On Wed, Apr 20, 2005 at 12:09:46PM -0700, Paul Jackson wrote:
> Earlier, I wrote to Dinakar:
> > What are your invariants, and how can you assure yourself and us
> > that your code preserves these invariants?
Ok, Let me begin at the beginning and attempt to define what I am
doing here
1. I need a method to isolate a random set of cpus in such a way that
only the set of processes that are specifically assigned can
make use of these CPUs
2. I need to ensure that the sched load balance code does not pull
any tasks other than the assigned ones onto these cpus
3. I need to be able to create multiple such groupings of cpus
that are disjoint from the rest and run only specified tasks
4. I need a user interface to specify which random set of cpus
form such a grouping of disjoint cpus
5. I need to be able to dynamically create and destroy these
grouping of disjoint cpus
6. I need to be able to add/remove cpus to/from this grouping
Now if you try to fit these requirements onto cpusets, keeping in mind
that it already has an user interface and some of the frame work
required to create disjoint groupings of cpus
1. An exclusive cpuset ensures that the cpus it has are disjoint from
all other cpusets except its parent and children
2. So now I need a way to disassociate the cpus of an exclusive
cpuset from its parent, so that this set of cpus are truly
disjoint from the rest of the system.
3. After I have done (2) above, I now need to build two set of sched
domains corresponding to the cpus of this exclusive cpuset and the
remaining cpus of its parent
4. Ensure that the current rules of non-isolated cpusets are all
preserved such that if this feature is not used, all other features
work as before
This is exactly what I have tried to do.
1. Maintain a flag to indicate whether a cpuset is isolated
2. Maintain an isolated_map for every cpuset. This contains a cache of
all cpus associated with isolated children
3. To isolate a cpuset x, x has to be an exclusive cpuset and its
parent has to be an isolated cpuset
4. On isolating a cpuset by issuing
/bin/echo 1 > cpu_isolated
It ensures that conditions in (3) are satisfied and then removes the
cpus of the current cpuset from the parent cpus_allowed mask. (It also
puts the cpus of the current cpuset into the isolated_map of its parent)
This ensures that only the current cpuset and its children will have
access to the now isolated cpus.
It also rebuilds the sched domains into two new domains consisting of
a. All cpus in the parent->cpus_allowed
b. All cpus in current->cpus_allowed
5. Similarly on setting isolated off on a isolated cpuset, (or on doing
an rmdir on an isolated cpuset) It adds all of the cpus of the current
cpuset into its parent cpuset's cpus_allowed mask and removes them from
it's parent's isolated_map
This ensures that all of the cpus in the current cpuset are now
visible to the parent cpuset.
It now rebuilds only one sched domain consisting of all of the cpus
in its parent's cpus_allowed mask.
6. You can also modify the cpus present in an isolated cpuset x provided
that x does not have any children that are also isolated.
7. On adding or removing cpus from an isolated cpuset that does not
have any isolated children, it reworks the parent cpuset's
cpus_allowed and isolated_map masks and rebuilds the sched domains
appropriately
8. Since the function update_cpu_domains, which does all of the
above updations to the parent cpuset's masks, is always called with
cpuset_sem held, it ensures that all these changes are atomic.
> > He removes cpus 4-5 from batch and adds them to cint
>
> Could you spell out the exact steps the user would take, for this part
> of your example? What does the user do, what does the kernel do in
> response, and what state the cpusets end up in, after each action of the
> user?
cpuset cpus isolated cpus_allowed isolated_map
top 0-7 1 0 0-7
top/lowlat 0-1 1 0-1 0
top/others 2-7 1 4-7 2-3
top/others/cint 2-3 1 2-3 0
top/others/batch 4-7 0 4-7 0
At this point to remove cpus 4-5 from batch and add them to cint, the admin
would do the following steps
# Remove cpus 4-5 from batch
# batch is not a isolated cpuset and hence this step
# has no other implications
/bin/echo 6-7 > /top/others/batch/cpus
cpuset cpus isolated cpus_allowed isolated_map
top 0-7 1 0 0-7
top/lowlat 0-1 1 0-1 0
top/others 2-7 1 4-7 2-3
top/others/cint 2-3 1 2-3 0
top/others/batch 6-7 0 6-7 0
# Add cpus 4-5 to cint alongwith existing cpus 2-3
/bin/echo 2-5 > /top/others/cint/cpus
cpuset cpus isolated cpus_allowed isolated_map
top 0-7 1 0 0-7
top/lowlat 0-1 1 0-1 0
top/others 2-7 1 6-7 2-5
top/others/cint 2-5 1 2-5 0
top/others/batch 6-7 0 6-7 0
As you can see there are no "side effects" here. All of these are legitimate
operations and work the same even in the current cpusets code as in mainline.
(Except ofcourse the isolation part)
Hope this helps in clarifying all your questions
However, after taking into account all of your comments so far, I have
reworked my patch and reduced and simplified it quite a bit. I have
maintained all of the functionality that I have described so far.
(Adding one restriction viz
You can also modify the cpus present in an isolated cpuset x provided
that x does not have any children that are also isolated.)
I'll send that in a new mail.
Thanks for all your comments and review so far
-Dinakar
-
To unsubscribe from this list: send the line "unsubscribe linux-kernel" in
the body of a message to [email protected]
More majordomo info at http://vger.kernel.org/majordomo-info.html
Please read the FAQ at http://www.tux.org/lkml/
[Index of Archives]
[Kernel Newbies]
[Netfilter]
[Bugtraq]
[Photo]
[Stuff]
[Gimp]
[Yosemite News]
[MIPS Linux]
[ARM Linux]
[Linux Security]
[Linux RAID]
[Video 4 Linux]
[Linux for the blind]
[Linux Resources]