[PATCH 0/2] mm: Enable page parallel initialisation for Power

Wed Mar 9 15:28:31 AEDT 2016

On 09/03/16 15:17, Li Zhang wrote:
> On Tue, Mar 8, 2016 at 10:45 PM, Balbir Singh <bsingharora at gmail.com> wrote:
>>
>> On 08/03/16 14:55, Li Zhang wrote:
>>> From: Li Zhang <zhlcindy at linux.vnet.ibm.com>
>>>
>>> Uptream has supported page parallel initialisation for X86 and the
>>> boot time is improved greately. Some tests have been done for Power.
>>>
>>> Here is the result I have done with different memory size.
>>>
>>> * 4GB memory:
>>>     boot time is as the following:
>>>     with patch vs without patch: 10.4s vs 24.5s
>>>     boot time is improved 57%
>>> * 200GB memory:
>>>     boot time looks the same with and without patches.
>>>     boot time is about 38s
>>> * 32TB memory:
>>>     boot time looks the same with and without patches
>>>     boot time is about 160s.
>>>     The boot time is much shorter than X86 with 24TB memory.
>>>     From community discussion, it costs about 694s for X86 24T system.
>>>
>>> From code view, parallel initialisation improve the performance by
>>> deferring memory initilisation to kswap with N kthreads, it should
>>> improve the performance therotically.
>>>
>>> From the test result, On X86, performance is improved greatly with huge
>>> memory. But on Power platform, it is improved greatly with less than
>>> 100GB memory. For huge memory, it is not improved greatly. But it saves
>>> the time with several threads at least, as the following information
>>> shows(32TB system log):
>>>
>>> [   22.648169] node 9 initialised, 16607461 pages in 280ms
>>> [   22.783772] node 3 initialised, 23937243 pages in 410ms
>>> [   22.858877] node 6 initialised, 29179347 pages in 490ms
>>> [   22.863252] node 2 initialised, 29179347 pages in 490ms
>>> [   22.907545] node 0 initialised, 32049614 pages in 540ms
>>> [   22.920891] node 15 initialised, 32212280 pages in 550ms
>>> [   22.923236] node 4 initialised, 32306127 pages in 550ms
>>> [   22.923384] node 12 initialised, 32314319 pages in 550ms
>>> [   22.924754] node 8 initialised, 32314319 pages in 550ms
>>> [   22.940780] node 13 initialised, 33353677 pages in 570ms
>>> [   22.940796] node 11 initialised, 33353677 pages in 570ms
>>> [   22.941700] node 5 initialised, 33353677 pages in 570ms
>>> [   22.941721] node 10 initialised, 33353677 pages in 570ms
>>> [   22.941876] node 7 initialised, 33353677 pages in 570ms
>>> [   22.944946] node 14 initialised, 33353677 pages in 570ms
>>> [   22.946063] node 1 initialised, 33345485 pages in 580ms
>>>
>>> It saves the time about 550*16 ms at least, although it can be ignore to compare
>>> the boot time about 160 seconds. What's more, the boot time is much shorter
>>> on Power even without patches than x86 for huge memory machine.
>>>
>>> So this patchset is still necessary to be enabled for Power.
>>>
>>>
> Hi Balbir,
>
> Thanks for your reviewing.
>
>> The patchset looks good, two questions
>>
>> 1. The patchset is still necessary for
>>     a. systems with smaller amount of RAM?
>        I think it is. Currently, I tested systems for 4GB, 50GB, and
> boot time is improved.
>        We may test more systems with different memory size in the future.
>>     b. Theoretically it improves boot time?
>        The boot time is improved a little bit for huge memory system
> and it can be ignored.
>        But I think it's still necessary to enable this feature.
>
>> 2. the pgdat->node_spanned_pages >> 8 sounds arbitrary
>>     On a system with 2TB*16 nodes, it would initialize about 8GB before calling deferred init?
>>     Don't we need at-least 32GB + space for other early hash allocations
>>     BTW, My expectation was that 32TB would imply 32GB+32GB of large hash allocations early on
>       pgdat->node_spanned_pages >> 8 means that it allocates the size
> of the memory on one node.
>       On a system with 2TB *16nodes, it will allocate 16*8GB = 128GB.
>       I am not sure if it can be minimised to >> 16 to make sure all
> the architectures with different
>       memory size work well.  And this is also mentioned in early
> discussion for X86, so I choose  >> 8.
>
> *    From the code as the following:
>
>       free_area_init_core ->
>                      memmap_init->
>                               update_defer_init
>      #define memmap_init(size, nid, zone, start_pfn) \
>            memmap_init_zone((size), (nid), (zone), (start_pfn), MEMMAP_EARLY)
>
>      memmap_init_zone is based on a zone, but free_area_init_core will
> help find the highest
>      zone on the node. And update_defer_init() get max initialised
> memory on highest zone for a node to
>      reserve for early initialisation.
>
>      static void __paginginit free_area_init_core(struct pglist_data *pgdat)
>      {
>             ...
>            for (j = 0; j < MAX_NR_ZONES; j++) {
>                   ....
>                  memmap_init(size, nid, j, zone_start_fn);   //find
> the highest zone on a node.
>                  ...
>            }
>      }
>
> *   From the dmesg log, after applying this patchset, it has
> 123013440K(about 117GB),
>     which is enough for Dentry node hash table and Inode hash table in
> this system.
>
>     [    0.000000] Memory: 123013440K/31739871232K available (8000K
> kernel code, 1856K rwdata,
>     3384K rodata, 6208K init, 2544K bss, 28531136K reserved, 0K cma-reserved)
>
> Thanks :)
>
Looks good! It seems the real benefit is for smaller systems - thanks for clarifying
Please check if CMA is affected in any way

Acked-by: Balbir Singh <bsingharora at gmail.com>

Balbir Singh.