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MEMFD_CREATE(2)                                                         Linux Programmer's Manual                                                        MEMFD_CREATE(2)

NAME
       memfd_create - create an anonymous file

SYNOPSIS
       #define _GNU_SOURCE         /* See feature_test_macros(7) */
       #include <sys/mman.h>

       int memfd_create(const char *name, unsigned int flags);

DESCRIPTION
       memfd_create()  creates  an  anonymous file and returns a file descriptor that refers to it.  The file behaves like a regular file, and so can be modified, trunā€
       cated, memory-mapped, and so on.  However, unlike a regular file, it lives in RAM and has a volatile backing storage.   Once  all  references  to  the  file  are
       dropped, it is automatically released.  Anonymous memory is used for all backing pages of the file.  Therefore, files created by memfd_create() have the same seā€
       mantics as other anonymous memory allocations such as those allocated using mmap(2) with the MAP_ANONYMOUS flag.

       The initial size of the file is set to 0.  Following the call, the file size should be set using ftruncate(2).  (Alternatively, the  file  may  be  populated  by
       calls to write(2) or similar.)

       The name supplied in name is used as a filename and will be displayed as the target of the corresponding symbolic link in the directory /proc/self/fd/.  The disā€
       played name is always prefixed with memfd: and serves only for debugging purposes.  Names do not affect the behavior of the file descriptor, and as such multiple
       files can have the same name without any side effects.

       The following values may be bitwise ORed in flags to change the behavior of memfd_create():

       MFD_CLOEXEC
              Set the close-on-exec (FD_CLOEXEC) flag on the new file descriptor.  See the description of the O_CLOEXEC flag in open(2) for reasons why this may be useā€
              ful.

       MFD_ALLOW_SEALING
              Allow sealing operations on this file.  See the discussion of the F_ADD_SEALS and F_GET_SEALS operations in fcntl(2), and also NOTES, below.  The  initial
              set of seals is empty.  If this flag is not set, the initial set of seals will be F_SEAL_SEAL, meaning that no other seals can be set on the file.

       MFD_HUGETLB (since Linux 4.14)
              The  anonymous  file will be created in the hugetlbfs filesystem using huge pages.  See the Linux kernel source file Documentation/admin-guide/mm/hugetlbā€
              page.rst for more information about hugetlbfs.  Specifying both MFD_HUGETLB and MFD_ALLOW_SEALING in flags is supported since Linux 4.16.

       MFD_HUGE_2MB, MFD_HUGE_1GB, ...
              Used in conjunction with MFD_HUGETLB to select alternative hugetlb page sizes (respectively, 2 MB, 1 GB, ...)  on systems that  support  multiple  hugetlb
              page sizes.  Definitions for known huge page sizes are included in the header file <linux/memfd.h>.

              For details on encoding huge page sizes not included in the header file, see the discussion of the similarly named constants in mmap(2).

       Unused bits in flags must be 0.

       As  its  return  value,  memfd_create() returns a new file descriptor that can be used to refer to the file.  This file descriptor is opened for both reading and
       writing (O_RDWR) and O_LARGEFILE is set for the file descriptor.

       With respect to fork(2) and execve(2), the usual semantics apply for the file descriptor created by memfd_create().  A copy of the file descriptor  is  inherited
       by the child produced by fork(2) and refers to the same file.  The file descriptor is preserved across execve(2), unless the close-on-exec flag has been set.

RETURN VALUE
       On success, memfd_create() returns a new file descriptor.  On error, -1 is returned and errno is set to indicate the error.

ERRORS
       EFAULT The address in name points to invalid memory.

       EINVAL flags included unknown bits.

       EINVAL name was too long.  (The limit is 249 bytes, excluding the terminating null byte.)

       EINVAL Both MFD_HUGETLB and MFD_ALLOW_SEALING were 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 There was insufficient memory to create a new anonymous file.

VERSIONS
       The memfd_create() system call first appeared in Linux 3.17; glibc support was added in version 2.27.

       EPERM  The  MFD_HUGETLB  flag  was  specified,  but  the  caller  was  not  privileged  (did  not  have  the  CAP_IPC_LOCK capability) and is not a member of the
              sysctl_hugetlb_shm_group group; see the description of /proc/sys/vm/sysctl_hugetlb_shm_group in proc(5).

CONFORMING TO
       The memfd_create() system call is Linux-specific.

NOTES
       The memfd_create() system call provides a simple alternative to manually mounting a tmpfs(5) filesystem and creating and opening a file in that filesystem.   The
       primary purpose of memfd_create() is to create files and associated file descriptors that are used with the file-sealing APIs provided by fcntl(2).

       The  memfd_create() system call also has uses without file sealing (which is why file-sealing is disabled, unless explicitly requested with the MFD_ALLOW_SEALING
       flag).  In particular, it can be used as an alternative to creating files in tmp or as an alternative to using the open(2) O_TMPFILE in cases where there  is  no
       intention to actually link the resulting file into the filesystem.

   File sealing
       In  the absence of file sealing, processes that communicate via shared memory must either trust each other, or take measures to deal with the possibility that an
       untrusted peer may manipulate the shared memory region in problematic ways.  For example, an untrusted peer might modify the contents of the shared memory at any
       time,  or shrink the shared memory region.  The former possibility leaves the local process vulnerable to time-of-check-to-time-of-use race conditions (typically
       dealt with by copying data from the shared memory region before checking and using it).  The latter possibility leaves the local  process  vulnerable  to  SIGBUS
       signals  when an attempt is made to access a now-nonexistent location in the shared memory region.  (Dealing with this possibility necessitates the use of a hanā€
       dler for the SIGBUS signal.)

       Dealing with untrusted peers imposes extra complexity on code that employs shared memory.  Memory sealing enables that extra complexity to be eliminated, by  alā€
       lowing a process to operate secure in the knowledge that its peer can't modify the shared memory in an undesired fashion.

       An example of the usage of the sealing mechanism is as follows:

       1. The first process creates a tmpfs(5) file using memfd_create().  The call yields a file descriptor used in subsequent steps.

       2. The  first  process  sizes  the  file created in the previous step using ftruncate(2), maps it using mmap(2), and populates the shared memory with the desired
          data.

       3. The first process uses the fcntl(2) F_ADD_SEALS operation to place one or more seals on the file, in order to restrict further modifications on the file.  (If
          placing the seal F_SEAL_WRITE, then it will be necessary to first unmap the shared writable mapping created in the previous step.  Otherwise, behavior similar
          to F_SEAL_WRITE can be achieved by using F_SEAL_FUTURE_WRITE, which will prevent future writes via mmap(2) and write(2) from succeeding while keeping existing
          shared writable mappings).

       4. A second process obtains a file descriptor for the tmpfs(5) file and maps it.  Among the possible ways in which this could happen are the following:

          *  The  process  that  called  memfd_create()  could  transfer  the  resulting file descriptor to the second process via a UNIX domain socket (see unix(7) and
             cmsg(3)).  The second process then maps the file using mmap(2).

          *  The second process is created via fork(2) and thus automatically inherits the file descriptor and mapping.  (Note that in this case and the next, there  is
             a  natural trust relationship between the two processes, since they are running under the same user ID.  Therefore, file sealing would not normally be necā€
             essary.)

          *  The second process opens the file /proc/<pid>/fd/<fd>, where <pid> is the PID of the first process (the one that called memfd_create()), and  <fd>  is  the
             number of the file descriptor returned by the call to memfd_create() in that process.  The second process then maps the file using mmap(2).

       5. The  second  process  uses  the  fcntl(2) F_GET_SEALS operation to retrieve the bit mask of seals that has been applied to the file.  This bit mask can be inā€
          spected in order to determine what kinds of restrictions have been placed on file modifications.  If desired, the second process can apply  further  seals  to
          impose additional restrictions (so long as the F_SEAL_SEAL seal has not yet been applied).

EXAMPLES
       Below are shown two example programs that demonstrate the use of memfd_create() and the file sealing API.

       The  first  program,  t_memfd_create.c,  creates  a tmpfs(5) file using memfd_create(), sets a size for the file, maps it into memory, and optionally places some
       seals on the file.  The program accepts up to three command-line arguments, of which the first two are required.  The first argument is  the  name  to  associate
       with  the file, the second argument is the size to be set for the file, and the optional third argument is a string of characters that specify seals to be set on
       file.

       The second program, t_get_seals.c, can be used to open an existing file that was created via memfd_create() and inspect the set of seals that have  been  applied
       to that file.

       The following shell session demonstrates the use of these programs.  First we create a tmpfs(5) file and set some seals on it:

           $ ./t_memfd_create my_memfd_file 4096 sw &
           [1] 11775
           PID: 11775; fd: 3; /proc/11775/fd/3

       At  this  point,  the  t_memfd_create  program continues to run in the background.  From another program, we can obtain a file descriptor for the file created by
       memfd_create() by opening the /proc/[pid]/fd file that corresponds to the file descriptor opened by memfd_create().  Using that pathname, we inspect the  content
       of the /proc/[pid]/fd symbolic link, and use our t_get_seals program to view the seals that have been placed on the file:

           $ readlink /proc/11775/fd/3
           /memfd:my_memfd_file (deleted)
           $ ./t_get_seals /proc/11775/fd/3
           Existing seals: WRITE SHRINK

   Program source: t_memfd_create.c

       #define _GNU_SOURCE
       #include <stdint.h>
       #include <sys/mman.h>
       #include <fcntl.h>
       #include <stdlib.h>
       #include <unistd.h>
       #include <string.h>
       #include <stdio.h>

       #define errExit(msg)    do { perror(msg); exit(EXIT_FAILURE); \
                               } while (0)

       int
       main(int argc, char *argv[])
       {
           int fd;
           unsigned int seals;
           char *addr;
           char *name, *seals_arg;
           ssize_t len;

           if (argc < 3) {
               fprintf(stderr, "%s name size [seals]\n", argv[0]);
               fprintf(stderr, "\t'seals' can contain any of the "
                       "following characters:\n");
               fprintf(stderr, "\t\tg - F_SEAL_GROW\n");
               fprintf(stderr, "\t\ts - F_SEAL_SHRINK\n");
               fprintf(stderr, "\t\tw - F_SEAL_WRITE\n");
               fprintf(stderr, "\t\tW - F_SEAL_FUTURE_WRITE\n");
               fprintf(stderr, "\t\tS - F_SEAL_SEAL\n");
               exit(EXIT_FAILURE);
           }

           name = argv[1];
           len = atoi(argv[2]);
           seals_arg = argv[3];

           /* Create an anonymous file in tmpfs; allow seals to be
              placed on the file. */

           fd = memfd_create(name, MFD_ALLOW_SEALING);
           if (fd == -1)
               errExit("memfd_create");

           /* Size the file as specified on the command line. */

           if (ftruncate(fd, len) == -1)
               errExit("truncate");

           printf("PID: %jd; fd: %d; /proc/%jd/fd/%d\n",
                   (intmax_t) getpid(), fd, (intmax_t) getpid(), fd);

           /* Code to map the file and populate the mapping with data
              omitted. */

           /* If a 'seals' command-line argument was supplied, set some
              seals on the file. */

           if (seals_arg != NULL) {
               seals = 0;

               if (strchr(seals_arg, 'g') != NULL)
                   seals |= F_SEAL_GROW;
               if (strchr(seals_arg, 's') != NULL)
                   seals |= F_SEAL_SHRINK;
               if (strchr(seals_arg, 'w') != NULL)
                   seals |= F_SEAL_WRITE;
               if (strchr(seals_arg, 'W') != NULL)
                   seals |= F_SEAL_FUTURE_WRITE;
               if (strchr(seals_arg, 'S') != NULL)
                   seals |= F_SEAL_SEAL;

               if (fcntl(fd, F_ADD_SEALS, seals) == -1)
                   errExit("fcntl");
           }

           /* Keep running, so that the file created by memfd_create()
              continues to exist. */

           pause();

           exit(EXIT_SUCCESS);
       }

   Program source: t_get_seals.c

       #define _GNU_SOURCE
       #include <sys/mman.h>
       #include <fcntl.h>
       #include <unistd.h>
       #include <stdlib.h>
       #include <string.h>
       #include <stdio.h>

       #define errExit(msg)    do { perror(msg); exit(EXIT_FAILURE); \
                               } while (0)

       int
       main(int argc, char *argv[])
       {
           int fd;
           unsigned int seals;

           if (argc != 2) {
               fprintf(stderr, "%s /proc/PID/fd/FD\n", argv[0]);
               exit(EXIT_FAILURE);
           }

           fd = open(argv[1], O_RDWR);
           if (fd == -1)
               errExit("open");

           seals = fcntl(fd, F_GET_SEALS);
           if (seals == -1)
               errExit("fcntl");

           printf("Existing seals:");
           if (seals & F_SEAL_SEAL)
               printf(" SEAL");
           if (seals & F_SEAL_GROW)
               printf(" GROW");
           if (seals & F_SEAL_WRITE)
               printf(" WRITE");
           if (seals & F_SEAL_FUTURE_WRITE)
               printf(" FUTURE_WRITE");
           if (seals & F_SEAL_SHRINK)
               printf(" SHRINK");
           printf("\n");

           /* Code to map the file and access the contents of the
              resulting mapping omitted. */

           exit(EXIT_SUCCESS);
       }

SEE ALSO
       fcntl(2), ftruncate(2), memfd_secret(2), mmap(2), shmget(2), shm_open(3)

Linux                                                                          2021-03-22                                                                MEMFD_CREATE(2)