On Jul 20, 2007, at 6:17 AM, Rafael J. Wysocki wrote:
On Friday, 20 July 2007 01:07, [email protected] wrote:
On Thu, 19 Jul 2007, Rafael J. Wysocki wrote:
On Thursday, 19 July 2007 17:46, Milton Miller wrote:
The currently identified problems under discussion include:
(1) how to interact with acpi to enter into S4.
(2) how to identify which memory needs to be saved
(3) how to communicate where to save the memory
(4) what state should devices be in when switching kernels
(5) the complicated setup required with the current patch
(6) what code restores the image
(7) how to avoid corrupting filesystems mounted by the hibernated
kernel
I didn't realize this was a discussion item. I thought the options
were
clear, for some filesystem types you can mount them read-only, but for
ext3 (and possilby other less common ones) you just plain cannot touch
them.
That's correct. And since you cannot thouch ext3, you need either to
assume
that you won't touch filesystems at all, or to have a code to
recognize the
filesystem you're dealing with.
Or add a small bit of infrastructure that errors writes at make_request
if you don't have a magic "i am a direct block device write from
userspace" flag on the bio.
The hibernate may fail, but you don't corrupt the media.
If you don't get the image out, resume back to the "this is resume"
instead of the power-down path.
(2) Upon start-up (by which I mean what happens after the user has
pressed
the power button or something like that):
* check if the image is present (and valid) _without_ enabling
ACPI
(we don't
do that now, but I see no reason for not doing it in the new
framework)
* if the image is present (and valid), load it
* turn on ACPI (unless already turned on by the BIOS, that is)
* execute the _BFS global control method
* execute the _WAK global control method
* continue
Here, the first two things should be done by the image-loading
kernel, but
the remaining operations have to be carried out by the restored
kernel.
Here I agree.
Here is my proposal. Instead of trying to both write the image and
suspend, I think this all becomes much simpler if we limit the scope
the work of the second kernel. Its purpose is to write the image.
After that its done. The platform can be powered off if we are
going
to S5. However, to support suspend to ram and suspend to disk, we
return to the first kernel.
We can't do this unless we have frozen tasks (this way, or another)
before
carrying out the entire operation. In that case, however, the
kexec-based
approach would have only one advantage over the current one.
Namely, it
would allow us to create bigger images.
we all agree that tasks cannot run during the suspend-to-ram state,
but
the disagreement is over what this means
at one extreme it could mean that you would need the full freezer as
per
the current suspend projects.
at the other extreme it could mean that all that's needed is to
invoke the
suspend-to-ram routine before anything else on the suspended kernel
on the
return from the save and restore kernel.
we just need to figure out which it is (or if it's somewhere in
between).
Well, I think that the "invoke the suspend-to-ram routine before
anything else
on the suspended kernel" thing won't be easy to implement in practice.
Why? You don't expect suspend-to-ram in drivers to be implemented? We
need more speperation of the quiesce drivers from power-down devices?
Note that we are just talking about "suspend devices and put their
state in ram", not actually invoking the platform to suspend to ram.
And I'm actually saying we free memory and maybe allocate disk blocks
for the save before we suspend (see below).
Message-ID: <[email protected]>
On Sun Jul 15 05:27:03 2007, Rafael J. Wysocki wrote:
(1) Filesystems mounted before the hibernation are untouchable
This is because some file systems do a fsck or other activity even
when
mounted read only. For the kexec case, however, this should be
"file
systems mounted by the hibernated system must not be written". As
has
been mentioned in the past, we should be able to use something like
dm
snapshot to allow fsck and the file system to see the cleaned copy
while not actually writing the media.
We can't _require_ users to use the dm snapshot in order for the
hibernation
to work, sorry.
And by _reading_ from a filesystem you generally update metadata.
not if the filesystem is mounted read-only (except on ext3)
Well, if the filesystem in question is a journaling one and the
hibernated
kernel has mounted this fs read-write, this seems to be tricky anyway.
Yes. I would argue writing to existing blocks of a file (not thorugh
the filesystem, just getting their blocsk from the file system) should
be safe, but it occurs to me that may not be the case if your fsck and
bmap move data blocks from some update log to the file system.
But we know the (maximum) image size. So we could allocate the blocks
in the first image before suspending the drivers and memory
allocations, and supplying the list to the second kernel. We could
even write to the first block with a signature "suspend to here", or
even the whole block list to the beginning (it will have to be saved to
disk for restore anyways).
The kjump kernel must not have any knowledge retained if we reuse
it.
(2) Swap space in use before the hibernation must be handled with
care
Yes. Actually, even though they have been used by the write-in-the
kernel users, they will be among the most difficult devices to use
for
snapshots by a userspace second kernel.
If we use the "write to these blocks" then this is as easy as writing
to a file in a mounted filesystem.
(4) The user should be able to limit the size of a hibernation
image
This means the suspending kernel must arrange to reduce its active
memory. The limited save can be done by providing a limited list in
(3).
It seems to me that you don't understand the problem here.
Assume you have 90% of RAM allocated before the hibernation and the
user has
requested the image to be not greater than 50% of RAM. In that case
you have
to free some memory _before_ identifying memory to save and you must
not
race with applications that attempt to allocate memory while you're
doing it.
I disagree a little bit.
first off, only the suspending kernel can know what can be freed and
what
is needed to do so (remember this is kernel internals, it can change
from
patch to patch, let alone version to version)
second, if you have a lot of memory to free, and you can't just throw
away
caches to do so, you don't know what is going to be involved in
freeing
the memory, it's very possilbe that it is going to involve userspace,
so
you can't freeze any significant portion of the system, so you can't
eliminate all chance of races
what you can do is
1. try to free stuff
2. stop the system and account for memory, is enough free
if not goto 1
if userspace is dirtying memory fast enough, or is just useing enough
memory that you can't meet your limit you just won't be able to
suspend.
This means unreliable hibernation for some workloads. While I agree
that
shouldn't be a problem in a common case, there are users who will
complain. ;-)
With my allocate memory as a task and don't save that task's memory
approach, we can get to this point while userspace is running. It
could be controllled by userspace, or even be userspace
(sys_do_not_save_me() waits for resume, and dies as the kernel
resumes).
but under any other conditions you will eventually get enough memory
free.
so try several times and if you still fail tell the user they have too
much stuff running and they need to kill something.
Well, with the freezer that's much simpler (and more reliable, I'd
say): you
freeze tasks and _then_ you shrink memory.
It means you are committed to suspend before you try to shrink memory.
What happens when the user requested a smaller image that memory in
use?
=(8) Hibernation and restore should not be too slow
We control the added code. We are using full runtime drivers and
will
run at hardware speeds.
That may not be enough. If you're going to save, say, 80% of RAM on
a 2 GB
machine, then you'll have to be using image compression.
this doesn't make sense, 20% of 2G is 400M, if you can't make a
kernel and
userspace that can run in 400M you have a serious problem.
I was talking about the _speed_ of writing and reading.
Yes. As I said, adding a compress as we copy the pages into the saving
kernel for writeout should be easy.
even if you wanted to save 99% of RAM on a 2G system, you have 20M of
ram
to play with, which should easily be enough.
remember, linux runs on really small systems as well, and while you do
have to load some drivers for the big system, there are a lot of other
things that aren't needed.
All in all, we have three different and working implementation of the
image-writing and image-reading code at our disposal. Why would you
want to
break the open doors?
becouse you say that the current methods won't work without ACPI
support.
I didn't say that. [Or if I did, please point me to this message.]
Anyway, this wouldn't be true even if I did.
What I've been trying to say from the very beginning is that the
current
frameworks _support_ hibernation a la ACPI S4 (although that's not
exactly
ACPI S4) and if we are going to introduce a new framework, then it
should
be designed to _support_ ACPI S4 fully _from_ _the_ _start_.
This DOESN'T mean that the non-ACPI hibernation should be unsupported
and
it DOESN"T mean that the non-ACPI hibernation is not supported
currently.
IT IS SUPPORTED.
As I said, I see kjump as a way to solve the "ok i am at a save point,
now how do I write this image to media without allowing any other io".
As you know by now, my solution for ACPI support is after the image is
written we go back to the kernel that started the suspend and it puts
the machine in S4.
If this works, we get down to 1 hibernate implementation in the kernel
:-).
milton
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