Andrea Righi wrote: > On Mon, Mar 07, 2011 at 03:31:11PM +0800, Gui Jianfeng wrote: >> Andrea Righi wrote: >>> On Wed, Mar 02, 2011 at 04:47:05PM -0500, Vivek Goyal wrote: >>>> On Wed, Mar 02, 2011 at 02:28:30PM +0100, Andrea Righi wrote: >>>>> On Mon, Feb 28, 2011 at 06:01:14PM -0500, Vivek Goyal wrote: >>>>>> On Mon, Feb 28, 2011 at 11:15:02AM +0100, Andrea Righi wrote: >>>>>>> Overview >>>>>>> ======== >>>>>>> Currently the blkio.throttle controller only support synchronous IO requests. >>>>>>> This means that we always look at the current task to identify the "owner" of >>>>>>> each IO request. >>>>>>> >>>>>>> However dirty pages in the page cache can be wrote to disk asynchronously by >>>>>>> the per-bdi flusher kernel threads or by any other thread in the system, >>>>>>> according to the writeback policy. >>>>>>> >>>>>>> For this reason the real writes to the underlying block devices may >>>>>>> occur in a different IO context respect to the task that originally >>>>>>> generated the dirty pages involved in the IO operation. This makes the >>>>>>> tracking and throttling of writeback IO more complicate respect to the >>>>>>> synchronous IO from the blkio controller's perspective. >>>>>>> >>>>>>> Proposed solution >>>>>>> ================= >>>>>>> In the previous patch set http://lwn.net/Articles/429292/ I proposed to resolve >>>>>>> the problem of the buffered writes limitation by tracking the ownership of all >>>>>>> the dirty pages in the system. >>>>>>> >>>>>>> This would allow to always identify the owner of each IO operation at the block >>>>>>> layer and apply the appropriate throttling policy implemented by the >>>>>>> blkio.throttle controller. >>>>>>> >>>>>>> This solution makes the blkio.throttle controller to work as expected also for >>>>>>> writeback IO, but it does not resolve the problem of faster cgroups getting >>>>>>> blocked by slower cgroups (that would expose a potential way to create DoS in >>>>>>> the system). >>>>>>> >>>>>>> In fact, at the moment critical IO requests (that have dependency with other IO >>>>>>> requests made by other cgroups) and non-critical requests are mixed together at >>>>>>> the filesystem layer in a way that throttling a single write request may stop >>>>>>> also other requests in the system, and at the block layer it's not possible to >>>>>>> retrieve such informations to make the right decision. >>>>>>> >>>>>>> A simple solution to this problem could be to just limit the rate of async >>>>>>> writes at the time a task is generating dirty pages in the page cache. The >>>>>>> big advantage of this approach is that it does not need the overhead of >>>>>>> tracking the ownership of the dirty pages, because in this way from the blkio >>>>>>> controller perspective all the IO operations will happen from the process >>>>>>> context: writes in memory and synchronous reads from the block device. >>>>>>> >>>>>>> The drawback of this approach is that the blkio.throttle controller becomes a >>>>>>> little bit leaky, because with this solution the controller is still affected >>>>>>> by the IO spikes during the writeback of dirty pages executed by the kernel >>>>>>> threads. >>>>>>> >>>>>>> Probably an even better approach would be to introduce the tracking of the >>>>>>> dirty page ownership to properly account the cost of each IO operation at the >>>>>>> block layer and apply the throttling of async writes in memory only when IO >>>>>>> limits are exceeded. >>>>>> Andrea, I am curious to know more about it third option. Can you give more >>>>>> details about accouting in block layer but throttling in memory. So say >>>>>> a process starts IO, then it will still be in throttle limits at block >>>>>> layer (because no writeback has started), then the process will write >>>>>> bunch of pages in cache. By the time throttle limits are crossed at >>>>>> block layer, we already have lots of dirty data in page cache and >>>>>> throttling process now is already late? >>>>> Charging the cost of each IO operation at the block layer would allow >>>>> tasks to write in memory at the maximum speed. Instead, with the 3rd >>>>> approach, tasks are forced to write in memory at the rate defined by the >>>>> blkio.throttle.write_*_device (or blkio.throttle.async.write_*_device). >>>>> >>>>> When we'll have the per-cgroup dirty memory accounting and limiting >>>>> feature, with this approach each cgroup could write to its dirty memory >>>>> quota at the maximum rate. >>>> Ok, so this is option 3 which you have already implemented in this >>>> patchset. >>>> >>>> I guess then I am confused with option 2. Can you elaborate a little >>>> more there. >>> With option 3, we can just limit the rate at which dirty pages are >>> generated in memory. And this can be done introducing the files >>> blkio.throttle.async.write_bps/iops_device. >>> >>> At the moment in blk_throtl_bio() we charge the dispatched bytes/iops >>> _and_ we check if the bio can be dispatched. These two distinct >>> operations are now done by the same function. >>> >>> With option 2, I'm proposing to split these two operations and place >>> throtl_charge_io() at the block layer in __generic_make_request() and an >>> equivalent of tg_may_dispatch_bio() (maybe a better name would be >>> blk_is_throttled()) at the page cache layer, in >>> balance_dirty_pages_ratelimited_nr(): >>> >>> A prototype for blk_is_throttled() could be the following: >>> >>> bool blk_is_throttled(void); >>> >>> This means in balance_dirty_pages_ratelimited_nr() we won't charge any >>> bytes/iops to the cgroup, but we'll just check if the limits are >>> exceeded. And stop it in that case, so that no more dirty pages can be >>> generated by this cgroup. >>> >>> Instead at the block layer WRITEs will be always dispatched in >>> blk_throtl_bio() (tg_may_dispatch_bio() will always return true), but >>> the throtl_charge_io() would charge the cost of the IO operation to the >>> right cgroup. >>> >>> To summarize: >>> >>> __generic_make_request(): >>> blk_throtl_bio(q, &bio); >>> >>> balance_dirty_pages_ratelimited_nr(): >>> if (blk_is_throttled()) >>> // add the current task into a per-group wait queue and >>> // wake up once this cgroup meets its quota >>> >>> What do you think? >> Hi Andrea, >> >> This means when you throttle writes, the reads issued by this task are also throttled? >> >> Thanks, >> Gui > > Exactly, we're treating the throttling of READs and WRITEs in two > different ways. > > READs will be always throttled synchronously in the > __generic_make_request() -> blk_throtl_bio() path. Andreaï I means If the task exceeds write limit, this task will be put to sleep, right? So It doesn't get a chance to issue read requests. Gui > > -Andrea > -- > To unsubscribe from this list: send the line "unsubscribe linux-kernel" in > the body of a message to majordomo@xxxxxxxxxxxxxxx > More majordomo info at http://vger.kernel.org/majordomo-info.html > Please read the FAQ at http://www.tux.org/lkml/ > -- Regards Gui Jianfeng -- To unsubscribe, send a message with 'unsubscribe linux-mm' in the body to majordomo@xxxxxxxxxx For more info on Linux MM, see: http://www.linux-mm.org/ . Fight unfair telecom internet charges in Canada: sign http://stopthemeter.ca/ Don't email: <a href