the in-progress blockack field. Tsk.
This workaround is to popuate the burst duration field with the delta
between the ACK duration the hardware is using and the required duration
for the block-ack. The result is that the RTS field should now contain
the correct duration for the subsequent block-ack.
This doesn't apply for AR9280 and later NICs.
Obtained from: Qualcomm Atheros
Specifically - never jack the TX FIFO threshold up to the absolute
maximum; always leave enough space for two DMA transactions to
appear.
This is a paranoia from the Linux ath9k driver. It can't hurt.
Obtained from: Linux ath9k
This has reduced the number of TX delimiter and data underruns when
doing large UDP transfers (>100mbit).
This stops any HAL_INT_TXURN interrupts from occuring, which is a good
sign!
Obtained from: Qualcomm Atheros
This includes the HAL routines to setup, enable/activate/disable spectral
scan and configure the relevant registers.
This still requires driver interaction to enable spectral scan reporting.
Specifically:
* call ah_spectralConfigure() to configure and enable spectral scan;
* .. there's currently no way to disable spectral scan... that will have
to follow.
* call ah_spectralStart() to force start a spectral report;
* call ah_spectralStop() to force stop an active spectral report.
The spectral scan results appear as PHY errors (type 0x5 on the AR9280,
same as radar) but with the spectral scan bit set (0x10 in the last byte
of the frame) identifying it as a spectral report rather than a radar
FFT report.
Caveats:
* It's likely quite difficult to run spectral _and_ radar at the same
time. Enabling spectral scan disables the radar thresholds but
leaves radar enabled. Thus, the driver (for now) needs to ensure
that only one or the other is enabled.
* .. it needs testing on HT40 mode.
Tested:
* AR9280 in STA mode, HT/20 only
TODO:
* Test on AR9285, AR9287;
* Test in both HT20 and HT40 modes;
* .. all the driver glue.
Obtained from: Qualcomm Atheros
* Finish adding the HAL capability to announce whether a NIC supports
spectral scan or not;
* Add spectral scan methods to the HAL structure;
* Add HAL_SPECTRAL_PARAM for configuration of the spectral scan logic.
The capability ID and HAL_SPECTRAL_PARAM struct are from Qualcomm
Atheros.
enforcing the TXOP and TBTT limits:
* Frames which will overlap with TBTT will not TX;
* Frames which will exceed TXOP will be filtered.
This is not enabled by default; it's intended to be enabled by the
TDMA code on 802.11n capable chipsets.
what the maximum legal values are.
The current beacon timer configuration from TDMA wraps things at
HAL_BEACON_PERIOD-1 TU. For the 11a chips this is fine, but for
the 11n chips it's not enough resolution. Since the 11a chips have a
limit on what's "valid", just enforce this so when I do write larger
values in, they get suitably wrapped before programming.
Tested:
* AR5413, TDMA slave
Todo:
* Run it for a (lot) longer on a clear channel, ensure that no strange
slippages occur.
* Re-validate this on STA configurations, just to be sure.
After chatting with the MAC team, the TSF writes (at least on the 11n
MACs, I don't know about pre-11n MACs) are done as 64 bit writes that
can take some time. So, doing a 32 bit TSF write is definitely not
supported. Leave a comment here which explains that.
Whilst here, add a comment which outlines that after a reset or TSF
write, the TSF write may take a while (up to 50uS) to update.
A write or reset shouldn't be done whilst the previous one is in
flight. Also (and this isn't currently done) a read shouldn't
occur until the SLEEP32_TSF_WRITE_STAT is clear. Right now we're
not doing that, mostly because we haven't been doing lots of TSF
resets/writes until recently.
encryption types.
The AR5210 only has four WEP key slots, in contrast to what the
later MACs have (ie, the keycache.) So there's no way to store a "clear"
key.
Even if the driver is taught to not allocate CLR key entries for
the AR5210, the hardware will actually attempt to decode the encrypted
frames with the (likely all 0!) WEP keys.
So for now, disable the hardware encryption entirely and just so it
all in software. That allows both WEP -and- WPA to actually work.
If someone wishes to try and make hardware WEP _but_ software WPA work,
they'll have to create a HAL capability to enable/disable hardware
encryption based on the current STA/Hostap mode. However, making
multi-vap work with one WEP and one WPA VAP will require hardware
encryption to be disabled anyway.
them, please let me know if not). Most of these are of the form:
static const struct bzzt_type {
[...list of members...]
} const bzzt_devs[] = {
[...list of initializers...]
};
The second const is unnecessary, as arrays cannot be modified anyway,
and if the elements are const, the whole thing is const automatically
(e.g. it is placed in .rodata).
I have verified this does not change the binary output of a full kernel
build (except for build timestamps embedded in the object files).
Reviewed by: yongari, marius
MFC after: 1 week
* introduce a new HAL API method to pull out the TX status descriptor
contents.
* Add num_delims to the 11n first aggr method. This isn't used by the
driver at the moment so it won't affect anything.
* Add some more ANI spur immunity levels.
* For AR5111 radios attached to an AR5212, limit the 5GHz channels
that are available. A later revision of the AR5111 supports the 4.9GHz
PSB channels but right now there's no check in place for the radio
revision.
If someone wants PSB support on AR5212+AR5111 radios then please let
me know and I'll add the relevant version check.
Obtained from: Qualcomm Atheros
the internet as "AR9380 and later which didn't get its PCI ID written
in at power-on", so it's hardly an unknown constant.
Obtained from: Qualcomm Atheros
AR5416 and AR9280, but leave it disabled by default.
TL;DR: don't enable this code at all unless you go through the process
of getting the NIC re-certified. This is purely to be used as a
reference and NOT a certified solution by any stretch of the imagination.
The background:
The AR5112 RF synth right up to the AR5133 RF synth (used on the AR5416,
derivative is used for the AR9130/AR9160) only implement down to 2.5MHz
channel spacing in 5GHz. Ie, the RF synth is programmed in steps of 2.5MHz
(or 5, 10, 20MHz.) So they can't represent the quarter rate channels
in the 4.9GHz PSB (which end in xxx2MHz and xxx7MHz). They support
fractional spacing in 2GHz (1MHz spacing) (or things wouldn't work,
right?)
So instead of doing this, the RF synth programming for the AR5112 and
later code will round to the nearest available frequency.
If all NICs were RF5112 or later, they'll inter-operate fine - they all
program the same. (And for reference, only the latest revision of the
RF5111 NICs do it, but the driver doesn't yet implement the programming.)
However:
* The AR5416 programming didn't at all implement the fractional synth
work around as above;
* The AR9280 programming actually programmed the accurate centre frequency
and thus wouldn't inter-operate with the legacy NICs.
So this patch:
* Implements the 4.9GHz PSB fractional synth workaround, exactly as the
RF5112 and later code does;
* Adds a very dirty workaround from me to calculate the same channel
centre "fudge" to the AR9280 code when operating on fractional frequencies
in 5GHz.
HOWEVER however:
It is disabled by default. Since the HAL didn't implement this feature,
it's highly unlikely that the AR5416 and AR928x has been tested in these
centre frequencies. There's a lot of regulatory compliance testing required
before a NIC can have this enabled - checking for centre frequency,
for drift, for synth spurs, for distortion and spectral mask compliance.
There's likely a lot of other things that need testing so please don't
treat this as an exhaustive, authoritative list. There's a perfectly good
process out there to get a NIC certified by your regulatory domain, please
go and engage someone to do that for you and pay the relevant fees.
If a company wishes to grab this work and certify existing 802.11n NICs
for work in these bands then please be my guest. The AR9280 works fine
on the correct fractional synth channels (49x2 and 49x7Mhz) so you don't
need to get certification for that. But the 500KHz offset hack may have
the above issues (spur, distortion, accuracy, etc) so you will need to
get the NIC recertified.
Please note that it's also CARD dependent. Just because the RF synth
will behave correctly doesn't at all mean that the card design will also
behave correctly. So no, I won't enable this by default if someone
verifies a specific AR5416/AR9280 NIC works. Please don't ask.
Tested:
I used the following NICs to do basic interoperability testing at
half and quarter rates. However, I only did very minimal spectrum
analyser testing (mostly "am I about to blow things up" testing;
not "certification ready" testing):
* AR5212 + AR5112 synth
* AR5413 + AR5413 synth
* AR5416 + AR5113 synth
* AR9280
This doesn't specifically fix the issue(s) i'm seeing in this 2GHz
environment (where setting/increasing spur immunity causes OFDM restart
errors to skyrocket through the roof; but leaving it at 0 would leave
the environment cleaner..)
Pointy-hat-to: me, for committing this broken code in the first place.
I'm not sure where in the deep, distant past I found the AR_PHY_MODE
registers for half/quarter rate mode, but unfortunately that doesn't
seem to work "right" for non-AR9280 chips.
Specifically:
* don't touch AR_PHY_MODE
* set the PLL bits when configuring half/quarter rate
I've verified this on the AR9280 (5ghz fast clock) and the AR5416.
The AR9280 works in both half/quarter rate; the AR5416 unfortunately
only currently works at half rate. It fails to calibrate on quarter rate.
