355 lines
17 KiB
ReStructuredText
355 lines
17 KiB
ReStructuredText
.. _userfaultfd:
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===========
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Userfaultfd
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===========
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Objective
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=========
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Userfaults allow the implementation of on-demand paging from userland
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and more generally they allow userland to take control of various
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memory page faults, something otherwise only the kernel code could do.
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For example userfaults allows a proper and more optimal implementation
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of the ``PROT_NONE+SIGSEGV`` trick.
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Design
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======
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Userspace creates a new userfaultfd, initializes it, and registers one or more
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regions of virtual memory with it. Then, any page faults which occur within the
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region(s) result in a message being delivered to the userfaultfd, notifying
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userspace of the fault.
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The ``userfaultfd`` (aside from registering and unregistering virtual
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memory ranges) provides two primary functionalities:
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1) ``read/POLLIN`` protocol to notify a userland thread of the faults
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happening
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2) various ``UFFDIO_*`` ioctls that can manage the virtual memory regions
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registered in the ``userfaultfd`` that allows userland to efficiently
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resolve the userfaults it receives via 1) or to manage the virtual
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memory in the background
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The real advantage of userfaults if compared to regular virtual memory
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management of mremap/mprotect is that the userfaults in all their
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operations never involve heavyweight structures like vmas (in fact the
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``userfaultfd`` runtime load never takes the mmap_lock for writing).
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Vmas are not suitable for page- (or hugepage) granular fault tracking
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when dealing with virtual address spaces that could span
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Terabytes. Too many vmas would be needed for that.
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The ``userfaultfd``, once created, can also be
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passed using unix domain sockets to a manager process, so the same
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manager process could handle the userfaults of a multitude of
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different processes without them being aware about what is going on
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(well of course unless they later try to use the ``userfaultfd``
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themselves on the same region the manager is already tracking, which
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is a corner case that would currently return ``-EBUSY``).
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API
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===
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Creating a userfaultfd
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----------------------
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There are two ways to create a new userfaultfd, each of which provide ways to
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restrict access to this functionality (since historically userfaultfds which
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handle kernel page faults have been a useful tool for exploiting the kernel).
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The first way, supported since userfaultfd was introduced, is the
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userfaultfd(2) syscall. Access to this is controlled in several ways:
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- Any user can always create a userfaultfd which traps userspace page faults
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only. Such a userfaultfd can be created using the userfaultfd(2) syscall
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with the flag UFFD_USER_MODE_ONLY.
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- In order to also trap kernel page faults for the address space, either the
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process needs the CAP_SYS_PTRACE capability, or the system must have
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vm.unprivileged_userfaultfd set to 1. By default, vm.unprivileged_userfaultfd
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is set to 0.
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The second way, added to the kernel more recently, is by opening
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/dev/userfaultfd and issuing a USERFAULTFD_IOC_NEW ioctl to it. This method
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yields equivalent userfaultfds to the userfaultfd(2) syscall.
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Unlike userfaultfd(2), access to /dev/userfaultfd is controlled via normal
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filesystem permissions (user/group/mode), which gives fine grained access to
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userfaultfd specifically, without also granting other unrelated privileges at
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the same time (as e.g. granting CAP_SYS_PTRACE would do). Users who have access
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to /dev/userfaultfd can always create userfaultfds that trap kernel page faults;
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vm.unprivileged_userfaultfd is not considered.
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Initializing a userfaultfd
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--------------------------
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When first opened the ``userfaultfd`` must be enabled invoking the
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``UFFDIO_API`` ioctl specifying a ``uffdio_api.api`` value set to ``UFFD_API`` (or
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a later API version) which will specify the ``read/POLLIN`` protocol
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userland intends to speak on the ``UFFD`` and the ``uffdio_api.features``
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userland requires. The ``UFFDIO_API`` ioctl if successful (i.e. if the
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requested ``uffdio_api.api`` is spoken also by the running kernel and the
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requested features are going to be enabled) will return into
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``uffdio_api.features`` and ``uffdio_api.ioctls`` two 64bit bitmasks of
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respectively all the available features of the read(2) protocol and
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the generic ioctl available.
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The ``uffdio_api.features`` bitmask returned by the ``UFFDIO_API`` ioctl
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defines what memory types are supported by the ``userfaultfd`` and what
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events, except page fault notifications, may be generated:
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- The ``UFFD_FEATURE_EVENT_*`` flags indicate that various other events
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other than page faults are supported. These events are described in more
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detail below in the `Non-cooperative userfaultfd`_ section.
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- ``UFFD_FEATURE_MISSING_HUGETLBFS`` and ``UFFD_FEATURE_MISSING_SHMEM``
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indicate that the kernel supports ``UFFDIO_REGISTER_MODE_MISSING``
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registrations for hugetlbfs and shared memory (covering all shmem APIs,
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i.e. tmpfs, ``IPCSHM``, ``/dev/zero``, ``MAP_SHARED``, ``memfd_create``,
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etc) virtual memory areas, respectively.
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- ``UFFD_FEATURE_MINOR_HUGETLBFS`` indicates that the kernel supports
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``UFFDIO_REGISTER_MODE_MINOR`` registration for hugetlbfs virtual memory
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areas. ``UFFD_FEATURE_MINOR_SHMEM`` is the analogous feature indicating
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support for shmem virtual memory areas.
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The userland application should set the feature flags it intends to use
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when invoking the ``UFFDIO_API`` ioctl, to request that those features be
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enabled if supported.
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Once the ``userfaultfd`` API has been enabled the ``UFFDIO_REGISTER``
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ioctl should be invoked (if present in the returned ``uffdio_api.ioctls``
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bitmask) to register a memory range in the ``userfaultfd`` by setting the
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uffdio_register structure accordingly. The ``uffdio_register.mode``
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bitmask will specify to the kernel which kind of faults to track for
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the range. The ``UFFDIO_REGISTER`` ioctl will return the
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``uffdio_register.ioctls`` bitmask of ioctls that are suitable to resolve
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userfaults on the range registered. Not all ioctls will necessarily be
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supported for all memory types (e.g. anonymous memory vs. shmem vs.
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hugetlbfs), or all types of intercepted faults.
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Userland can use the ``uffdio_register.ioctls`` to manage the virtual
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address space in the background (to add or potentially also remove
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memory from the ``userfaultfd`` registered range). This means a userfault
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could be triggering just before userland maps in the background the
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user-faulted page.
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Resolving Userfaults
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--------------------
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There are three basic ways to resolve userfaults:
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- ``UFFDIO_COPY`` atomically copies some existing page contents from
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userspace.
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- ``UFFDIO_ZEROPAGE`` atomically zeros the new page.
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- ``UFFDIO_CONTINUE`` maps an existing, previously-populated page.
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These operations are atomic in the sense that they guarantee nothing can
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see a half-populated page, since readers will keep userfaulting until the
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operation has finished.
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By default, these wake up userfaults blocked on the range in question.
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They support a ``UFFDIO_*_MODE_DONTWAKE`` ``mode`` flag, which indicates
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that waking will be done separately at some later time.
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Which ioctl to choose depends on the kind of page fault, and what we'd
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like to do to resolve it:
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- For ``UFFDIO_REGISTER_MODE_MISSING`` faults, the fault needs to be
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resolved by either providing a new page (``UFFDIO_COPY``), or mapping
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the zero page (``UFFDIO_ZEROPAGE``). By default, the kernel would map
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the zero page for a missing fault. With userfaultfd, userspace can
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decide what content to provide before the faulting thread continues.
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- For ``UFFDIO_REGISTER_MODE_MINOR`` faults, there is an existing page (in
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the page cache). Userspace has the option of modifying the page's
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contents before resolving the fault. Once the contents are correct
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(modified or not), userspace asks the kernel to map the page and let the
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faulting thread continue with ``UFFDIO_CONTINUE``.
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Notes:
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- You can tell which kind of fault occurred by examining
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``pagefault.flags`` within the ``uffd_msg``, checking for the
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``UFFD_PAGEFAULT_FLAG_*`` flags.
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- None of the page-delivering ioctls default to the range that you
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registered with. You must fill in all fields for the appropriate
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ioctl struct including the range.
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- You get the address of the access that triggered the missing page
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event out of a struct uffd_msg that you read in the thread from the
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uffd. You can supply as many pages as you want with these IOCTLs.
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Keep in mind that unless you used DONTWAKE then the first of any of
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those IOCTLs wakes up the faulting thread.
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- Be sure to test for all errors including
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(``pollfd[0].revents & POLLERR``). This can happen, e.g. when ranges
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supplied were incorrect.
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Write Protect Notifications
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---------------------------
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This is equivalent to (but faster than) using mprotect and a SIGSEGV
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signal handler.
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Firstly you need to register a range with ``UFFDIO_REGISTER_MODE_WP``.
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Instead of using mprotect(2) you use
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``ioctl(uffd, UFFDIO_WRITEPROTECT, struct *uffdio_writeprotect)``
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while ``mode = UFFDIO_WRITEPROTECT_MODE_WP``
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in the struct passed in. The range does not default to and does not
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have to be identical to the range you registered with. You can write
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protect as many ranges as you like (inside the registered range).
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Then, in the thread reading from uffd the struct will have
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``msg.arg.pagefault.flags & UFFD_PAGEFAULT_FLAG_WP`` set. Now you send
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``ioctl(uffd, UFFDIO_WRITEPROTECT, struct *uffdio_writeprotect)``
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again while ``pagefault.mode`` does not have ``UFFDIO_WRITEPROTECT_MODE_WP``
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set. This wakes up the thread which will continue to run with writes. This
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allows you to do the bookkeeping about the write in the uffd reading
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thread before the ioctl.
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If you registered with both ``UFFDIO_REGISTER_MODE_MISSING`` and
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``UFFDIO_REGISTER_MODE_WP`` then you need to think about the sequence in
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which you supply a page and undo write protect. Note that there is a
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difference between writes into a WP area and into a !WP area. The
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former will have ``UFFD_PAGEFAULT_FLAG_WP`` set, the latter
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``UFFD_PAGEFAULT_FLAG_WRITE``. The latter did not fail on protection but
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you still need to supply a page when ``UFFDIO_REGISTER_MODE_MISSING`` was
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used.
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QEMU/KVM
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========
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QEMU/KVM is using the ``userfaultfd`` syscall to implement postcopy live
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migration. Postcopy live migration is one form of memory
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externalization consisting of a virtual machine running with part or
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all of its memory residing on a different node in the cloud. The
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``userfaultfd`` abstraction is generic enough that not a single line of
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KVM kernel code had to be modified in order to add postcopy live
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migration to QEMU.
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Guest async page faults, ``FOLL_NOWAIT`` and all other ``GUP*`` features work
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just fine in combination with userfaults. Userfaults trigger async
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page faults in the guest scheduler so those guest processes that
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aren't waiting for userfaults (i.e. network bound) can keep running in
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the guest vcpus.
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It is generally beneficial to run one pass of precopy live migration
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just before starting postcopy live migration, in order to avoid
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generating userfaults for readonly guest regions.
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The implementation of postcopy live migration currently uses one
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single bidirectional socket but in the future two different sockets
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will be used (to reduce the latency of the userfaults to the minimum
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possible without having to decrease ``/proc/sys/net/ipv4/tcp_wmem``).
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The QEMU in the source node writes all pages that it knows are missing
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in the destination node, into the socket, and the migration thread of
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the QEMU running in the destination node runs ``UFFDIO_COPY|ZEROPAGE``
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ioctls on the ``userfaultfd`` in order to map the received pages into the
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guest (``UFFDIO_ZEROCOPY`` is used if the source page was a zero page).
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A different postcopy thread in the destination node listens with
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poll() to the ``userfaultfd`` in parallel. When a ``POLLIN`` event is
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generated after a userfault triggers, the postcopy thread read() from
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the ``userfaultfd`` and receives the fault address (or ``-EAGAIN`` in case the
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userfault was already resolved and waken by a ``UFFDIO_COPY|ZEROPAGE`` run
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by the parallel QEMU migration thread).
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After the QEMU postcopy thread (running in the destination node) gets
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the userfault address it writes the information about the missing page
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into the socket. The QEMU source node receives the information and
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roughly "seeks" to that page address and continues sending all
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remaining missing pages from that new page offset. Soon after that
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(just the time to flush the tcp_wmem queue through the network) the
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migration thread in the QEMU running in the destination node will
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receive the page that triggered the userfault and it'll map it as
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usual with the ``UFFDIO_COPY|ZEROPAGE`` (without actually knowing if it
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was spontaneously sent by the source or if it was an urgent page
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requested through a userfault).
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By the time the userfaults start, the QEMU in the destination node
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doesn't need to keep any per-page state bitmap relative to the live
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migration around and a single per-page bitmap has to be maintained in
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the QEMU running in the source node to know which pages are still
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missing in the destination node. The bitmap in the source node is
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checked to find which missing pages to send in round robin and we seek
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over it when receiving incoming userfaults. After sending each page of
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course the bitmap is updated accordingly. It's also useful to avoid
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sending the same page twice (in case the userfault is read by the
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postcopy thread just before ``UFFDIO_COPY|ZEROPAGE`` runs in the migration
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thread).
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Non-cooperative userfaultfd
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===========================
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When the ``userfaultfd`` is monitored by an external manager, the manager
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must be able to track changes in the process virtual memory
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layout. Userfaultfd can notify the manager about such changes using
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the same read(2) protocol as for the page fault notifications. The
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manager has to explicitly enable these events by setting appropriate
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bits in ``uffdio_api.features`` passed to ``UFFDIO_API`` ioctl:
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``UFFD_FEATURE_EVENT_FORK``
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enable ``userfaultfd`` hooks for fork(). When this feature is
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enabled, the ``userfaultfd`` context of the parent process is
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duplicated into the newly created process. The manager
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receives ``UFFD_EVENT_FORK`` with file descriptor of the new
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``userfaultfd`` context in the ``uffd_msg.fork``.
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``UFFD_FEATURE_EVENT_REMAP``
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enable notifications about mremap() calls. When the
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non-cooperative process moves a virtual memory area to a
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different location, the manager will receive
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``UFFD_EVENT_REMAP``. The ``uffd_msg.remap`` will contain the old and
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new addresses of the area and its original length.
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``UFFD_FEATURE_EVENT_REMOVE``
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enable notifications about madvise(MADV_REMOVE) and
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madvise(MADV_DONTNEED) calls. The event ``UFFD_EVENT_REMOVE`` will
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be generated upon these calls to madvise(). The ``uffd_msg.remove``
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will contain start and end addresses of the removed area.
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``UFFD_FEATURE_EVENT_UNMAP``
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enable notifications about memory unmapping. The manager will
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get ``UFFD_EVENT_UNMAP`` with ``uffd_msg.remove`` containing start and
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end addresses of the unmapped area.
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Although the ``UFFD_FEATURE_EVENT_REMOVE`` and ``UFFD_FEATURE_EVENT_UNMAP``
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are pretty similar, they quite differ in the action expected from the
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``userfaultfd`` manager. In the former case, the virtual memory is
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removed, but the area is not, the area remains monitored by the
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``userfaultfd``, and if a page fault occurs in that area it will be
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delivered to the manager. The proper resolution for such page fault is
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to zeromap the faulting address. However, in the latter case, when an
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area is unmapped, either explicitly (with munmap() system call), or
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implicitly (e.g. during mremap()), the area is removed and in turn the
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``userfaultfd`` context for such area disappears too and the manager will
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not get further userland page faults from the removed area. Still, the
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notification is required in order to prevent manager from using
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``UFFDIO_COPY`` on the unmapped area.
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Unlike userland page faults which have to be synchronous and require
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explicit or implicit wakeup, all the events are delivered
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asynchronously and the non-cooperative process resumes execution as
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soon as manager executes read(). The ``userfaultfd`` manager should
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carefully synchronize calls to ``UFFDIO_COPY`` with the events
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processing. To aid the synchronization, the ``UFFDIO_COPY`` ioctl will
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return ``-ENOSPC`` when the monitored process exits at the time of
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``UFFDIO_COPY``, and ``-ENOENT``, when the non-cooperative process has changed
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its virtual memory layout simultaneously with outstanding ``UFFDIO_COPY``
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operation.
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The current asynchronous model of the event delivery is optimal for
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single threaded non-cooperative ``userfaultfd`` manager implementations. A
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synchronous event delivery model can be added later as a new
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``userfaultfd`` feature to facilitate multithreading enhancements of the
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non cooperative manager, for example to allow ``UFFDIO_COPY`` ioctls to
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run in parallel to the event reception. Single threaded
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implementations should continue to use the current async event
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delivery model instead.
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