On Thu, Jan 28, 2021 at 07:28:57AM -0800, James Bottomley wrote:
On Thu, 2021-01-28 at 14:01 +0100, Michal Hocko wrote:
On Thu 28-01-21 11:22:59, Mike Rapoport wrote:
[...]
One of the major pushbacks on the first RFC [1] of the concept was about the direct map fragmentation. I tried really hard to find data that shows what is the performance difference with different page sizes in the direct map and I didn't find anything.
So presuming that large pages do provide advantage the first implementation of secretmem used PMD_ORDER allocations to amortise the effect of the direct map fragmentation and then handed out 4k pages at each fault. In addition there was an option to reserve a finite pool at boot time and limit secretmem allocations only to that pool.
At some point David suggested to use CMA to improve overall flexibility [3], so I switched secretmem to use CMA.
Now, with the data we have at hand (my benchmarks and Intel's report David mentioned) I'm even not sure this whole pooling even required.
I would still like to understand whether that data is actually representative. With some underlying reasoning rather than I have run these XYZ benchmarks and numbers do not look terrible.
My theory, and the reason I made Mike run the benchmarks, is that our fear of TLB miss has been alleviated by CPU speculation advances over the years. You can appreciate this if you think that both Intel and AMD have increased the number of levels in the page table to accommodate larger virtual memory size 5 instead of 3. That increases the length of the page walk nearly 2x in a physical system and even more in a virtual system. Unless this were massively optimized, systems would have slowed down significantly. Using 2M pages only eliminates one level and 2G pages eliminates 2, so I theorized that actually fragmentation wouldn't be the significant problem we once thought it was and asked Mike to benchmark it.
The benchmarks show that indeed, it isn't a huge change in the data TLB miss time, I suspect because data is nicely continuous nowadays and the prediction that goes into the CPU optimizations quite easy. ITLB fragmentation actually seems to be quite a bit worse, likely because we still don't have branch prediction down to an exact science.
Another thing is that normally useful work done by userspace so data accesses are dominated by userspace and any change in dTLB miss rate for kernel data accesses is only a small fraction of all misses.
James