| Message ID | 20190927161836.57978-1-bgardon@google.com (mailing list archive) |
|---|---|
| Headers | show |
| Series | Create a userfaultfd demand paging test | expand |
On Fri, Sep 27, 2019 at 09:18:28AM -0700, Ben Gardon wrote: > When handling page faults for many vCPUs during demand paging, KVM's MMU > lock becomes highly contended. This series creates a test with a naive > userfaultfd based demand paging implementation to demonstrate that > contention. This test serves both as a functional test of userfaultfd > and a microbenchmark of demand paging performance with a variable number > of vCPUs and memory per vCPU. > > The test creates N userfaultfd threads, N vCPUs, and a region of memory > with M pages per vCPU. The N userfaultfd polling threads are each set up > to serve faults on a region of memory corresponding to one of the vCPUs. > Each of the vCPUs is then started, and touches each page of its disjoint > memory region, sequentially. In response to faults, the userfaultfd > threads copy a static buffer into the guest's memory. This creates a > worst case for MMU lock contention as we have removed most of the > contention between the userfaultfd threads and there is no time required > to fetch the contents of guest memory. Hi, Ben, Even though I may not have enough MMU knowledge to say this... this of course looks like a good test at least to me. I'm just curious about whether you have plan to customize the userfaultfd handler in the future with this infrastructure? Asked because IIUC with this series userfaultfd only plays a role to introduce a relatively adhoc delay to page faults. In other words, I'm also curious what would be the number look like (as you mentioned in your MMU rework cover letter) if you simply start hundreds of vcpu and do the same test like this, but use the default anonymous page faults rather than uffd page faults. I feel like even without uffd that could be a huge contention already there. Or did I miss anything important on your decision to use userfaultfd? Thanks,
Hi Peter, You're absolutely right that we could demonstrate more contention by avoiding UFFD and just letting the kernel resolve page faults. I used UFFD in this test and benchmarking for the other MMU patch set because I believe it's a more realistic scenario. A simpler page access benchmark would be better for identifying further scaling problems within the MMU, but the only situation I can think of where that would be used is VM boot. However, we don't usually see many vCPUs touching memory all over the place on boot. In a migration or restore without demand paging, the memory would have to be pre-populated with the contents of guest memory and the KVM MMU fault handler wouldn't be taking a fault in get_user_pages. In the interest of eliminating the delay from UFFD, I will add an option to use anonymous page faults or prefault memory instead. I don't have any plans to customize the UFFD implementation at the moment, but experimenting with UFFD strategies will be useful for building higher performance post-copy in QEMU and other userspaces in the future. Thank you for taking a look at these patches. Ben On Sun, Sep 29, 2019 at 12:23 AM Peter Xu <peterx@redhat.com> wrote: > > On Fri, Sep 27, 2019 at 09:18:28AM -0700, Ben Gardon wrote: > > When handling page faults for many vCPUs during demand paging, KVM's MMU > > lock becomes highly contended. This series creates a test with a naive > > userfaultfd based demand paging implementation to demonstrate that > > contention. This test serves both as a functional test of userfaultfd > > and a microbenchmark of demand paging performance with a variable number > > of vCPUs and memory per vCPU. > > > > The test creates N userfaultfd threads, N vCPUs, and a region of memory > > with M pages per vCPU. The N userfaultfd polling threads are each set up > > to serve faults on a region of memory corresponding to one of the vCPUs. > > Each of the vCPUs is then started, and touches each page of its disjoint > > memory region, sequentially. In response to faults, the userfaultfd > > threads copy a static buffer into the guest's memory. This creates a > > worst case for MMU lock contention as we have removed most of the > > contention between the userfaultfd threads and there is no time required > > to fetch the contents of guest memory. > > Hi, Ben, > > Even though I may not have enough MMU knowledge to say this... this of > course looks like a good test at least to me. I'm just curious about > whether you have plan to customize the userfaultfd handler in the > future with this infrastructure? > > Asked because IIUC with this series userfaultfd only plays a role to > introduce a relatively adhoc delay to page faults. In other words, > I'm also curious what would be the number look like (as you mentioned > in your MMU rework cover letter) if you simply start hundreds of vcpu > and do the same test like this, but use the default anonymous page > faults rather than uffd page faults. I feel like even without uffd > that could be a huge contention already there. Or did I miss anything > important on your decision to use userfaultfd? > > Thanks, > > -- > Peter Xu