Re: [tsvwg] draft-ietf-tsvwg-nqb, more questions

["Black, David" <David.Black@dell.com>]

Greg,

I will look at the proposed text in more detail later - this is a quick response to say that I agree with the comments that precede the proposed text, and especially that I agree with this:

> Also, I think the remedies available in this situation include more than just
> rate limiting (and other remedies may be preferred in some cases), so I
> would not want to make it a MUST that rate limiting be employed.

I definitely agree that if there are multiple possible remedies, then it is better to apply the "MUST" to "solve the problem" as opposed to mandating the specific remedy of rate limiting.

Thanks, --David

> -----Original Message-----
> From: Greg White <g.white@CableLabs.com>
> Sent: Saturday, November 9, 2019 2:02 PM
> To: Black, David
> Cc: tsvwg IETF list; Sebastian Moeller
> Subject: Re: [tsvwg] draft-ietf-tsvwg-nqb, more questions
> 
> 
> [EXTERNAL EMAIL]
> 
> David,
> 
> Thanks for these suggestions.  I agree that rate limiting aggregate NQB traffic
> could be an approach to address the concern.
> 
> It seems to me that this concern exists only for existing residential WiFi
> networks, which do not support the NQB PHB, are known to treat 0x2A as
> higher priority than the 0x1* and 0x0* DSCPs, and are unlikely to have other
> means of re-marking traffic before it hits the WiFi link.  For interconnections
> with another AS, the recommendations in Section 2.3.4.2 of RFC 2475 and
> Section 4.1 of RFC 2474 (unrecognized DSCPs) should be sufficient.
> 
> On that basis, I think that any such text would be placed in the section on
> existing WiFi (which, in retrospect, I should not have put in the PHB "Use
> Cases" section of the draft, but rather as a separate "Interoperability ..."
> section, to avoid confusion).
> 
> Also, I think the remedies available in this situation include more than just
> rate limiting (and other remedies may be preferred in some cases), so I
> would not want to make it a MUST that rate limiting be employed.
> 
> I've taken a stab at some text below.
> 
> 
> 
> 8. Interoperability with WiFi Networks
> 
>    WiFi networking equipment compliant with 802.11e generally supports
>    either four or eight transmit queues and four sets of associated EDCA
>    parameters (corresponding to the four WiFi Multimedia Access
>    Categories) that are used to enable differentiated media access
>    characteristics.  Implementations typically utilize the IP DSCP field
>    to select a transmit queue, but should be considered as Non-
>    Differentiated Services-Compliant Nodes as described in Section 4 of
>    [RFC2475].  As a result this document discusses interoperability with
>    WiFi networks, as opposed to PHB compliance.
> 
>    As discussed in [RFC8325], most existing implementations use a
>    default DSCP to User Priority mapping that utilizes the most
>    significant three bits of the DiffServ Field to select "User
>    Priority" which is then mapped to the four WMM Access Categories.  In
>    order to increase the likelihood that NQB traffic is provided a
>    separate queue from QB traffic in existing WiFi equipment, the 0x2A
>    codepoint is preferred for NQB.  This would map NQB to UP_5 which is
>    in the "Video" Access Category.
> 
>    Systems that utilize [RFC8325], SHOULD map the NQB codepoint to UP_5
>    in the "Video" Access Category.
> 
>    WMM systems, by default, are configured to provide statistically prioritized
> channel access for the four Access Categories, with "Voice" being given
> highest priority, followed by "Video", "Best Effort" and "Background".  Since
> prioritization of NQB traffic over QB traffic is contrary to the requirements of
> the NQB PHB and could erode the principle of incentive alignment, care
> needs to be taken in introducing NQB-marked traffic into such networks.
> One remedy is to configure the EDCA parameters for the Video Access
> Category to match those of the Best Effort Access Category, thus giving the
> two queues statistically equal access to the channel.  Another remedy is to
> limit the amount of traffic that is allowed to be marked as NQB, such as to
> ensure that it does not monopolize airtime to the detriment of QB traffic.   In
> situations where a network operator is introducing aggregate traffic into a
> network that is known or presumed to be utilizing WMM-enabled WiFi, the
> operator MUST employ a remedy to ensure that QB traffic is not
> disadvantaged.
> 
> 
> 
> 
> 
> 
> 
> 
> 
> On 11/8/19, 4:43 PM, "Black, David" <David.Black@dell.com> wrote:
> 
>     Looks like progress - more inline ...
> 
>     Thanks, --David
> 
>     > -----Original Message-----
>     > From: Sebastian Moeller <moeller0@gmx.de>
>     > Sent: Friday, November 8, 2019 6:23 PM
>     > To: Black, David
>     > Cc: Greg White; tsvwg IETF list
>     > Subject: Re: [tsvwg] draft-ietf-tsvwg-nqb, more questions
>     >
>     >
>     > [EXTERNAL EMAIL]
>     >
>     > Hi David,
>     >
>     >
>     > > On Nov 8, 2019, at 20:56, Black, David <David.Black@dell.com> wrote:
>     > >
>     > > Hi Greg,
>     > >
>     > > Backing up a few messages, I might have found a way out of this
> debate.
>     > Sebastian wrote:
>     > >
>     > >>    	[SM] Sorry with source, I was not talking about individual
> senders,
>     > >> but about the "NQB/L4S complex" that I expect to cause a lot of NQB
> marked
>     > >> traffic to appear on the ingress side of home users once it gets off the
>     > >> ground.
>     > >
>     > > That specific situation appears to be straightforward to address
> because
>     > the edge of the ISP network that supports Diffserv is involved.
> Specifically,
>     > the specification of the NQB PHB ought to include text to the effect that
>     > outbound NQB-marked traffic MUST be rate limited at the egress from
> the
>     > Diffserv domain/region if the downstream (receiving) network is not
> known
>     > to support NQB (this is not the precise language, but should convey the
>     > concept).
>     >
>     > 	[SM] I like this idea, I just wonder how that is going to work in the
>     > light of highly variable transmit rates on wifi links? IMHO AP & stations are
> in
>     > a better position to meaningfully rate limit than any upstream element.
> 
>     [David>] Apply a generous "fudge factor" so that the NQB rate limit is well
> short of any rate that could cause trouble.  My initial sense is that this NQB
> rate limit limit is a safety limit that does not have an optimization goal, so the
> rate can be set well short of transmission rates that have a reasonable
> possibility of causing trouble.  As part of, this, I'm hoping that there's limited
> downside to remarking more NQB traffic to Default (best effort) than
> necessary in this situation.  I understand that the WiFi AP/station would be a
> more effective location for this sort of functionality, but in this situation, we
> are able specify the functionality of the immediate upstream ISP element,
> but not the well-worn WiFi AP that the user bought on eBay last week.
> 
>     I would leave configuration of NQB rate limits to network operators.  Also,
> in extremis, zero is always a safe NQB egress rate ;-), so would it help to
> require that the NQB egress rate be configurable to zero?
> 
>     >
>     >
>     > > In the reverse direction rate limiting NQB traffic on ingress (or outright
>     > bleaching it to best effort if the subscriber should not be using NQB in the
>     > first place) seems like a good idea, and may rise to the level of a MUST
>     > requirement if the NQB-supporting  network that the traffic is entering
> does
>     > not implement traffic protection for the NQB "queue" at each network
> node.
>     > With a little creativity, the necessary rate limiting might be able to take
>     > advantage of an NQB queue protection mechanism if one is present at
> the
>     > Diffserv edge.
>     > >
>     > > The individual sender situation appears to be of less concern, as at least
> in
>     > this case it looks like an instance of:
>     > >
>     > > 	If you point the gun at your own foot and pull the trigger, do not ask
>     > where the hole in your foot came from.
>     > >
>     > > As, at least for the home user, the result is only to damage her own
> WiFi
>     > network, particularly if the ISP ingress node protects its network from the
>     > user sending too much NQB-marked traffic.
>     > >
>     > > Thanks, --David
>     > >
>     > >> -----Original Message-----
>     > >> From: tsvwg <tsvwg-bounces@ietf.org> On Behalf Of Greg White
>     > >> Sent: Thursday, November 7, 2019 7:45 PM
>     > >> To: Sebastian Moeller
>     > >> Cc: tsvwg IETF list
>     > >> Subject: Re: [tsvwg] draft-ietf-tsvwg-nqb, more questions
>     > >>
>     > >>
>     > >> [EXTERNAL EMAIL]
>     > >>
>     > >> It seems as if you are arguing from religious grounds.   There is no
>     > "NQB/L4S
>     > >> complex" that is nefariously seeking to saturate your home network.
>     > >>
>     > >> So, I will try to ask the question again.
>     > >>
>     > >> If the policy that gets written into the RFC is that NQB traffic should
> not be
>     > >> high data rate traffic, then this achieves your objective?  If we include
> a
>     > >> paragraph like that which exists in RFC 8325 that explains why, in the
> case
>     > of
>     > >> WiFi networks, it should not be high data rate traffic, would that be
>     > >> sufficient?
>     > >>
>     > >> -Greg
>     > >>
>     > >>
>     > >> On 11/7/19, 5:09 PM, "Sebastian Moeller" <moeller0@gmx.de>
> wrote:
>     > >>
>     > >>
>     > >>
>     > >>> On Nov 8, 2019, at 00:20, Greg White <g.white@CableLabs.com>
> wrote:
>     > >>>
>     > >>> You've still missed the point.
>     > >>>
>     > >>>   	[SM] It will keep one expected major source of DSCP marked
> traffic
>     > >> on a sane(r) policy.
>     > >>>
>     > >>> No. It won't.
>     > >>>
>     > >>> What will keep that source on a sane policy is that they have an
> interest
>     > >> in having a sane policy.  This IETF draft does not create that interest,
> nor
>     > >> would it prevent them from running amok.
>     > >>>
>     > >>> -Greg
>     > >>
>     > >>    	[SM] Sorry with source, I was not talking about individual
> senders,
>     > >> but about the "NQB/L4S complex" that I expect to cause a lot of NQB
>     > marked
>     > >> traffic to appear on the ingress side of home users ionce it gets off the
>     > >> ground. And my point is very much to give my best arguments to
> make
>     > sure
>     > >> you do not end up writing a bad policy into an RFC. What ever you do
> in
>     > the
>     > >> real world is outside of the scope of the IETF, but taking that as an
>     > argument
>     > >> in favor of bad engineering is simply a bad argument.
>     > >>    	And regarding your interpretation of individual senders, it is
> clear that
>     > >> remote senders have a snowballs chance in hell to react timely to the
>     > >> variable bitrates on a wifi segment, hence the wifi elements AP (and
>     > ideally
>     > >> STAs) will need to enforce sanity and make sure tp avoid starvation.
> This is
>     > >> not a new requirement, but the status quo is that most traffic is
> AC_BE, so
>     > >> the lack of enforcement was sort of tolerable; but either NQB withers
>     > away
>     > >> and will not be used (and all of this discussion does not matter) or it
> will be
>     > >> used and then you better make sure that NQB will not be found out as
> a
>     > >> reason why non-NQB on-line gaming starts to suck. But really looking
> at
>     > the
>     > >> AC stats from my laptop:
>     > >>
>     > >>    laptop:~ user$ sudo netstat -I en0 -qq
>     > >>    en0:
>     > >>         [ sched:  FQ_CODEL  qlength:    0/128 ]
>     > >>         [ pkts:          0  bytes:          0  dropped pkts:    185 bytes:  55724 ]
>     > >>
> =====================================================
>     > >>         [ pri: VO (1)	srv_cl: 0x400180	quantum: 600	drr_max: 8 ]
>     > >>         [ queued pkts: 0	bytes: 0 ]
>     > >>         [ dequeued pkts: 171322	bytes: 15967234 ]
>     > >>         [ budget: 0	target qdelay: 10.00 msec	update
>     > interval:100.00 msec ]
>     > >>         [ flow control: 0	feedback: 0	stalls: 0	failed: 0 ]
>     > >>         [ drop overflow: 0	early: 0	memfail: 0	duprexmt:0 ]
>     > >>         [ flows total: 0	new: 0	old: 0 ]
>     > >>         [ throttle on: 0	off: 0	drop: 0 ]
>     > >>
> =====================================================
>     > >>         [ pri: VI (2)	srv_cl: 0x380100	quantum: 3000	drr_max: 6 ]
>     > >>         [ queued pkts: 0	bytes: 0 ]
>     > >>         [ dequeued pkts: 1081254	bytes: 95307849 ]
>     > >>         [ budget: 0	target qdelay: 10.00 msec	update
>     > interval:100.00 msec ]
>     > >>         [ flow control: 0	feedback: 0	stalls: 0	failed: 0 ]
>     > >>         [ drop overflow: 0	early: 0	memfail: 0	duprexmt:0 ]
>     > >>         [ flows total: 0	new: 0	old: 0 ]
>     > >>         [ throttle on: 0	off: 0	drop: 0 ]
>     > >>
> =====================================================
>     > >>         [ pri: BE (7)	srv_cl: 0x0	quantum: 1500	drr_max: 4 ]
>     > >>         [ queued pkts: 0	bytes: 0 ]
>     > >>         [ dequeued pkts: 41792980	bytes: 10120070005 ]
>     > >>         [ budget: 0	target qdelay: 10.00 msec	update
>     > interval:100.00 msec ]
>     > >>         [ flow control: 9	feedback: 9	stalls: 8	failed: 0 ]
>     > >>         [ drop overflow: 0	early: 5	memfail: 0	duprexmt:0 ]
>     > >>         [ flows total: 0	new: 0	old: 0 ]
>     > >>         [ throttle on: 0	off: 0	drop: 0 ]
>     > >>
> =====================================================
>     > >>         [ pri: BK (8)	srv_cl: 0x100080	quantum: 1500	drr_max: 2 ]
>     > >>         [ queued pkts: 0	bytes: 0 ]
>     > >>         [ dequeued pkts: 4392109	bytes: 1258595132 ]
>     > >>         [ budget: 0	target qdelay: 10.00 msec	update
>     > interval:100.00 msec ]
>     > >>         [ flow control: 2	feedback: 2	stalls: 2	failed: 0 ]
>     > >>         [ drop overflow: 0	early: 0	memfail: 0	duprexmt:0 ]
>     > >>         [ flows total: 0	new: 0	old: 0 ]
>     > >>         [ throttle on: 0	off: 0	drop: 0 ]
>     > >>
>     > >>
>     > >>
>     > >>
>     > >>    and my OpenWrt router:
>     > >>
>     > >>    root@router:~# cat /sys/kernel/debug/ieee80211/phy1/ath9k/xmit
>     > >>                                BE         BK        VI        VO
>     > >>
>     > >>    MPDUs Queued:             4933        120       595     47628
>     > >>    MPDUs Completed:          2765        331      1045    110627
>     > >>    MPDUs XRetried:           2792         30       381       216
>     > >>    Aggregates:            4053416     109096     11152         0
>     > >>    AMPDUs Queued HW:            0          0         0         0
>     > >>    AMPDUs Completed:     29761018     931822    280598         0
>     > >>    AMPDUs Retried:         484203      23327      4543         0
>     > >>    AMPDUs XRetried:          8606        149       754         0
>     > >>    TXERR Filtered:             97          7        32        37
>     > >>    FIFO Underrun:               0          0         0         0
>     > >>    TXOP Exceeded:               0          0         0         0
>     > >>    TXTIMER Expiry:              0          0         0         0
>     > >>    DESC CFG Error:              0          0         0         0
>     > >>    DATA Underrun:               0          0         0         0
>     > >>    DELIM Underrun:              0          0         0         0
>     > >>    TX-Pkts-All:          29775181     932332    282778    110843
>     > >>    TX-Bytes-All:        672115293 1008162267 199579558  20417055
>     > >>    HW-put-tx-buf:               8          8         8         8
>     > >>    HW-tx-start:          21266021     570626    256944    110799
>     > >>    HW-tx-proc-desc:      21266026     570629    257004    110839
>     > >>    TX-Failed:                   0          0         0         0
>     > >>
>     > >>
>     > >>    Summary packet numbers:
>     > >>    AC	Laptop
>     > >>    BE:		 41792980	29775181
>     > >>    BK:		   4392109	    932332
>     > >>    VI:		   1081254	    282778
>     > >>    VO:		     171322	    110843
>     > >>    Total:	 47437665	31101134
>     > >>
>     > >>
>     > >>    So my status quo is that all four AC are used with the fraction of
>     > >> AC_VI+AC_VO at
>     > >>    100*(1081254+ 171322)/47437665 = 2.6 % (laptop)
>     > >>    100*(282778 + 110843)/31101134 = 1.3 % (router)
>     > >>
>     > >>    This is with relative high streaming media usage.
>     > >>
>     > >>
>     > >>    Best Regards
>     > >>    	Sebastian
>     > >>
>     > >>
>     > >>
>     > >>
>     > >>
>     > >>
>     > >>>
>     > >>>
>     > >>>
>     > >>> On 11/7/19, 4:12 PM, "Sebastian Moeller" <moeller0@gmx.de>
> wrote:
>     > >>>
>     > >>>   Hi Greg,
>     > >>>
>     > >>>
>     > >>>> On Nov 7, 2019, at 23:44, Greg White <g.white@CableLabs.com>
> wrote:
>     > >>>>
>     > >>>> Sebastian,
>     > >>>>
>     > >>>> I agree that this isn't rocket science.  In the existing WiFi systems
> that
>     > >> we're discussing, there are 16 DSCPs that get mapped to AC_VI, and
> 16
>     > >> DSCPs that get mapped to AC_VO.   No one polices any of them in
>     > residential
>     > >> WiFi networks!  There is nothing that prevents anyone from writing an
>     > >> application today that sends bulk traffic marked as CS7 (a value that
> the
>     > IETF
>     > >> considers to be reserved).
>     > >>>
>     > >>>   	[SM] Sure, but thanks to ISP often bleaching DSCPs there
> currently is
>     > >> very little in and outgoing traffic that actually maps to anything but
> AC_BE,
>     > >> you propose to change that in a major way, with your attempt at
> making
>     > NQB
>     > >> end to end (with one end potentially being in a close data center with
> an
>     > SLA
>     > >> allowing for NQB survival). Just because no one has massively abused
> this
>     > so
>     > >> far, is NOT a justification to do so now.
>     > >>>
>     > >>>
>     > >>>>
>     > >>>> I believe that the reason that RFC 8325 simply wrings its hands over
> this
>     > >> issue, as opposed to solving it, is that A) it is a *really* hard problem to
>     > solve
>     > >> in an unmanaged network, and B) while it is certainly a problem in
> theory,
>     > >> there is no evidence that it is a real problem in practice.
>     > >>>
>     > >>>   	[SM] The problem is that there is simply no data, and
> interpreting this
>     > >> as there is no problem is neither solid science nor engineering. If you
> have
>     > >> measurements showing that this is no problem with the expected
> traffic
>     > >> rates with the NQB marking, please feel free to post them to the list
> or as
>     > >> PM.
>     > >>>
>     > >>>>
>     > >>>>
>     > >>>> Blocking the IETF from assigning NQB the 0x2A value does
> *nothing* to
>     > >> prevent an application from using 0x2A (or any of the other 31 code
> points
>     > >> that you are concerned about) for *any* purpose that the application
>     > >> developer sees fit, it does *nothing* to prevent a network operator
> from
>     > >> using 0x2A for NQB traffic, and it does *nothing* to help solve the
> main
>     > issue
>     > >> that you are concerned about.
>     > >>>
>     > >>>   	[SM] It will keep one expected major source of DSCP marked
> traffic
>     > >> on a sane(r) policy. Most users and applications do not bother paying
> with
>     > >> dscps so the current amount of abuse is limited (and if I configure my
>     > internal
>     > >> skype and ssh applications to even use AC_VO I can control their
> activity
>     > and
>     > >> usage much better than I can traffic rushing in from the internet). Sure
> I
>     > can
>     > >> re-map 0x2A to a sane value on ingress to my network, but that is not
>     > going
>     > >> to help that much if my neighbors do not do this, and their APs start
>     > hogging
>     > >> all tx_ops on the shared channel.
>     > >>>
>     > >>>>
>     > >>>> If you want to solve this problem, my suggestion is that you start a
> new
>     > >> draft proposing a technology that will holistically protect WiFi
> networks
>     > from
>     > >> all potential DSCP abuses.
>     > >>>
>     > >>>   	[SM] First rule of holes, put the shovel away when you find
> yourself
>     > >> inside one. Here, I am not concerned so much in fixing all wifi AC
> abuse
>     > and
>     > >> more in giving my best to avoid this unfortunate and undesirable
>     > condition
>     > >> getting worse.
>     > >>>
>     > >>>
>     > >>>
>     > >>>   Sebastian
>     > >>>
>     > >>>
>     > >>>
>     > >>>>
>     > >>>> Greg
>     > >>>>
>     > >>>>
>     > >>>>
>     > >>>>
>     > >>>> On 11/7/19, 3:00 PM, "Sebastian Moeller" <moeller0@gmx.de>
> wrote:
>     > >>>>
>     > >>>>  Greg,
>     > >>>>
>     > >>>>> On Nov 7, 2019, at 22:11, Greg White <g.white@CableLabs.com>
>     > >> wrote:
>     > >>>>>
>     > >>>>> Sebastian,
>     > >>>>>
>     > >>>>> In the interest of moving this forward and not going in circles,
>     > >>>>
>     > >>>>  	[SM] My impression is not that we going in circles, it is a
> rather slow
>     > >> road to understanding and accepting the properties and limitations of
>     > wifi's
>     > >> unfortunate prioritization scheme in conjunction with your intended
> use
>     > of
>     > >> the NQB dscp. Me shutting up, would not change the underlaying
> facts
>     > that
>     > >> need to be considered here if the issue is to be solved.
>     > >>>>
>     > >>>>
>     > >>>>> I think you summarized your position as: "To be explicit, I do not
>     > object
>     > >> on principle to using AC_VI or even AC_VO as long as this does not eat
>     > >> significantly into the tx_ops for AC_BE, the current draft improves  in
> that
>     > >> direction. Would it be possible to make this point even stronger?"
>     > >>>>>
>     > >>>>> In my view, as long as the applications that we're recommending
> to be
>     > >> marked NQB are no more bandwidth intensive than video
> conferencing
>     > (the
>     > >> applications that the IETF already recommends be marked with a DSCP
>     > that
>     > >> maps to AC_VI), then we have achieved what is needed.  Do you
> agree?
>     > >>>>
>     > >>>>  	To state the obvious, "no more bandwidth intensive than
> video
>     > >> conferencing" is virtually meaningless as it will give very little guidance
> on
>     > >> acceptable either single flow nor aggregate NQB traffic share or
> absolute
>     > >> bandwidth (yes rfc8325 is also pretty silent on this, but "look mum, the
>     > other
>     > >> guys are doing it too" is not the best of defenses IMHO). I realize that
> this
>     > is
>     > >> an issue for you as you explicitly target NQB as requiring no
> prioritization
>     > or
>     > >> rate-limiting, I get that; but I believe that on wifi since you effectively
>     > >> propose to use a prioritization system you really really should require
>     > rate-
>     > >> limiting.
>     > >>>>
>     > >>>>  rfc8325, section 8.2:
>     > >>>>  "The wireless LAN presents a unique DoS attack vector, as
> endpoint
>     > >>>>     devices contend for the shared media on a completely egalitarian
>     > >>>>     basis with the network (as represented by the AP).  This means
> that
>     > >>>>     any wireless client could potentially monopolize the air by
> sending
>     > >>>>     packets marked to preferred UP values (i.e., UP values 4-7) in the
>     > >>>>     upstream direction.  Similarly, airtime could be monopolized if
>     > >>>>     excessive amounts of downstream traffic were marked/mapped
> to
>     > >> these
>     > >>>>     same preferred UP values.  As such, the ability to mark/map to
> these
>     > >>>>     preferred UP values (of UP 4-7) should be controlled.
>     > >>>>
>     > >>>>     If such marking/mapping were not controlled, then, for example,
> a
>     > >>>>     malicious user could cause WLAN DoS by flooding traffic marked
> CS7
>     > >>>>     DSCP downstream.  This codepoint would map by default (as
>     > >> described
>     > >>>>     in Section 2.3) to UP 7 and would be assigned to the Voice Access
>     > >>>>     Category (AC_VO).  Such a flood could cause Denial-of-Service to
> not
>     > >>>>     only wireless voice applications, but also to all other traffic
>     > >>>>     classes.  Similarly, an uninformed application developer may
> request
>     > >>>>     all traffic from his/her application be marked CS7 or CS6, thinking
>     > >>>>     this would achieve the best overall servicing of their application
>     > >>>>     traffic, while not realizing that such a marking (if honored by the
>     > >>>>     client operating system) could cause not only WLAN DoS, but also
> IP
>     > >>>>     network instability, as the traffic marked CS7 or CS6 finds its way
>     > >>>>     into queues intended for servicing (relatively low-bandwidth)
>     > >> network
>     > >>>>     control protocols, potentially starving legitimate network control
>     > >>>>     protocols in the process."
>     > >>>>
>     > >>>>  To me this clearly indicates that the achievable wifi rate betwnn AP
> and
>     > >> each station needs to be taken into account when considering which
>     > fraction
>     > >> of > AC_BE traffic is acceptable. So very much incompatible with your
> goal
>     > of
>     > >> having endpoints set the NQB dscp based on their own best
> assessment
>     > of
>     > >> traffic type without some sanitization at the AP level (only the AP will
>     > have a
>     > >> reasonable chance of predicting immediate achievable rates with
> some
>     > >> confidence, neither endpoints nor intermediate low latency queue
>     > enabled
>     > >> AQMs have sufficient knowledge to judge what traffic rate is
> acceptable
>     > for
>     > >> AC_VI). I consider it to be quite unfortunate that rfc8325 has no
>     > references
>     > >> to research on real-world data on the consequences of actually
> following
>     > >> through with its recommendations, nor that it has robust
>     > recommendations
>     > >> of recommended maximal fractions of the achievable rate each AC
> should
>     > be
>     > >> constrained to.
>     > >>>>
>     > >>>>  All of this is not really rocket science, and the obvious solution,
>     > >> following both the principle of least surprise and a "first, do no harm"
>     > maxim
>     > >> is to select the NQB dscp such that the unfortunate default DSCP to
> AC
>     > >> mappings keep NQB marked traffic in the AC_BE queue, UNLESS the
> AP is
>     > >> NQB-aware in which case the AP should be mandated to at least
> reliably
>     > >> avoid starvation of ACs.
>     > >>>>  The amount of back and forth seems to indicate that this is not an
>     > >> outcome you consider desirable.
>     > >>>>
>     > >>>>
>     > >>>>  Sebastian
>     > >>>>
>     > >>>>>
>     > >>>>> -Greg
>     > >>>>>
>     > >>>>>
>     > >>>>>
>     > >>>>>
>     > >>>>>
>     > >>>>> On 11/5/19, 1:58 AM, "Sebastian Moeller" <moeller0@gmx.de>
>     > wrote:
>     > >>>>>
>     > >>>>> Hi Greg,
>     > >>>>>
>     > >>>>>
>     > >>>>>> On Nov 5, 2019, at 01:28, Greg White <g.white@CableLabs.com>
>     > >> wrote:
>     > >>>>>>
>     > >>>>>> Hi Sebastian,
>     > >>>>>>
>     > >>>>>> Interoperability with existing WiFi equipment is an important
> aspect,
>     > >> since WiFi latency can be considerable. By default, many existing APs
> only
>     > >> support 4 priority queues, and thus it is not possible to meet all of the
>     > >> requirements of the NQB PHB (at least in this default configuration).
>     > >>>>>
>     > >>>>> 	[SM] I agree the question is how to deal with that
> "impedance
>     > >> mismatch".
>     > >>>>>
>     > >>>>>> Nonetheless, it is possible to utilize two of the four queues in
> order
>     > >> to meet some of the requirements, and thus provide some of the
>     > benefits of
>     > >> the NQB PHB.
>     > >>>>>
>     > >>>>> 	[SM] Unless you opt for selecting AC_BK for the NQB traffic,
> for most
>     > >> users the value of NQB will be mostly in the priority boost on wifi and
> the
>     > >> resulting air-time access advantage (which results in both lower
> latency
>     > and
>     > >> potentially higher bandwidth).
>     > >>>>>
>     > >>>>>> With proper configuration and/or policies, this can be done
> safely.
>     > >>>>>
>     > >>>>> 	[SM] Sure, I am concerned about the status quo wich does
> not entail
>     > >> "proper configuration and/or policies", and hence I believe the NQB
>     > special
>     > >> treatment on WIFI should be opt-in and not "opt-out" (in quotes as
> most
>     > >> endusers will not be able to opt-out). For thid reaon I believe that the
>     > >> proposal to use a code point that by default is mapped to AC_BK is the
>     > only
>     > >> correct solution (as a bonus it seems that such a code point also has a
>     > better
>     > >> chance to survive transit over the internet). NQB-aware APs then
> simply
>     > >> treat that NQB-codepoint however they want. If for example a
> priority
>     > boost
>     > >> is desired such an AP can easily implement the required rate-limiting
> so
>     > that
>     > >> AC_BE traffic does not get starved out. In short, I fully agree that
> special
>     > >> treatment requires "proper configuration and/or policies" and the
>     > desirable
>     > >> strategy if that can not guaranteed should be "do no harm".
>     > >>>>>
>     > >>>>>> The final SHOULD is intended to address your concern about
>     > >> prioritization (since it results in segregation without prioritization).
>     > >>>>>
>     > >>>>> 	[SM] Ah, in that case the AP needs to be be NQB aware
> anyway,
>     > >> would it then not be better to use an appropriate scheduler/AQM in
> front
>     > of
>     > >> the AC_BE queue and keep all traffic in the same priority class? The
>     > >> disadvantage of setting AC_VI to the same EDCA values as AC_BE is
> then
>     > that
>     > >> applicatons that expect an airtime access boost from using AC_VI will
> not
>     > get
>     > >> it any more (not necessarily a deal-breaker but certainly unexpected
>     > enough
>     > >> to merit clear communication of that side-effect).
>     > >>>>>
>     > >>>>>> Absent this requirement (or the ability to comply with it
>     > >> operationally), the operator would need to consider (and perhaps
> limit)
>     > >> which applications are allowed to be marked as NQB.  This aspect isn't
>     > >> discussed in the draft, but I will add it based on your input.
>     > >>>>>
>     > >>>>> 	[SM] Great! I would guess the safest would be to have the
> NQB-
>     > >> aware scheduler in an AP apply some (proportional) rate-limiting if
> NQB
>     > >> traffic is getting preferential air-time access.
>     > >>>>>
>     > >>>>>>
>     > >>>>>> Network operators understand the value of segregating NQB
> traffic
>     > >> on WiFi links, and will almost certainly select a DSCP in practice that
>     > achieves
>     > >> that goal.
>     > >>>>>
>     > >>>>> 	[SM] That is exactly part of my concern with the default
> mapping to
>     > >> AC_VI approach, I expect that very quickly a lot of traffic will utilize the
>     > AC_VI
>     > >> queue potentially starving normal AC_BE traffic in the process.
>     > >>>>>
>     > >>>>>> Assigning a different DSCP in this draft would do nothing to
> prevent
>     > >> them from doing so.
>     > >>>>>
>     > >>>>> 	[SM] Sure, but is that really a good justification for proposing
> a DSCP
>     > >> with known side-effects? As far as I am concerned an RFC should
> propose
>     > >> sane defaults and hope for the best.
>     > >>>>>
>     > >>>>>> Instead, what we need to do is clearly articulate how to make
> best
>     > >> use of the existing WiFi tools, and how to avoid conflicts.
>     > >>>>>
>     > >>>>> 	[SM] I believe the last two are mutually exclusive...
>     > >>>>>
>     > >>>>>>
>     > >>>>>> In existing RFCs, the IETF already recommends that video
>     > >> conferencing applications mark their traffic as either AF4x or CS4, all of
>     > which
>     > >> get mapped to AC_VI.  The remaining language in the NQB draft
> describes
>     > >> sparser flows than these.
>     > >>>>>
>     > >>>>> 	[SM] as an implementer I read "relatively low data rates",
> without
>     > >> further guidance I have very little intuition what to use as reference.
>     > Could
>     > >> this be made more explicit? This is orthogonal to the question
> whether
>     > such
>     > >> a limit should be enforced in any way, here the question really is
> about
>     > >> getting a feel what is considered acceptable for NQB treatment.
>     > >>>>>
>     > >>>>>>
>     > >>>>>> Based on your comments, I attempted to remove all text that
> could
>     > >> be interpreted as recommending that high-data-rate traffic be
> marked
>     > NQB.
>     > >>>>>
>     > >>>>> 	[SM] Thanks, as long as the aggregate NQB traffic is relative
> sparse
>     > >> compared to the available WiFi bandwidth (or the number of tx_ops)
>     > most of
>     > >> my WiFi concerns get less and less relevant. To be explicit, I do not
> object
>     > on
>     > >> principle to using AC_VI or even AC_VO as long as this does not eat
>     > >> significantly into the tx_ops for AC_BE, the current draft improves  in
> that
>     > >> direction. Would it be possible to make this point even stronger?
>     > >>>>>
>     > >>>>>> It appears that I missed one instance (in the Introduction it gives
>     > >> "interactive voice and video" as an example). Aside from this (which I
> can
>     > >> correct), I think the draft currently recommends that NQB only be
> used
>     > for
>     > >> sparse traffic.  That said, the section where this guidance is intended
> to be
>     > >> given is still lacking in specificity, and poses some open questions that
> may
>     > >> need to be addressed in a subsequent revision.
>     > >>>>>
>     > >>>>> 	[SM] Sounds great. Now this then cycles back to one of the
> other
>     > >> open topics, "enforcement". Ideally NQB-aware APs should monitor
> both
>     > >> queues and re-assign flows between them based on flow-behavior in
>     > >> relation to time-variant bandwidth experienced by that flow.
>     > >>>>>
>     > >>>>> Best Regards
>     > >>>>> 	Sebastian
>     > >>>>>
>     > >>>>>>
>     > >>>>>> Best Regards,
>     > >>>>>> Greg
>     > >>>>>>
>     > >>>>>>
>     > >>>>>> On 11/4/19, 3:25 PM, "tsvwg on behalf of Sebastian Moeller"
>     > <tsvwg-
>     > >> bounces@ietf.org on behalf of moeller0@gmx.de> wrote:
>     > >>>>>>
>     > >>>>>> Regarding https://datatracker.ietf.org/doc/draft-ietf-tsvwg-
>     > >> nqb/?include_text=1
>     > >>>>>>
>     > >>>>>> 7.3.  WiFi Networks
>     > >>>>>>
>     > >>>>>>   WiFi networking equipment compliant with 802.11e generally
>     > >> supports
>     > >>>>>>   either four or eight transmit queues and four sets of associated
>     > >> EDCA
>     > >>>>>>   parameters (corresponding to the four WiFi Multimedia Access
>     > >>>>>>   Categories) that are used to enable differentiated media access
>     > >>>>>>   characteristics.  Implementations typically utilize the IP DSCP
> field
>     > >>>>>>   to select a transmit queue, but should be considered as Non-
>     > >>>>>>   Differentiated Services-Compliant Nodes as described in
> Section 4
>     > >> of
>     > >>>>>>   [RFC2475].  As a result this document discusses interoperability
> with
>     > >>>>>>   WiFi networks, as opposed to PHB compliance.
>     > >>>>>>
>     > >>>>>>   As discussed in [RFC8325], most existing implementations use a
>     > >>>>>>   default DSCP to User Priority mapping that utilizes the most
>     > >>>>>>   significant three bits of the DiffServ Field to select "User
>     > >>>>>>   Priority" which is then mapped to the four WMM Access
>     > Categories.
>     > >> In
>     > >>>>>>   order to increase the likelihood that NQB traffic is provided a
>     > >>>>>>   separate queue from QB traffic in existing WiFi equipment, the
>     > >> 0x2A
>     > >>>>>>   codepoint is preferred for NQB.  This would map NQB to UP_5
>     > >> which is
>     > >>>>>>   in the "Video" Access Category.
>     > >>>>>>
>     > >>>>>>   Systems that utilize [RFC8325], SHOULD map the NQB codepoint
> to
>     > >> UP_5
>     > >>>>>>   in the "Video" Access Category.
>     > >>>>>>
>     > >>>>>>   In order to preserve the incentives principle, WiFi systems
> SHOULD
>     > >>>>>>   configure the EDCA parameters for the Video Access Category
> to
>     > >> match
>     > >>>>>>   those of the Best Effort Access Category.
>     > >>>>>>
>     > >>>>>>
>     > >>>>>> [SM] This last section is puzzling: if the wifi system configures
> AC_VI
>     > >> with EDCA parameters that match the AC_BE parameters, AC_VI
> ceases
>     > to
>     > >> be different from AC_BE, in that case picking a codepoint that
>     > automatically
>     > >> maps to CS0 and hence to AC_BE  seems much safer, simpler and
> straight
>     > >> forward to me.
>     > >>>>>> Especially since essentially none of the millions deployed WiFi
> APs
>     > out
>     > >> there will a) have this configured like proposed already and b) none of
> the
>     > >> consumer APs I know actually allow to easily adjust EDCA parameters
> at
>     > all. I
>     > >> guess I must be missing something and would be delighted to be
> shown
>     > why
>     > >> the proposed text is the right thing.
>     > >>>>>> My take on this still is, if NQB traffic is sufficiently sparse using
> AC_VI
>     > >> can be justified, but without any rate limits this has the potential of
> being
>     > >> quite unfair to concurrent APs on the same channel (as well as the
>     > >> neighboring channels that overlap with the selected).
>     > >>>>>> I do not want to sound alarmist, but given the number of cable-
> ISP
>     > >> WiFi-APs (as indicated by a SSID containing the ISPs name) in my city, I
>     > >> believe making sure that those APs will not basically start hogging
> most
>     > >> airtime seems the prudent thing to do. If there are sufficient
> backstops in
>     > >> place (like rate limiting or automatic down-marking if the traffic is not
>     > sparse
>     > >> enough) to avoid the described situation, I am all for it.
>     > >>>>>>
>     > >>>>>> The text probably should also openly discuss that in WiFi/WMM
> the
>     > >> four available queues by design have different priorities, and by
> moving
>     > NQB
>     > >> out of the default AC_BE while leaving QB flows in there, this
> effectively
>     > runs
>     > >> against  the following text in the draft: "The NQB queue SHOULD be
> given
>     > >> equal priority compared to queue-building traffic of equivalent
>     > importance."
>     > >> (leaving alone the question how an AP or a station is supposed to
>     > measure
>     > >> importance)
>     > >>>>>>
>     > >>>>>>
>     > >>>>>> Sebastian
>     > >>>>>>
>     > >>>>>>
>     > >>>>>
>     > >>>>>
>     > >>>>>
>     > >>>>
>     > >>>>
>     > >>>>
>     > >>>
>     > >>>
>     > >>>
>     > >>
>     > >>
>     > >
> 
>