the given node.
This takes into account the per-node cap, the ic cap and the
per-channel regulatory caps.
This is designed to replace references to ni_txpower in various net80211
drivers - ni_txpower doesn't necessarily reflect the actual cap for
the given node (eg if the node has the default value of 50dBm (100) and
the administrator has manually configured a lower TX power.)
This patchset implements a new TX lock, covering both the per-VAP (and
thus per-node) TX locking and the serialisation through to the underlying
physical device.
This implements the hard requirement that frames to the underlying physical
device are scheduled to the underlying device in the same order that they
are processed at the VAP layer. This includes adding extra encapsulation
state (such as sequence numbers and CCMP IV numbers.) Any order mismatch
here will result in dropped packets at the receiver.
There are multiple transmit contexts from the upper protocol layers as well
as the "raw" interface via the management and BPF transmit paths.
All of these need to be correctly serialised or bad behaviour will result
under load.
The specifics:
* add a new TX IC lock - it will eventually just be used for serialisation
to the underlying physical device but for now it's used for both the
VAP encapsulation/serialisation and the physical device dispatch.
This lock is specifically non-recursive.
* Methodize the parent transmit, vap transmit and ic_raw_xmit function
pointers; use lock assertions in the parent/vap transmit routines.
* Add a lock assertion in ieee80211_encap() - the TX lock must be held
here to guarantee sensible behaviour.
* Refactor out the packet sending code from ieee80211_start() - now
ieee80211_start() is just a loop over the ifnet queue and it dispatches
each VAP packet send through ieee80211_start_pkt().
Yes, I will likely rename ieee80211_start_pkt() to something that
better reflects its status as a VAP packet transmit path. More on
that later.
* Add locking around the management and BAR TX sending - to ensure that
encapsulation and TX are done hand-in-hand.
* Add locking in the mesh code - again, to ensure that encapsulation
and mesh transmit are done hand-in-hand.
* Add locking around the power save queue and ageq handling, when
dispatching to the parent interface.
* Add locking around the WDS handoff.
* Add a note in the mesh dispatch code that the TX path needs to be
re-thought-out - right now it's doing a direct parent device transmit
rather than going via the vap layer. It may "work", but it's likely
incorrect (as it bypasses any possible per-node power save and
aggregation handling.)
Why not a per-VAP or per-node lock?
Because in order to ensure per-VAP ordering, we'd have to hold the
VAP lock across parent->if_transmit(). There are a few problems
with this:
* There's some state being setup during each driver transmit - specifically,
the encryption encap / CCMP IV setup. That should eventually be dragged
back into the encapsulation phase but for now it lives in the driver TX path.
This should be locked.
* Two drivers (ath, iwn) re-use the node->ni_txseqs array in order to
allocate sequence numbers when doing transmit aggregation. This should
also be locked.
* Drivers may have multiple frames queued already - so when one calls
if_transmit(), it may end up dispatching multiple frames for different
VAPs/nodes, each needing a different lock when handling that particular
end destination.
So to be "correct" locking-wise, we'd end up needing to grab a VAP or
node lock inside the driver TX path when setting up crypto / AMPDU sequence
numbers, and we may already _have_ a TX lock held - mostly for the same
destination vap/node, but sometimes it'll be for others. That could lead
to LORs and thus deadlocks.
So for now, I'm sticking with an IC TX lock. It has the advantage of
papering over the above and it also has the added advantage that I can
assert that it's being held when doing a parent device transmit.
I'll look at splitting the locks out a bit more later on.
General outstanding net80211 TX path issues / TODO:
* Look into separating out the VAP serialisation and the IC handoff.
It's going to be tricky as parent->if_transmit() doesn't give me the
opportunity to split queuing from driver dispatch. See above.
* Work with monthadar to fix up the mesh transmit path so it doesn't go via
the parent interface when retransmitting frames.
* Push the encryption handling back into the driver, if it's at all
architectually sane to do so. I know it's possible - it's what mac80211
in Linux does.
* Make ieee80211_raw_xmit() queue a frame into VAP or parent queue rather
than doing a short-cut direct into the driver. There are QoS issues
here - you do want your management frames to be encapsulated and pushed
onto the stack sooner than the (large, bursty) amount of data frames
that are queued. But there has to be a saner way to do this.
* Fragments are still broken - drivers need to be upgraded to an if_transmit()
implementation and then fragmentation handling needs to be properly fixed.
Tested:
* STA - AR5416, AR9280, Intel 5300 abgn wifi
* Hostap - AR5416, AR9160, AR9280
* Mesh - some testing by monthadar@, more to come.
* The following bit flags where incroccetly defined:
o Mesh Control Present
o Mesh Power Save Level
o RSPI
This is now corrected according to Table 8.4 as per IEEE 802.11 2012;
Approved by: adrian (mentor)
since the former is defined everywhere. This cuts off some code not
necessary on non strict aligment arches.
Reviewed by: adrian
Sponsored by: Nginx, Inc.
* Add the superg.h header to allow ieee80211_check_ff() to work
* Since the assert stuff creates assertions based on line numbers and there
was a conflict, just nudge things down a bit.
* Added hwmp_update_transmitter function that checks if the metric
to the transmitter have improved. If old FI is invalid or metric
is larger the FI to the transmitter is updated occurdingly.
This is a recommendation from the 802.11 2012 standard, table 13-9;
Approved by: adrian (mentor)
* When calling ieee80211_mesh_rt_flush_peer, the rt->rt_dest argument
should not be passed because it can get freed before invalidating
the other routes that depends on it to compare with next_hop.
Use PERR_DADDR(i) instead;
Approved by: adrian (mentor)
* The standard is unclear about what should happen in case a mesh STA (not
marked as a mesh gate) recevies a PREQ for a destination that is marked
as proxy. Solution for now is not to do intermediate reply at all, and
let the PREQ reach the mesh gate;
Approved by: adrian (mentor)
* Original PREP frame is transmitted only by the target mesh STA or the
mesh STA that is the proxy target;
* Fixed so that metric value is not over written incorrectly in
hwmp_recv_preq for when replying back with a PREP;
Approved by: adrian (mentor)
This is a code re-write. ic->raw_xmit need a pointer to ieee80211_node
for the destination node (da). I have reorganized the code so that
a pointer to the da node is searched for in the end & in one place.
* Make mesh_find_txnode public to be used by HWMP, renamed to
ieee80211_mesh_finx_txnode;
* changed the argument from ieee80211_node to ieee80211vap for all
hwmp_send_* functions;
* removed the 'sa' argument from hwmp_send_* functions as all HWMP frames
have the source address equal to vap->iv_myaddr;
* Modified hwmp_send_action so that if da is MULTCAST ni=vap->iv_bss
otherwise we called ieee80211_mesh_find_txnode. Also no need to hold
a reference in this functions if da is not MULTICAST as by finding the
node it became referenced in ieee80211_find_txnode;
Approved by: adrian (mentor)
* Modified mesh_find_txnode to be able to handle proxy marked entries by
recursively calling itself to find the txnode towards the active mesh gate;
* Mesh Gate: Added a new function that transmits data frames
similar to ieee80211_start;
* Modified ieee80211_mesh_forward_to_gates so that:
+ Frames are duplicated and sent to each valid Mesh Gate;
+ Route is marked invalid before return of function, this is
because we dont know yet which Mesh Gate is we will use;
Approved by: adrian (mentor)
* Send frames that have no path to a known valid Mesh Gate;
* Added the function ieee80211_mesh_forward_to_gates that sends the frame
to the first found Mesh Gate in the forwarding information;
* If we try to discover again while we are discovering queue frame,
the discovery callout will send the frames either to mesh gates
or discards them silently;
* Queue frame also if we try to discover to frequently;
Approved by: adrian (mentor)
* Add function ieee80211_mesh_mark_gate in ieee80211_mesh.h;
* When received a proactive PREQ or RANN with corresponding mesh gate
flag set, create a new entry in the known mesh gate list;
Approved by: adrian (mentor)
* Modified mesh_recv_action_meshgate to do following:
+ if mesh STA already knows the mesh gate of the recevied GANN frame
+ if mesh gate is know, check seq number according to 802.11 standard
+ if mesh gate is not know, add it to the list of known mesh gates
+ if forwarding is enabled and ttl >= 1 then propagate the GANN frame;
* Declare a new malloc type M_80211_MESH_GT_RT;
* Declare a struct to store GANN information, ieee80211_mesh_gate_route. And
add it as a TAILQ list to ieee80211_mesh_state;
Approved by: adrian (mentor)
A Mesh Gate should transmit a Mesh Action frame containing
ieee80211_meshgann_ie as its only information element periodically
every ieee80211_mesh_gateint ms. Unless the mesh gate is also configure
as a ROOT, then these frames should not be send.
This is according to 802.11 2012 standard;
* Introduce new SYSCTL net.wlan.mesh.gateint, with 10s default;
* Add two new functions mesh_gatemode_setup and mesh_gatemode_cb. This
is similar to how HWMP setups up a callout;
* Add two new action handlers mesh_recv_action_meshgate and
mesh_send_action_meshgate;
* Added ieee80211_add_meshgate to ieee80211_mesh.h;
* Modified mesh_send_action to look similar to hwmp_send_action. This is
because we need to send out broadcast management frames.
* Introduced a new flag for mesh state IEEE80211_MESHFLAGS_ROOT. This flag
is now set by HWMP code when a mesh STA is configured as a ROOT. This
is then checked by mesh_gatemode_cb before scheduling a new callout;
* Added to new field to ieee80211_mesh_state:
+ struct callout ms_gatetimer
+ ieee80211_mesh_seq ms_gateseq;
Approved by: adrian (mentor)
when not peered.
* Modified ieee80211_recv_action to check if neighbour is peered for
IEEE80211_ACTION_CAT_MESH frames, if not frame is discarded. This is
according to IEEE802.11 2012 standard;
* Removed duplicate checks in each hwmp_recv_* handlers because HWMP
is a subtype of mesh action;
Approved by: adrian (mentor)
* Removed meshlm_send_action and hwmp_send_action. Introduced one common
for all Mesh Action frames meshaction_send_action. According to 802.11
standard Link Metric and HWMP are all under Mesh Action category;
* Did similar changes to recv_action part;
* The size of meshaction_*_action is set to 12. This is to make room for
the rest of Mesh Action category subtypes;
Approved by: adrian (mentor)
* Change all field prefix from pann_ to gann_;
* Added IEEE80211_MESHGANN_BASE_SZ macro to be used in the length field
of a GANN frame according to 802.11 standard;
* Changed gann_seq field type to uint32_t;
* Added a Gate Announcement interval field according to
IEEE802.11 2012 standard;
* Added IEEE80211_MESHRT_FLAGS_GATE as flag bit to ieee80211_mesh_route;
* Added IEEE80211_MESHRT_FLAGS_GATE as flag bit to ieee80211req_mesh_route;
Approved by: adrian (mentor)
* An HWMP PERR should be accepted even if path is valid. Because
we check if we recevied it from a neighbour that we use as a next hop;
Approved by: adrian (mentor)
* A bug occurs while in discovery mode which leaves a path marked with
both Discover and Valid flag. This happens when receiving/sending
PREQ and PREP in a particular order. Solution is to assign the Valid bit
instead of oring it;
Approved by: adrian (mentor)
This problem happens when using ACL policy to filter mesh STA
but two nodes have different policy. Then one of them will try to
peer all the time. This can also help if for any reason one of the
peering mesh STA have problems sending/receiving peer frames.
* Modified struct ieee80211_node to include two new fields:
+ struct callout ni_mlhtimer /* link mesh backoff timer */
+ uint8_t ni_mlhcnt /* link mesh holding counter */
* Added two new sysctl (check sysctl -d for more info):
+ net.wlan.mesh.backofftimeout=5000
+ net.wlan.mesh.maxholding=2;
* When receiving a beacon and we are in IEEE80211_NODE_MESH_IDLE
check if ni_mlhcnt >= ieee80211_mesh_maxholding, if so do not do anything;
* In mesh_peer_timeout_cb when transitioning from IEEE80211_NODE_MESH_HOLDING
to IEEE80211_NODE_MESH_IDLE increment ni_mlhcnt, and eventually start
ieee80211_mesh_backofftimeout;
Approved by: adrian (mentor)
* Add HTINFO field decoding to ieee80211_ies_expand() - it's likely not
100% correct as it's not looking at the draft 11n HTINFO location,
but I don't think anyone will care.
* When doing an IBSS join make sure the 11n channel configuration
is used - otherwise the 11a/11bg channel will be used
and there won't be any chance for an upgrade to 11n.
* When creating an IBSS network, ensure the channel is updated to an
11n channel so other 11n nodes can see it and speak to it with MCS
rates.
* Add a bit of code that's disabled for now which handles the HT
field updating. This won't work out very well with lots of adhoc
nodes as we'd end up ping-ponging between the HT configuration for
each node. Instead, we should likely only pay attention to the
"master" node we initially associated against and then ensure we
propagate that information forward in our subsequent beacons. However,
due to the nature of IBSS (ie, there's no specific "master" node in
the specification) it's unclear which node we should lift the HT
parameters from.
So for now this assumes the HT parameters are squirreled away in the
initial beacon/probe response.
So there's some trickiness here.
With ap/sta pairing, the probe response just populates a legacy node
and the association request/response is what is used for negotiation
11n-ness (and upgrading things as needed.)
With ibss networks, the pairing is done with probe request/response,
with discovery being done by creating nodes when new beacons in the
IBSS / BSSID are heard. There's no assoc request/response frames going on.
So the trick here has been to figure out where to upgrade things.
I don't like how I just taught ieee80211_sta_join() to "speak" HT -
I'd rather there be an upgrade path when an IBSS node joins and there
are HT parameters present. Once I've done that, I'll kill this
HT special casing that's going on in ieee80211_sta_join().
Tested:
* AR9280, AR5416, AR5212 - basic iperf and ping interoperability tests
whilst in a non-encrypted adhoc network.
TODO:
* Fix up the HT upgrade path for IBSS nodes rather than adding code
in ieee80211_sta_join(), then remove my code from there.
* When associating, there's a concept of a "master" node in the IBSS
which is the node you first joined the network through. It's possible
the correct thing to do is to listen to HT updates and configure WME
parameters from that node. However, once that node goes away, which
node(s) should be listened to for configuration changes?
For things like HT channel width, it's likely going to be ok to
just associate as HT40 and then use the per-neighbor rate control
and HTINFO/HTCAP fields to figure out which rates and configuration
to speak. Ie, for a 20MHz 11n node, just speak 20MHz rates to
it. It shouldn't "change", like what goes on in AP/STA configurations.
save queue code.
Instead, use if_transmit() directly - and handle the cases where frame
transmission fails.
I don't necessarily like this and I think at this point the M_ENCAP check,
node freeing upon fail and the actual if_transmit() call should be done
in methods in ieee80211_freebsd.c, but I digress slightly..
This removes one of the last few uses of if_start() and the ifnet
if_snd queue. The last major offender is ieee80211_output.c, where
ieee80211_start() implements if_start() and uses the ifnet queue
directly.
(There's a couple of gotchas here, where the if_start pointer is
compared to ieee80211_start(), but that's a later problem.)
If the data frame transmission failures, it may have a node reference
that needs cleaning up.
If the frame is marked as M_ENCAP then it should treat recvif as a node
reference and clear it.
Now - since the mbuf has been freed by calling if_transmit() (even on
failure), the mbuf has to be treated as invalid. Hence why the ifp is
used.
If if_transmit() fails, the node ref may need freeing.
This is based on the same logic used by the ageq, which the mesh code
(re) uses for frames which need to be staged before transmitting.
It also does the same thing - if M_ENCAP is set on the mbuf, it treats
the recvif pointer as a node reference and derefs it.
processing. For if_transmit() style hardware drivers (which none publicly
exist yet, for wireless) they will need to still implement if_start()
but only to re-start the TX queue.
an IBSS VAP to RUN.
An 11n IBSS was beaconing HTINFO/HTCAP IE's that didn't have any HT
information setup (like the HT TX/RX MCS bitmask.)
Tested:
* AR9280, IBSS - both a statically setup channel and a scanned channel
PR: kern/172955
parameters in IBSSes.
IBSS was just being plainly ignored here even though aggressive mode
was 'on'.
This still doesn't fix the "why are the WME parameters reset upon
interface down/up" issue.
PR: kern/165969
is totally wrong.
If we parse the WME IE here, we'll be constantly updating the WME
configuration from each WME enabled IBSS node we see.
There's a separate issue where the WME configuration is blanked out
when the interface is brought up; the WME parameters aren't "sticky."
Also, ieee80211_init_neighbor() parses the ath IE, so doing it here
isn't required.
Sorry about the noise.
PR: kern/165969
The Adhoc support wasn't parsing and handling the ath specific and WME
IEs, thus the atheros vendor support and WME TXOP parameters aren't being
copied from the peer.
It copies the WME parameters from whichever adhoc node it decides to
associate to, rather than just having them be statically configured
per adhoc node. This may or may not be exactly "right", but it's certainly
going to be more convienent for people - they just have to ensure their
adhoc nodes are setup with correct WME parameters.
Since WME parameters aren't per-node but are configured on hardware TX
queues, if some nodes support WME and some don't - or perhaps, have
different WME parameters - things will get quite quirky.
So ensure that you configure your adhoc nodes with the same WME
parameters.
Secondly - the Atheros Vendor IE is parsed and operated on per-node, so
this should work out ok between nodes that do and don't do Atheros
extensions. Once you see a becaon from that node and you setup the
association state, it _should_ parse things correctly.
TODO:
* I do need to ensure that both adhoc setup paths are correctly updating
the IE stuff. Ie, if the adhoc node is created by a data frame instead
of a beacon frame, it'll come up with no WME/ath IE config. The next
beacon frame that it receives from that node will update the state.
I just need to sit down and better understand how that's suppose to
work in IBSS mode.
Tested:
* AR5416 <-> AR9280 - fast frames and the WME configuration both popped
up. (This is with a local HAL patch that enables the fast frames
capability on the AR5416 chipsets.)
PR: kern/165969
The stageqdepth (global, over all staging queues) was being kept
incorrectly. It was being incremented whenever things were added,
but only decremented during a flush. During active fast frames activity
it wasn't being decremented, resulting in it always having a non-zero
value during normal fast-frames operation.
It was only used when checking if the aging queue should be checked;
we may as well just defer to each of those staging queue counters (which
look correct, thankfully.)
Whilst I'm here, add locking assertions in the staging queue add/remove
functions. The current crash shows that the staging queue has one frame,
but only has a tail pointer set (the head pointer being set to NULL.)
I'd like to grab a few more crashes where these locking assertions are
in place so I can narrow down the issue between "somehow locking is
messed up and things are racy" and "the stage queue head/tail pointer
manipulation logic is subtly wrong."
Tested:
* AR5416 STA, AR5413 AP; with FastFrames enabled in the AR5416 HAL.
PR: kern/174283
pointers and leave the stage queue flush routine to just do nothing
(since both head and tail here will be NULL.)
This should quieten the "stageq empty" panic where the stageq itself
is empty, but it won't fix the second KASSERT() here "staging queue empty"
as that's likely a different underlying problem.
PR: kern/174283
The XC900M acts as a Ubiquiti XR9 (and I _think_ SR9) by default;
it uses the same 900MHz<->2.4GHz downconverter mapping.
However it has an alternative frequency mapping which squeezes in a couple
more half/quarter rate channels. Since the default HAL doesn't support
fractional tuning (sub-1MHz) in 2.4GHz mode on the AR5413/AR5414, they
implement it using a jumper.
Datasheet: http://www.xagyl.com/download/XC900M_Datasheet.pdf
Thankyou to Xagyl Communications for the XC900M NICs and Edgar Martinez
for organising the donation.
Tested:
* XC900M <-> XC900M
* Ubiquiti XR9 <-> XC900M
TODO:
* Test against SR9 and GZ901 if possible (the IEEE channel<->frequency
mapping may not match up, thanks to the slightly different channels
involved)