userfaultfd - create a file descriptor for handling page faults in user space
#include <sys/types.h>
#include <linux/userfaultfd.h>
int userfaultfd(int flags);
Note: There is no glibc wrapper for this system call; see NOTES.
userfaultfd() creates a new userfaultfd object that can be used for
delegation of page-fault handling to a user-space application, and returns a
file descriptor that refers to the new object. The new userfaultfd object is
configured using
ioctl(2).
Once the userfaultfd object is configured, the application can use
read(2) to receive userfaultfd notifications. The reads from
userfaultfd may be blocking or non-blocking, depending on the value of
flags used for the creation of the userfaultfd or subsequent calls to
fcntl(2).
The following values may be bitwise ORed in
flags to change the behavior
of
userfaultfd():
- O_CLOEXEC
- Enable the close-on-exec flag for the new userfaultfd file descriptor. See
the description of the O_CLOEXEC flag in open(2).
- O_NONBLOCK
- Enables non-blocking operation for the userfaultfd object. See the
description of the O_NONBLOCK flag in open(2).
When the last file descriptor referring to a userfaultfd object is closed, all
memory ranges that were registered with the object are unregistered and unread
events are flushed.
The userfaultfd mechanism is designed to allow a thread in a multithreaded
program to perform user-space paging for the other threads in the process.
When a page fault occurs for one of the regions registered to the userfaultfd
object, the faulting thread is put to sleep and an event is generated that can
be read via the userfaultfd file descriptor. The fault-handling thread reads
events from this file descriptor and services them using the operations
described in
ioctl_userfaultfd(2). When servicing the page fault
events, the fault-handling thread can trigger a wake-up for the sleeping
thread.
It is possible for the faulting threads and the fault-handling threads to run in
the context of different processes. In this case, these threads may belong to
different programs, and the program that executes the faulting threads will
not necessarily cooperate with the program that handles the page faults. In
such non-cooperative mode, the process that monitors userfaultfd and handles
page faults needs to be aware of the changes in the virtual memory layout of
the faulting process to avoid memory corruption.
Starting from Linux 4.11, userfaultfd can also notify the fault-handling threads
about changes in the virtual memory layout of the faulting process. In
addition, if the faulting process invokes
fork(2), the userfaultfd
objects associated with the parent may be duplicated into the child process
and the userfaultfd monitor will be notified (via the
UFFD_EVENT_FORK
described below) about the file descriptor associated with the userfault
objects created for the child process, which allows the userfaultfd monitor to
perform user-space paging for the child process. Unlike page faults which have
to be synchronous and require an explicit or implicit wakeup, all other events
are delivered asynchronously and the non-cooperative process resumes execution
as soon as the userfaultfd manager executes
read(2). The userfaultfd
manager should carefully synchronize calls to
UFFDIO_COPY with the
processing of events.
The current asynchronous model of the event delivery is optimal for single
threaded non-cooperative userfaultfd manager implementations.
After the userfaultfd object is created with
userfaultfd(), the
application must enable it using the
UFFDIO_API ioctl(2)
operation. This operation allows a handshake between the kernel and user space
to determine the API version and supported features. This operation must be
performed before any of the other
ioctl(2) operations described below
(or those operations fail with the
EINVAL error).
After a successful
UFFDIO_API operation, the application then registers
memory address ranges using the
UFFDIO_REGISTER ioctl(2)
operation. After successful completion of a
UFFDIO_REGISTER operation,
a page fault occurring in the requested memory range, and satisfying the mode
defined at the registration time, will be forwarded by the kernel to the
user-space application. The application can then use the
UFFDIO_COPY or
UFFDIO_ZEROPAGE ioctl(2) operations to resolve the page fault.
Starting from Linux 4.14, if the application sets the
UFFD_FEATURE_SIGBUS
feature bit using the
UFFDIO_API ioctl(2), no page-fault
notification will be forwarded to user space. Instead a
SIGBUS signal
is delivered to the faulting process. With this feature, userfaultfd can be
used for robustness purposes to simply catch any access to areas within the
registered address range that do not have pages allocated, without having to
listen to userfaultfd events. No userfaultfd monitor will be required for
dealing with such memory accesses. For example, this feature can be useful for
applications that want to prevent the kernel from automatically allocating
pages and filling holes in sparse files when the hole is accessed through a
memory mapping.
The
UFFD_FEATURE_SIGBUS feature is implicitly inherited through
fork(2) if used in combination with
UFFD_FEATURE_FORK.
Details of the various
ioctl(2) operations can be found in
ioctl_userfaultfd(2).
Since Linux 4.11, events other than page-fault may enabled during
UFFDIO_API operation.
Up to Linux 4.11, userfaultfd can be used only with anonymous private memory
mappings. Since Linux 4.11, userfaultfd can be also used with hugetlbfs and
shared memory mappings.
Each
read(2) from the userfaultfd file descriptor returns one or more
uffd_msg structures, each of which describes a page-fault event or an
event required for the non-cooperative userfaultfd usage:
struct uffd_msg {
__u8 event; /* Type of event */
...
union {
struct {
__u64 flags; /* Flags describing fault */
__u64 address; /* Faulting address */
} pagefault;
struct { /* Since Linux 4.11 */
__u32 ufd; /* Userfault file descriptor
of the child process */
} fork;
struct { /* Since Linux 4.11 */
__u64 from; /* Old address of remapped area */
__u64 to; /* New address of remapped area */
__u64 len; /* Original mapping length */
} remap;
struct { /* Since Linux 4.11 */
__u64 start; /* Start address of removed area */
__u64 end; /* End address of removed area */
} remove;
...
} arg;
/* Padding fields omitted */
} __packed;
If multiple events are available and the supplied buffer is large enough,
read(2) returns as many events as will fit in the supplied buffer. If
the buffer supplied to
read(2) is smaller than the size of the
uffd_msg structure, the
read(2) fails with the error
EINVAL.
The fields set in the
uffd_msg structure are as follows:
- event
- The type of event. Depending of the event type, different fields of the
arg union represent details required for the event processing. The
non-page-fault events are generated only when appropriate feature is
enabled during API handshake with UFFDIO_API ioctl(2).
- The following values can appear in the event field:
- UFFD_EVENT_PAGEFAULT (since Linux 4.3)
- A page-fault event. The page-fault details are available in the
pagefault field.
- UFFD_EVENT_FORK (since Linux 4.11)
- Generated when the faulting process invokes fork(2) (or
clone(2) without the CLONE_VM flag). The event details are
available in the fork field.
- UFFD_EVENT_REMAP (since Linux 4.11)
- Generated when the faulting process invokes mremap(2). The event
details are available in the remap field.
- UFFD_EVENT_REMOVE (since Linux 4.11)
- Generated when the faulting process invokes madvise(2) with
MADV_DONTNEED or MADV_REMOVE advice. The event details are
available in the remove field.
- UFFD_EVENT_UNMAP (since Linux 4.11)
- Generated when the faulting process unmaps a memory range, either
explicitly using munmap(2) or implicitly during mmap(2) or
mremap(2). The event details are available in the remove
field.
- pagefault.address
- The address that triggered the page fault.
- pagefault.flags
- A bit mask of flags that describe the event. For
UFFD_EVENT_PAGEFAULT, the following flag may appear:
- UFFD_PAGEFAULT_FLAG_WRITE
- If the address is in a range that was registered with the
UFFDIO_REGISTER_MODE_MISSING flag (see ioctl_userfaultfd(2))
and this flag is set, this a write fault; otherwise it is a read
fault.
- fork.ufd
- The file descriptor associated with the userfault object created for the
child created by fork(2).
- remap.from
- The original address of the memory range that was remapped using
mremap(2).
- remap.to
- The new address of the memory range that was remapped using
mremap(2).
- remap.len
- The original length of the memory range that was remapped using
mremap(2).
- remove.start
- The start address of the memory range that was freed using
madvise(2) or unmapped
- remove.end
- The end address of the memory range that was freed using madvise(2)
or unmapped
A
read(2) on a userfaultfd file descriptor can fail with the following
errors:
- EINVAL
- The userfaultfd object has not yet been enabled using the
UFFDIO_API ioctl(2) operation
If the
O_NONBLOCK flag is enabled in the associated open file
description, the userfaultfd file descriptor can be monitored with
poll(2),
select(2), and
epoll(7). When events are
available, the file descriptor indicates as readable. If the
O_NONBLOCK
flag is not enabled, then
poll(2) (always) indicates the file as having
a
POLLERR condition, and
select(2) indicates the file descriptor
as both readable and writable.
On success,
userfaultfd() returns a new file descriptor that refers to
the userfaultfd object. On error, -1 is returned, and
errno is set
appropriately.
- EINVAL
- An unsupported value was specified in flags.
- EMFILE
- The per-process limit on the number of open file descriptors has been
reached
- ENFILE
- The system-wide limit on the total number of open files has been
reached.
- ENOMEM
- Insufficient kernel memory was available.
- EPERM (since Linux 5.2)
- The caller is not privileged (does not have the CAP_SYS_PTRACE
capability in the initial user namespace), and
/proc/sys/vm/unprivileged_userfaultfd has the value 0.
The
userfaultfd() system call first appeared in Linux 4.3.
The support for hugetlbfs and shared memory areas and non-page-fault events was
added in Linux 4.11
userfaultfd() is Linux-specific and should not be used in programs
intended to be portable.
Glibc does not provide a wrapper for this system call; call it using
syscall(2).
The userfaultfd mechanism can be used as an alternative to traditional
user-space paging techniques based on the use of the
SIGSEGV signal and
mmap(2). It can also be used to implement lazy restore for
checkpoint/restore mechanisms, as well as post-copy migration to allow
(nearly) uninterrupted execution when transferring virtual machines and Linux
containers from one host to another.
If the
UFFD_FEATURE_EVENT_FORK is enabled and a system call from the
fork(2) family is interrupted by a signal or failed, a stale
userfaultfd descriptor might be created. In this case, a spurious
UFFD_EVENT_FORK will be delivered to the userfaultfd monitor.
The program below demonstrates the use of the userfaultfd mechanism. The program
creates two threads, one of which acts as the page-fault handler for the
process, for the pages in a demand-page zero region created using
mmap(2).
The program takes one command-line argument, which is the number of pages that
will be created in a mapping whose page faults will be handled via
userfaultfd. After creating a userfaultfd object, the program then creates an
anonymous private mapping of the specified size and registers the address
range of that mapping using the
UFFDIO_REGISTER ioctl(2)
operation. The program then creates a second thread that will perform the task
of handling page faults.
The main thread then walks through the pages of the mapping fetching bytes from
successive pages. Because the pages have not yet been accessed, the first
access of a byte in each page will trigger a page-fault event on the
userfaultfd file descriptor.
Each of the page-fault events is handled by the second thread, which sits in a
loop processing input from the userfaultfd file descriptor. In each loop
iteration, the second thread first calls
poll(2) to check the state of
the file descriptor, and then reads an event from the file descriptor. All
such events should be
UFFD_EVENT_PAGEFAULT events, which the thread
handles by copying a page of data into the faulting region using the
UFFDIO_COPY ioctl(2) operation.
The following is an example of what we see when running the program:
$ ./userfaultfd_demo 3
Address returned by mmap() = 0x7fd30106c000
fault_handler_thread():
poll() returns: nready = 1; POLLIN = 1; POLLERR = 0
UFFD_EVENT_PAGEFAULT event: flags = 0; address = 7fd30106c00f
(uffdio_copy.copy returned 4096)
Read address 0x7fd30106c00f in main(): A
Read address 0x7fd30106c40f in main(): A
Read address 0x7fd30106c80f in main(): A
Read address 0x7fd30106cc0f in main(): A
fault_handler_thread():
poll() returns: nready = 1; POLLIN = 1; POLLERR = 0
UFFD_EVENT_PAGEFAULT event: flags = 0; address = 7fd30106d00f
(uffdio_copy.copy returned 4096)
Read address 0x7fd30106d00f in main(): B
Read address 0x7fd30106d40f in main(): B
Read address 0x7fd30106d80f in main(): B
Read address 0x7fd30106dc0f in main(): B
fault_handler_thread():
poll() returns: nready = 1; POLLIN = 1; POLLERR = 0
UFFD_EVENT_PAGEFAULT event: flags = 0; address = 7fd30106e00f
(uffdio_copy.copy returned 4096)
Read address 0x7fd30106e00f in main(): C
Read address 0x7fd30106e40f in main(): C
Read address 0x7fd30106e80f in main(): C
Read address 0x7fd30106ec0f in main(): C
/* userfaultfd_demo.c
Licensed under the GNU General Public License version 2 or later.
*/
#define _GNU_SOURCE
#include <sys/types.h>
#include <stdio.h>
#include <linux/userfaultfd.h>
#include <pthread.h>
#include <errno.h>
#include <unistd.h>
#include <stdlib.h>
#include <fcntl.h>
#include <signal.h>
#include <poll.h>
#include <string.h>
#include <sys/mman.h>
#include <sys/syscall.h>
#include <sys/ioctl.h>
#include <poll.h>
#define errExit(msg) do { perror(msg); exit(EXIT_FAILURE); \
} while (0)
static int page_size;
static void *
fault_handler_thread(void *arg)
{
static struct uffd_msg msg; /* Data read from userfaultfd */
static int fault_cnt = 0; /* Number of faults so far handled */
long uffd; /* userfaultfd file descriptor */
static char *page = NULL;
struct uffdio_copy uffdio_copy;
ssize_t nread;
uffd = (long) arg;
/* Create a page that will be copied into the faulting region */
if (page == NULL) {
page = mmap(NULL, page_size, PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
if (page == MAP_FAILED)
errExit("mmap");
}
/* Loop, handling incoming events on the userfaultfd
file descriptor */
for (;;) {
/* See what poll() tells us about the userfaultfd */
struct pollfd pollfd;
int nready;
pollfd.fd = uffd;
pollfd.events = POLLIN;
nready = poll(&pollfd, 1, -1);
if (nready == -1)
errExit("poll");
printf("\nfault_handler_thread():\n");
printf(" poll() returns: nready = %d; "
"POLLIN = %d; POLLERR = %d\n", nready,
(pollfd.revents & POLLIN) != 0,
(pollfd.revents & POLLERR) != 0);
/* Read an event from the userfaultfd */
nread = read(uffd, &msg, sizeof(msg));
if (nread == 0) {
printf("EOF on userfaultfd!\n");
exit(EXIT_FAILURE);
}
if (nread == -1)
errExit("read");
/* We expect only one kind of event; verify that assumption */
if (msg.event != UFFD_EVENT_PAGEFAULT) {
fprintf(stderr, "Unexpected event on userfaultfd\n");
exit(EXIT_FAILURE);
}
/* Display info about the page-fault event */
printf(" UFFD_EVENT_PAGEFAULT event: ");
printf("flags = %llx; ", msg.arg.pagefault.flags);
printf("address = %llx\n", msg.arg.pagefault.address);
/* Copy the page pointed to by 'page' into the faulting
region. Vary the contents that are copied in, so that it
is more obvious that each fault is handled separately. */
memset(page, 'A' + fault_cnt % 20, page_size);
fault_cnt++;
uffdio_copy.src = (unsigned long) page;
/* We need to handle page faults in units of pages(!).
So, round faulting address down to page boundary */
uffdio_copy.dst = (unsigned long) msg.arg.pagefault.address &
~(page_size - 1);
uffdio_copy.len = page_size;
uffdio_copy.mode = 0;
uffdio_copy.copy = 0;
if (ioctl(uffd, UFFDIO_COPY, &uffdio_copy) == -1)
errExit("ioctl-UFFDIO_COPY");
printf(" (uffdio_copy.copy returned %lld)\n",
uffdio_copy.copy);
}
}
int
main(int argc, char *argv[])
{
long uffd; /* userfaultfd file descriptor */
char *addr; /* Start of region handled by userfaultfd */
unsigned long len; /* Length of region handled by userfaultfd */
pthread_t thr; /* ID of thread that handles page faults */
struct uffdio_api uffdio_api;
struct uffdio_register uffdio_register;
int s;
if (argc != 2) {
fprintf(stderr, "Usage: %s num-pages\n", argv[0]);
exit(EXIT_FAILURE);
}
page_size = sysconf(_SC_PAGE_SIZE);
len = strtoul(argv[1], NULL, 0) * page_size;
/* Create and enable userfaultfd object */
uffd = syscall(__NR_userfaultfd, O_CLOEXEC | O_NONBLOCK);
if (uffd == -1)
errExit("userfaultfd");
uffdio_api.api = UFFD_API;
uffdio_api.features = 0;
if (ioctl(uffd, UFFDIO_API, &uffdio_api) == -1)
errExit("ioctl-UFFDIO_API");
/* Create a private anonymous mapping. The memory will be
demand-zero paged--that is, not yet allocated. When we
actually touch the memory, it will be allocated via
the userfaultfd. */
addr = mmap(NULL, len, PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
if (addr == MAP_FAILED)
errExit("mmap");
printf("Address returned by mmap() = %p\n", addr);
/* Register the memory range of the mapping we just created for
handling by the userfaultfd object. In mode, we request to track
missing pages (i.e., pages that have not yet been faulted in). */
uffdio_register.range.start = (unsigned long) addr;
uffdio_register.range.len = len;
uffdio_register.mode = UFFDIO_REGISTER_MODE_MISSING;
if (ioctl(uffd, UFFDIO_REGISTER, &uffdio_register) == -1)
errExit("ioctl-UFFDIO_REGISTER");
/* Create a thread that will process the userfaultfd events */
s = pthread_create(&thr, NULL, fault_handler_thread, (void *) uffd);
if (s != 0) {
errno = s;
errExit("pthread_create");
}
/* Main thread now touches memory in the mapping, touching
locations 1024 bytes apart. This will trigger userfaultfd
events for all pages in the region. */
int l;
l = 0xf; /* Ensure that faulting address is not on a page
boundary, in order to test that we correctly
handle that case in fault_handling_thread() */
while (l < len) {
char c = addr[l];
printf("Read address %p in main(): ", addr + l);
printf("%c\n", c);
l += 1024;
usleep(100000); /* Slow things down a little */
}
exit(EXIT_SUCCESS);
}
fcntl(2),
ioctl(2),
ioctl_userfaultfd(2),
madvise(2),
mmap(2)
Documentation/admin-guide/mm/userfaultfd.rst in the Linux kernel source
tree