Re: [ckrm-tech] Re: [Lse-tech] [PATCH] cpusets - big numa cpu andmemory placement
From: Shailabh Nagar
Date: Tue Aug 10 2004 - 17:53:01 EST
Paul Jackson wrote:
The more I look, the more convinced I become that these two projects
are separate, in means and goals, with little interaction and less
opportunty for either to leverage the other. Neither project should
be contingent on the other.
Warning:
No one should take anything that follows as actually
describing CKRM. I can find statements on the CKRM web
pages directly contradicting what I state, and I am certain
that I'm somewhat to substantially confused. I'll just go
ahead and boldly describe CKRM as I currently understand it,
in the hopes that someone knowledgeable in the project will
thus more easily see my errors and offer corrections.
Here is my current understanding of cpusets and CKRM, and how they
differ.
Cpusets - Static Isolation:
The essential purpose of cpusets is to support isolating large,
long-running, multinode compute bound HPC (high performance
computing) applications or relatively independent service jobs,
on dedicated sets of processor and memory nodes.
CKRM's overall objective is to isolate the performance of a group of
kernel objects from other groups. The grouping can be static
(applications, users, etc.) or dynamic (processes of the same app can
change membership from one group to another).
The group of objects is what we call a class.
The apparent dichotomy between what you describe and what we manage is
resolved when you consider that all applications/users etc. finally boil
down to some set of tasks making resource demands of cpu, mem, io etc.
Basically we have a flexible way of defining a group of tasks - what
that group maps to in user space doesn't matter inside the kernel when
resource allocations are being done.
The (unobtainable) ideal of cpusets is to provide perfect
isolation, for such jobs as:
1) Massive compute jobs that might run hours or days, on dozens
or hundreds of processors, consuming gigabytes or terabytes
of main memory. These jobs are often highly parallel, and
carefully sized and placed to obtain maximum performance
on NUMA hardware, where memory placement and bandwidth is
critical.
2) Independent services for which dedicated compute resources
have been purchased or allocated, in units of one or more
CPUs and Memory Nodes, such as a web server and a DBMS
sharing a large system, but staying out of each others way.
The essential new construct of cpusets is the set of dedicated
compute resources - some processors and memory. These sets have
names, permissions, an exclusion property, and can be subdivided
into subsets.
The only difference between CKRM and cpusets in the paragraphs above is
that cpusets tries to achieve the isolation by a static partitioning of
physical cpus and mem nodes. CKRM does so in terms of cpu time and
memory pages.
The cpuset file system models a hierarchy of 'virtual computers',
which hierarchy will be deeper on larger systems.
The average lifespan of a cpuset used for (1) above is probably
between hours and days, based on the job lifespan, though a couple
of system cpusets will remain in place as long as the system is
running. The cpusets in (2) above might have a longer lifespan;
you'd have to ask Simon Derr of Bull about that.
CKRM class lifespans depend on how the classes are defined by the
sysadmin or delegated users. Classes representing users will last as
long as the system is up, those representing a particular application
will last as long as the app (typically - CKRM doesn't autodelete
classes - the user who created it needs to do it himself).
CKRM - Dynamic Sharing:
My current, probably confused, understanding is that the purpose
of CKRM is to enable managing different Qualities of Service, or
"Classes" (*) on streams of transactions, queries, jobs, tasks that
are sharing the same compute resources.
It would be easier to think of classes as a grouping of tasks and
sockets which, as an aggregate, have some share of each resource managed
by CKRM. A class is not characterized by the QoS level, but the objects
it groups. In particular, two classes can have the same QoS level (e.g.
20% of total cpu time) and the same class can have its QoS level changed
(from 20% to say 40%).
Even if there is some
big honking service process such as an enterprise DBMS running,
the point of CKRM is not focused on optimizing the overall
performance of that job, but rather on distinguishing between
various transactions flowing through the system, determining the
quality of service (Class) allowed for each, measuring critical
resource usage for each Class, and biasing resource allocation
decisions, such as in the scheduler and allocator, to obtain the
desired balance of resource usage between Classes, or the desired
response time to particular favored Classes.
Managing the QoS of transactions (which tend to cross task/application
boundaries) is a complicated use of CKRM which tries to exploit its
support for flexible and dynamic grouping. Doing this requires some
degree of application cooperation (it is only the app which can tell
what transaction it is processing).
However transaction QoS management is not what CKRM, the kernel project,
is doing. Its most commonly expected usage is to isolate the performance
of one application from another or one user from another. Doing this is
far easier than transactions since apps and users map to tasks/sockets
in easily understood ways that do not require any cooperation from the
app/user (indeed we don't want any "cooperation" or "interference" from
them !)
This is certainly a more challenging objective than cpusets,
in that it requires (1) tracking resource usage (cpu cycles,
memory pages, i/o bandwidth) by Class, (2) assigning a Class to
transactions moving through the system, and imputing that Class to
the tasks handling each transaction, and (3) dynamically biasing
scheduling and allocation decisions so as to affect the desired
Quality of Service policies.
Correct, CKRM does have more work to do than cpusets does, since it
controls more fine-grained resources than cpusets (cpu time vs cpus, mem
pages vs. nodes).
However, it does get a lot of help from the system and does not have to
carry the burden of 1) and 3) all by itself. 1) only requires existing
resource usage data (cpu time consumed by a process) to be aggregated,
additionally, into class statistics. 3) too can be done as an increment
over existing schedulers, not a replacement. In case of the CPU, it
means picking the next class to run and then choosing the next task to
run. In mem, it means preferentially picking pages from an "over share"
class to swap out etc.
The essential new construct of CKRM is the Class - a Quality
of Service level.
As said above, this is not the right way to think of a class. Think
groupings ! The Quality of Service level is an attribute of a class,
not its defining characteristic.
Metrics, transactions, tasks, and resource
decisions all have to be tracked or managed by Class.
These Classes form a fairly shallow hierarchy of usage levels or
service qualities, as perceived by the end users of the system.
I'd guess that the average lifetime of a Class is months or years,
as they can reflect the relative priority of relations with long
standing, external customers.
Cpusets and CKRM have profoundly different purposes, economics and
motivations.
I would say the methods differ, not the purpose. Both are trying to
performance-isolate groups of tasks - one uses the spatial dimension of
cpu bindings, the other uses the temporal dimension of cpu time.
For one thing, the cpuset hierarchy and the class hierarchy are two
different things. One provides semi-static collections of compute
resources, which I sometimes call virtual computers or soft partitions.
The other reflects the differing qualities of service which you find
it worth providing the originators of transactions into your system.
These have about as much to do with each other as the "Program Files"
on my sons game machine has to do with Linus' home directory. Yup -
they're both representable in file system trees ;).
Again, I would disagree. The filesytem hierarchies of cpusets and CKRM
have quite a few things in common.
- directories representing the grouping of tasks
- hierarchical subdivision aka a child can only subdivide what its
parent has. In CKRM, only the % share that a parent gets from the system
is further divisible amongst child classes. In cpusets, that resource
happens to be the set of cpus_allowed.
- delegation of control through file permissions : both allow non-root
users to control their resource allocations.
- binding of tasks to a group by writing pids to a special virtual file
I see no value other than obfuscation to attempting to represent
either hierarchy in terms of the other.
Notwithstanding the similarities between the hierarchies listed above,
this danger of obfuscation is a possibility. The reason for that is that
our interface within the filesystem, as defined by the virtual files and
the attributes within them that one can read and write, do not map
cleanly onto the ones exported by cpusets.
e.g. the notions of stats, lower and upper bounds for shares that CKRM
needs, are not relevant to cpusets. On the other hand, we do allow
attributes that are controller-specific to be represented within some
virtual files and cpusets could use that.
The other point of difference is the one you'd brought up earlier - ther
restrictions on the hierarchy creation. CKRM has none (effectively),
cpusets has many.
As CKRM's interface stands today, there are sufficient differences
between the interfaces to keep them separate.
However, if CKRM moves to a model where
- each controller is allowed to define its own virtual files and attributes
- each controllers has its own hierarchy (and hence more control over
how it can be formed),
then the similarities will be too many to ignore merger possibilities
altogether.
The kicker is, we've not decided. The splitting of controllers into
their own hierarchy is something we're considering independently (as a
consequence of Linus' suggestion at KS04). But making the interface
completely per-controller is something we can do, without too much
effort, IF there is sufficient reason (we have other reasons for doing
that as well - see recent postings on ckrm-tech).
Interest/recommendations from the community that cpusets be part of
CKRM's hierarchy would certainly be a factor in that decision.
For another way to put the difference, CKRM is managing "commodity"
resources, such as cycles and bits. One cycle is as good as the
next; it's just a question of who gets how many. On the other hand,
cpusets manage precious named resources - such as an entire block
of 64 CPUs and associated memory on a 256 CPU system.
Each such
cpuset is a unique, named, first class, relatively long lasting
entity represented by its own directory in the cpuset file system,
and assigned a specific well known job to execute.
s/cpuset/class and s/cpuset file system/rcfs and this pretty much
describes CKRM.
So what interaction or relationship if any do I see between cpusets
and CKRM? Only one at the moment. A major job running within a
long lasting cpuset might well want to make use of CKRM in order to
provide refined Qualities of Service to its clients. This means that
the CKRM instance would need to understand that it's not managing
the entire physical system, but just some cpuset-defined subset.
This brings up a very important point. If CKRM's cpu controller is
managing cpu time and cpusets are also operational, it might be hard for
one or the other to achieve their objectives since they're both trying
to constrain CPU usage along different dimensions.
But in a sense, CKRM already faces this problem since cpu, mem and io
are not completely independent resources. We're pretty much relying on
the sysadmin/user not to set wildly conflicting sets of shares for these
resources and can have the same expectation from someone trying to use
both CKRM cpu controller and cpusets at the same time.
A few days ago, one of the CKRM gurus encouraged me to look forward
to providing a CKRM controller for cpusets. At the time, I nodded
knowingly at my screen, as if that all made sense.
Now, I've no clue what such a controller would be or do, or why anyone
would want one.
Such a controller would be a different packaging of the cpusets patch
with most of its internals remaining the same but using the CKRM
interfaces, as Erich had pointed out.
I look forward to having my likely serious confusions over CKRM
corrected. Meanwhile, I remain convinced that cpusets and CKRM are
separate and distinct projects, and that neither should wait for
the other.
On the non-technical front, this is desirable. Tying two projects
together always runs the risk that one drags the other down. CKRM also
faces this dilemma while considering a switch from using relayfs to
netlink as the kernel-user communication channel. We think relayfs suits
our needs better but given the problems the project has, can't afford to
tie ourselves down to it.
Broadly, CKRM is not just a collection of controllers which operate on
arbitrary groups of kernel objects, but also a framework for such
controllers. In its latter role, it has a place for cpusets.
However, cpusets has little need for CKRM except for the commonalities
in the interfaces and that too, if and when CKRM adopts the changes
needed by cpusets.
So the bottomline, IMHO, is the interface - should there be one or two ?
One can argue either way. There are already so many filesystems, whats
one more ? CKRM doesn't encompass other "grouping" resource controllers
such as outbound network (yet!) so why try to shoehorn cpusets into it ?
On the other hand, the user may appreciate one-stop-shops for similar
kinds of resource management and would probably benefit from an
integration of interfaces. And there is a merit to the argument that
interfaces, once adopted in the mainline, will be hard to change.
Rusty's keynote at OLS2003 advised "work on the interfaces last".
Evidently that advice isn't operative here ! Future incompatibility of
interfaces is becoming a blocking factor for acceptance/testing/usage of
the core functionality.
One suggestion is to go ahead with the -mm acceptance of cpusets so its
functionality has a chance to get feedback and address the CKRM
interface integration a couple of months from now once CKRM's interface
issues get resolved ? But do let us know if there is interest in merging
(after this round of clarificatory emails is over) as it will affect
which way we go.
-- Shailabh
I continue to recommend that cpusets be accepted into the 2.6.9 mm
patches, and if that goes well, into Linus' tree.
Thank-you for reading.
(*) The above description of a Class as a Quality of Service
does _not_ match the phrase on http://ckrm.sourcefourge.net:
"A class is a group of Linux tasks (processes), ..."
I'm speculating that this phrase is misleading. More
likely, it's just that I'm confused ;).
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