[libvirt] [virt-devel] RFC: Modelling timers / clocks & tick policies in libvirt

Zachary Amsden zamsden at redhat.com
Fri Mar 5 16:50:47 UTC 2010


On 03/05/2010 04:27 AM, Daniel P. Berrange wrote:
> This mail describes how I'm suggesting libvirt addresses Dor's RFE to
> timers/tick policies in libvirt
>
>    https://bugzilla.redhat.com/show_bug.cgi?id=557285
>
> Thanks to those who've answered my previous mail / irc questions. Please
> point out any mistakes I made in understanding / modelling this problem
>
> Daniel
>
>
>               Virtual machine timer management in libvirt
>               ===========================================
>
> On PC hardware there are a number of terrible timers / clock sources available
> to operating systems
>
>   * PIT
>      Timer with periodic interrupts
>
>   * RTC
>
>      Time of Day clock, continuous running
>      Timer with periodic interrupts
>
>   * Local APIC Timer
>      Timer with periodic interrupts
>
>   * ACPI Timer
>      Timer with periodic interrupts
>
>   * TSC
>      Read via rdtsc instruction. No interrupts
>    

Never, ever tell anyone this, but it is possible to generate interrupts 
from the TSC.  Doing so is a million orders of perverse because of the 
problems you list:

>      Unreliable on some hardware. eg changes frequency.
>      Not synced between cores
>      Different HZ across hosts
>
>   * HPET
>      Multiple timers with periodic interrupts
>      Can replace PIT/RTC timers
>
> They all generally suck in real hardware, and this gets worse in virtual machines.
> Many different approaches to making them suck less in VMWare, Xen&  KVM, but there
> are some reasonably common concepts....
>    

HPET doesn't suck.

>
> Virtual timekeeping problems
> ----------------------------
>
> Three primary problems / areas to deal with:
>
>   * Time of day clock (RTC)
>
>       - Initialized to UTC/Localtime/Timezone/UTC+offset
>       - Two modes of operation:
>          1. Guest wallclock: only runs when guest is executing. ie stopped across save/restore, etc
>          2. Host  wallclock: runs continuously with host wall time.
>    

Windows wants RTC in localtime, Linux can do either but RTC in UTC is 
easiest to maintain.

Guest / host wall clock is a general consideration for all timers, 
obviously RTC is supposed to be a wallclock, but there is a question: do 
we allow the guest to see host time exactly or do we hide it?

>   * Interrupt timers
>
>       - Ticks can not always be delivered on time
>
>         Policies to deal with "missed" ticks:
>
>          1. Deliver at normal rate without catchup
>          2. Deliver at higher rate to catch up
>          3. Merge into 1 tick&  deliver asap
>    
>          4. Discard all missed ticks
>    

The issue is actually more complex than just these policies.  A naive 
implementation of the policy leads to a guest DOS of the host.

We actually have such a bug, and it demands a policy which merges ticks 
over a certain threshold and does not deliver ASAP.  It's tricky and 
complex to fix because it means our notion of timers for the guest is 
wrong, and we need to introduce a higher order scheduling behaviour.

In general, there isn't much we can tune here, but what we can tune is 
whether the other counters (RTC / HPET / TSC / ACPI) stay in sync with 
ticks delivered.  It's not perfect or completely well defined because 
the tick can't actually be delivered until a fairly complex set of 
hardware rules is obeyed.  This may not be apparent now, because it gets 
worse as we implement more hardware support for NMIs and SMIs.  An ideal 
solution would sync the other counters when the tick is generated, not 
when it is injected.  However, this leads us back to the DOS attack.  
There are also problems with SMP timing here (which CPU gets timer 
interrupts can change, and are they broadcast?).  These problems are 
made worse because we don't gang schedule.

>   * TSC
>       - rdtsc instruction can be exposed to guests in two ways
>
>          1. Trap + emulate (slow, but more reliable)
>          2. Native         (fast, but possibly unreliable)
>
>         Optionally also expose a 'rdtscp' instruction
>
>         Possiblly set a fixed HZ independant of host.
>    

There is also

3) a mixed approach; trap and emulate only when required, allow native 
access and offset appropriately at each exit; and

4) a SMP safe approach; trap and emulate always, and interlock SMP 
access to the clock so it is globally consistent

5) a secure approach; trap and emulate always and hide host time.  This 
precludes the possibility of SMP, as timing differences can be observed 
since we don't gang schedule.  This obviously has implications for the 
other timers.

So this variable is not a simple boolean, but a multi-choice.


> VMWare timekeeping
> ------------------
>
>   * All timers run in "apparant time" ie track guest wallclock
>   * Missed tick policy is to deliver at higher rate to catchup
>   * TSC can be switched between native/emulate (virtual_rdtsc=TRUE|FALSE)
>   * TSC can have hardcoded HZ in emulate mode  (apparantHZ=VALUE)
>   * RTC time of day is synced to host at startup (rtc.diffFromUTC or rtc.startTime)
>   * VMWare tools reset guest TOD if it gets out of sync
>    

There is also lateness hiding; (timeTracker.hideLateness); adjust TSC to 
compensate for lateness of injected interrupts (it's the slightly buggy 
counter compensation at each tick I mention above).

> Xen timekeeping
> ---------------
>
>   * Virtual platform timer (VPT) used as source for other timers
>   * VPT has 4 modes
>
>      0: delay_for_missed_ticks
>
>       Missed ticks are delivered when next scheduled, at the normal
>       rate. RTC runs in guest wallclock, so is delayed. No catchup is
>       attempted
>
>      1: no_delay_for_missed_ticks
>
>       Missed ticks are delivered when next scheduled, at the normal
>       rate. RTC runs in host wallclock, so is not delayed.
>
>      2: no_missed_ticks_pending
>
>       Missed ticks are discarded&  next tick is delivered normally. RTC
>       runs in host wallclock.
>
>
>      3: one_missed_tick_pending
>
>       Missed interrupts are collapsed into a single late tick. RTC
>       run in host wallclock.
>
>    * HPET
>
>      Optionally enabled
>
>    * TSC. Can run in 4 modes
>
>       - auto: emulate if host TSC is unstable. native with invariant TSC
>       - native: always native regardless of host TSC stability
>       - emulate: trap + emulate regardless of host TSC invariant
>       - pvrdtsc: native, requiring invariant TSC. Also exposes rdtscp instruction
>    

TSC is complex enough without RDTSCP.  Let's consider rdtscp as a host 
optimization for vendors of hardware with buggy clocks who want fast 
gettimeofday system calls.  We already are compensating to try to keep 
virtual TSC in sync on KVM and probably don't need this mode.

>
> KVM timekeeping
> ---------------
>
>   * PIT: can be in kernel, or userspace (userspace deprecated for KVM)
>
>     Default tick policies differ for both impls
>
>      - Userspace: Default: missed ticks are delivered when next scheduled at normal rate
>
>         -tdf flag enable tick reinjection to catchup
>
>      - Kernel: Default: Missed ticks are delivered at higher rate to catch up
>
>         -no-kvm-pit-reinjection to disable tick reinjection catchup
>
>   * RTC
>
>      TOD clock can run in host or guest wallclock (clock=host|guest)
>
>       Default: missed ticks are delivered when next scheduled at normal rate
>
>       -rtc-td-hack or -clock driftfix=slew:  missed ticks are delivered at a
>        higher rate to catchup
>
>   * TSC
>
>      - Always runs native.
>
>   * HPET
>
>      - Optionally enabled/disabled
>
>
> Mapping in libvirt XML
> ----------------------
>
> Currently supports setting Time of Day clock via
>
>    <clock offset="utc"/>
>
>      Always sync to UTC
>
>    <clock offset="localtime"/>
>
>      Always sync to host timezone
>
>    <clock offset="timezone" timezone='Europe/Paris'/>
>
>      Sync to arbitrary timezone
>
>    <clock offset="variable" adjustment='123456'/>
>
>      Sync to UTC + arbitrary offset
>
>
>
> Proposal to model all timers policies as sub-elements of this<clock/>
> In general we wil allow zero or more<timer/>  elements following the
> syntax:
>
>    <timer name='platform|pit|rtc|hpet|tsc'
>      wallclock='host|guest'
>     tickpolicy='none|catchup|merge|discard'
>      frequency='123'
>           mode='auto|native|emulate|paravirt'
>        present='yes|no' />
>
> Meaning of 'name':
>
>    Names map to regular PC timers / clocks.  'Platform' refers to the
>    (optional) master virtual clock source that may be used to drive
>    policy of "other" clocks (eg used in Xen, which clocks are controlled
>    by the platform clock is to be undefined because it has varied in
>    Xen over time).
>
> Meaning of 'tickpolicy':
>
>         none: continue to deliver at normal rate (ie ticks are delayed)
>      catchup: deliver at higher rate to catchup
>        merge: ticks merged into 1 single tick
>      discard: all missed ticks are discarded
>
> Meaning of 'wallclock':
>
>    Only valid for name='rtc' or 'platform'
>
>      host: RTC wallclock always tracks host time
>     guest: RTC wallclock always tracks host time
>
> Meaning of 'frequency':
>
>    Set a fixed frequency in HZ.
>
>    NB: Only relevant for TSC. All other timers are fixed (PIT, RTC), or
>        fully guest controlled frequency (HPET)
>    

Actually, the guest doesn't control the HPET base frequency, only the 
divider.  I think.  I'd need to recheck the spec.

> Meaning of 'mode':
>
>   Control how the clock is exposed to guest.
>
>        auto: native if safe, otherwise emulate
>      native: always native
>     emulate: always emulate
>    paravirt: native + paravirtualize
>
>    NB: Only relevant for TSC. All other timers are always emulated.
>    

auto, native, emulate can map nicely for us, but it would be good to 
have an smp safe mode.  (A secure mode is more of a global setting for 
all timers).

> Meaing of 'present':
>
>    Used to override default set of timers visible to the guest. eg to
>    enable or disable the HPET
>
>
>
> Mapping to VMWare
> -----------------
>
> eg with guest config showing
>
>     diffFromUTC='123456'
>       apparentHZ='123456'
>    virtual_rdtsc=False
>
> libvirt XML gets:
>
>    <clock mode='variable' adjustment='123456'>
>      <timer name='tsc' frequency='123456' mode='native'/>
>    </clock>
>
>
> Mapping to Xen
> --------------
>
> eg with guest config showing
>
>       timer_mode=3
>       hpet=1
>       tsc_mode=2
>       localtime=1
>
>     <clock mode='localtime'>
>       <timer name='platform' tickpolicy='merge' wallclock='host'/>
>       <timer name='hpet'/>
>       <timer name='tsc' mode='native'/>
>     </clock>
>
>
> Mapping to KVM
> --------------
>
> eg with guest ARGV showing
>
>     -no-kvm-pit-reinjection
>     -clock base=localtime,clock=guest,driftfix=slew
>     -no-hpet
>
>
>    <clock mode='localtime'>
>      <timer name='rtc' tickpolicy='catchup' wallclock='guest'/>
>      <timer name='pit' tickpolicy='none'/>
>      <timer name='hpet' present='no'/>
>    </clock>
>
>
>
> Further reading
> ---------------
>
> VMWare has the best doc:
>
>    http://www.vmware.com/pdf/vmware_timekeeping.pdf
>
> Xen:
>
>    Docs on 'tsc_mode' at
>
>      $SOURCETREE/docs/misc/tscmode.txt
>
>    Docs for 'timer_mode'  in the source code only:
>
>      xen/include/public/hvm/params.h
>
> KVM:
>
>    No docs at all. Guess from -help descriptions, reading source code&  asking
>    clever people about it :-)
>    

Let me propose an XML mapping a bit later today.  I haven't had coffee 
yet, and we know what that can do.

Zach




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