| = Userfaultfd = |
| |
| == Objective == |
| |
| Userfaults allow the implementation of on-demand paging from userland |
| and more generally they allow userland to take control of various |
| memory page faults, something otherwise only the kernel code could do. |
| |
| For example userfaults allows a proper and more optimal implementation |
| of the PROT_NONE+SIGSEGV trick. |
| |
| == Design == |
| |
| Userfaults are delivered and resolved through the userfaultfd syscall. |
| |
| The userfaultfd (aside from registering and unregistering virtual |
| memory ranges) provides two primary functionalities: |
| |
| 1) read/POLLIN protocol to notify a userland thread of the faults |
| happening |
| |
| 2) various UFFDIO_* ioctls that can manage the virtual memory regions |
| registered in the userfaultfd that allows userland to efficiently |
| resolve the userfaults it receives via 1) or to manage the virtual |
| memory in the background |
| |
| The real advantage of userfaults if compared to regular virtual memory |
| management of mremap/mprotect is that the userfaults in all their |
| operations never involve heavyweight structures like vmas (in fact the |
| userfaultfd runtime load never takes the mmap_sem for writing). |
| |
| Vmas are not suitable for page- (or hugepage) granular fault tracking |
| when dealing with virtual address spaces that could span |
| Terabytes. Too many vmas would be needed for that. |
| |
| The userfaultfd once opened by invoking the syscall, can also be |
| passed using unix domain sockets to a manager process, so the same |
| manager process could handle the userfaults of a multitude of |
| different processes without them being aware about what is going on |
| (well of course unless they later try to use the userfaultfd |
| themselves on the same region the manager is already tracking, which |
| is a corner case that would currently return -EBUSY). |
| |
| == API == |
| |
| When first opened the userfaultfd must be enabled invoking the |
| UFFDIO_API ioctl specifying a uffdio_api.api value set to UFFD_API (or |
| a later API version) which will specify the read/POLLIN protocol |
| userland intends to speak on the UFFD and the uffdio_api.features |
| userland requires. The UFFDIO_API ioctl if successful (i.e. if the |
| requested uffdio_api.api is spoken also by the running kernel and the |
| requested features are going to be enabled) will return into |
| uffdio_api.features and uffdio_api.ioctls two 64bit bitmasks of |
| respectively all the available features of the read(2) protocol and |
| the generic ioctl available. |
| |
| Once the userfaultfd has been enabled the UFFDIO_REGISTER ioctl should |
| be invoked (if present in the returned uffdio_api.ioctls bitmask) to |
| register a memory range in the userfaultfd by setting the |
| uffdio_register structure accordingly. The uffdio_register.mode |
| bitmask will specify to the kernel which kind of faults to track for |
| the range (UFFDIO_REGISTER_MODE_MISSING would track missing |
| pages). The UFFDIO_REGISTER ioctl will return the |
| uffdio_register.ioctls bitmask of ioctls that are suitable to resolve |
| userfaults on the range registered. Not all ioctls will necessarily be |
| supported for all memory types depending on the underlying virtual |
| memory backend (anonymous memory vs tmpfs vs real filebacked |
| mappings). |
| |
| Userland can use the uffdio_register.ioctls to manage the virtual |
| address space in the background (to add or potentially also remove |
| memory from the userfaultfd registered range). This means a userfault |
| could be triggering just before userland maps in the background the |
| user-faulted page. |
| |
| The primary ioctl to resolve userfaults is UFFDIO_COPY. That |
| atomically copies a page into the userfault registered range and wakes |
| up the blocked userfaults (unless uffdio_copy.mode & |
| UFFDIO_COPY_MODE_DONTWAKE is set). Other ioctl works similarly to |
| UFFDIO_COPY. They're atomic as in guaranteeing that nothing can see an |
| half copied page since it'll keep userfaulting until the copy has |
| finished. |
| |
| == QEMU/KVM == |
| |
| QEMU/KVM is using the userfaultfd syscall to implement postcopy live |
| migration. Postcopy live migration is one form of memory |
| externalization consisting of a virtual machine running with part or |
| all of its memory residing on a different node in the cloud. The |
| userfaultfd abstraction is generic enough that not a single line of |
| KVM kernel code had to be modified in order to add postcopy live |
| migration to QEMU. |
| |
| Guest async page faults, FOLL_NOWAIT and all other GUP features work |
| just fine in combination with userfaults. Userfaults trigger async |
| page faults in the guest scheduler so those guest processes that |
| aren't waiting for userfaults (i.e. network bound) can keep running in |
| the guest vcpus. |
| |
| It is generally beneficial to run one pass of precopy live migration |
| just before starting postcopy live migration, in order to avoid |
| generating userfaults for readonly guest regions. |
| |
| The implementation of postcopy live migration currently uses one |
| single bidirectional socket but in the future two different sockets |
| will be used (to reduce the latency of the userfaults to the minimum |
| possible without having to decrease /proc/sys/net/ipv4/tcp_wmem). |
| |
| The QEMU in the source node writes all pages that it knows are missing |
| in the destination node, into the socket, and the migration thread of |
| the QEMU running in the destination node runs UFFDIO_COPY|ZEROPAGE |
| ioctls on the userfaultfd in order to map the received pages into the |
| guest (UFFDIO_ZEROCOPY is used if the source page was a zero page). |
| |
| A different postcopy thread in the destination node listens with |
| poll() to the userfaultfd in parallel. When a POLLIN event is |
| generated after a userfault triggers, the postcopy thread read() from |
| the userfaultfd and receives the fault address (or -EAGAIN in case the |
| userfault was already resolved and waken by a UFFDIO_COPY|ZEROPAGE run |
| by the parallel QEMU migration thread). |
| |
| After the QEMU postcopy thread (running in the destination node) gets |
| the userfault address it writes the information about the missing page |
| into the socket. The QEMU source node receives the information and |
| roughly "seeks" to that page address and continues sending all |
| remaining missing pages from that new page offset. Soon after that |
| (just the time to flush the tcp_wmem queue through the network) the |
| migration thread in the QEMU running in the destination node will |
| receive the page that triggered the userfault and it'll map it as |
| usual with the UFFDIO_COPY|ZEROPAGE (without actually knowing if it |
| was spontaneously sent by the source or if it was an urgent page |
| requested through an userfault). |
| |
| By the time the userfaults start, the QEMU in the destination node |
| doesn't need to keep any per-page state bitmap relative to the live |
| migration around and a single per-page bitmap has to be maintained in |
| the QEMU running in the source node to know which pages are still |
| missing in the destination node. The bitmap in the source node is |
| checked to find which missing pages to send in round robin and we seek |
| over it when receiving incoming userfaults. After sending each page of |
| course the bitmap is updated accordingly. It's also useful to avoid |
| sending the same page twice (in case the userfault is read by the |
| postcopy thread just before UFFDIO_COPY|ZEROPAGE runs in the migration |
| thread). |
