openat2(2) System Calls Manual openat2(2)

openat2 - open and possibly create a file (extended)

Standard C library (libc, -lc)

#include <fcntl.h>          /* Definition of O_* and S_* constants */
#include <linux/openat2.h>  /* Definition of RESOLVE_* constants */
#include <sys/syscall.h>    /* Definition of SYS_* constants */
#include <unistd.h>
long syscall(SYS_openat2, int dirfd, const char *pathname,
             struct open_how *how, size_t size);

Note: glibc provides no wrapper for openat2(), necessitating the use of syscall(2).

The openat2() system call is an extension of openat(2) and provides a superset of its functionality.

The openat2() system call opens the file specified by pathname. If the specified file does not exist, it may optionally (if O_CREAT is specified in how.flags) be created.

As with openat(2), if pathname is a relative pathname, then it is interpreted relative to the directory referred to by the file descriptor dirfd (or the current working directory of the calling process, if dirfd is the special value AT_FDCWD). If pathname is an absolute pathname, then dirfd is ignored (unless how.resolve contains RESOLVE_IN_ROOT, in which case pathname is resolved relative to dirfd).

Rather than taking a single flags argument, an extensible structure (how) is passed to allow for future extensions. The size argument must be specified as sizeof(struct open_how).

The how argument specifies how pathname should be opened, and acts as a superset of the flags and mode arguments to openat(2). This argument is a pointer to an open_how structure, described in open_how(2type).

Any future extensions to openat2() will be implemented as new fields appended to the open_how structure, with a zero value in a new field resulting in the kernel behaving as though that extension field was not present. Therefore, the caller must zero-fill this structure on initialization. (See the "Extensibility" section of the NOTES for more detail on why this is necessary.)

The fields of the open_how structure are as follows:

This field specifies the file creation and file status flags to use when opening the file. All of the O_* flags defined for openat(2) are valid openat2() flag values.
Whereas openat(2) ignores unknown bits in its flags argument, openat2() returns an error if unknown or conflicting flags are specified in how.flags.
This field specifies the mode for the new file, with identical semantics to the mode argument of openat(2).
Whereas openat(2) ignores bits other than those in the range 07777 in its mode argument, openat2() returns an error if how.mode contains bits other than 07777. Similarly, an error is returned if openat2() is called with a nonzero how.mode and how.flags does not contain O_CREAT or O_TMPFILE.
This is a bit-mask of flags that modify the way in which all components of pathname will be resolved. (See path_resolution(7) for background information.)
The primary use case for these flags is to allow trusted programs to restrict how untrusted paths (or paths inside untrusted directories) are resolved. The full list of resolve flags is as follows:
Do not permit the path resolution to succeed if any component of the resolution is not a descendant of the directory indicated by dirfd. This causes absolute symbolic links (and absolute values of pathname) to be rejected.
Currently, this flag also disables magic-link resolution (see below). However, this may change in the future. Therefore, to ensure that magic links are not resolved, the caller should explicitly specify RESOLVE_NO_MAGICLINKS.
Treat the directory referred to by dirfd as the root directory while resolving pathname. Absolute symbolic links are interpreted relative to dirfd. If a prefix component of pathname equates to dirfd, then an immediately following .. component likewise equates to dirfd (just as /.. is traditionally equivalent to /). If pathname is an absolute path, it is also interpreted relative to dirfd.
The effect of this flag is as though the calling process had used chroot(2) to (temporarily) modify its root directory (to the directory referred to by dirfd). However, unlike chroot(2) (which changes the filesystem root permanently for a process), RESOLVE_IN_ROOT allows a program to efficiently restrict path resolution on a per-open basis.
Currently, this flag also disables magic-link resolution. However, this may change in the future. Therefore, to ensure that magic links are not resolved, the caller should explicitly specify RESOLVE_NO_MAGICLINKS.
Disallow all magic-link resolution during path resolution.
Magic links are symbolic link-like objects that are most notably found in proc(5); examples include /proc/pid/exe and /proc/pid/fd/*. (See symlink(7) for more details.)
Unknowingly opening magic links can be risky for some applications. Examples of such risks include the following:
If the process opening a pathname is a controlling process that currently has no controlling terminal (see credentials(7)), then opening a magic link inside /proc/pid/fd that happens to refer to a terminal would cause the process to acquire a controlling terminal.
In a containerized environment, a magic link inside /proc may refer to an object outside the container, and thus may provide a means to escape from the container.
Because of such risks, an application may prefer to disable magic link resolution using the RESOLVE_NO_MAGICLINKS flag.
If the trailing component (i.e., basename) of pathname is a magic link, how.resolve contains RESOLVE_NO_MAGICLINKS, and how.flags contains both O_PATH and O_NOFOLLOW, then an O_PATH file descriptor referencing the magic link will be returned.
Disallow resolution of symbolic links during path resolution. This option implies RESOLVE_NO_MAGICLINKS.
If the trailing component (i.e., basename) of pathname is a symbolic link, how.resolve contains RESOLVE_NO_SYMLINKS, and how.flags contains both O_PATH and O_NOFOLLOW, then an O_PATH file descriptor referencing the symbolic link will be returned.
Note that the effect of the RESOLVE_NO_SYMLINKS flag, which affects the treatment of symbolic links in all of the components of pathname, differs from the effect of the O_NOFOLLOW file creation flag (in how.flags), which affects the handling of symbolic links only in the final component of pathname.
Applications that employ the RESOLVE_NO_SYMLINKS flag are encouraged to make its use configurable (unless it is used for a specific security purpose), as symbolic links are very widely used by end-users. Setting this flag indiscriminately—i.e., for purposes not specifically related to security—for all uses of openat2() may result in spurious errors on previously functional systems. This may occur if, for example, a system pathname that is used by an application is modified (e.g., in a new distribution release) so that a pathname component (now) contains a symbolic link.
Disallow traversal of mount points during path resolution (including all bind mounts). Consequently, pathname must either be on the same mount as the directory referred to by dirfd, or on the same mount as the current working directory if dirfd is specified as AT_FDCWD.
Applications that employ the RESOLVE_NO_XDEV flag are encouraged to make its use configurable (unless it is used for a specific security purpose), as bind mounts are widely used by end-users. Setting this flag indiscriminately—i.e., for purposes not specifically related to security—for all uses of openat2() may result in spurious errors on previously functional systems. This may occur if, for example, a system pathname that is used by an application is modified (e.g., in a new distribution release) so that a pathname component (now) contains a bind mount.
Make the open operation fail unless all path components are already present in the kernel's lookup cache. If any kind of revalidation or I/O is needed to satisfy the lookup, openat2() fails with the error EAGAIN. This is useful in providing a fast-path open that can be performed without resorting to thread offload, or other mechanisms that an application might use to offload slower operations.
If any bits other than those listed above are set in how.resolve, an error is returned.

On success, a new file descriptor is returned. On error, -1 is returned, and errno is set to indicate the error.

The set of errors returned by openat2() includes all of the errors returned by openat(2), as well as the following additional errors:

An extension that this kernel does not support was specified in how. (See the "Extensibility" section of NOTES for more detail on how extensions are handled.)
how.resolve contains either RESOLVE_IN_ROOT or RESOLVE_BENEATH, and the kernel could not ensure that a ".." component didn't escape (due to a race condition or potential attack). The caller may choose to retry the openat2() call.
RESOLVE_CACHED was set, and the open operation cannot be performed using only cached information. The caller should retry without RESOLVE_CACHED set in how.resolve.
An unknown flag or invalid value was specified in how.
mode is nonzero, but how.flags does not contain O_CREAT or O_TMPFILE.
size was smaller than any known version of struct open_how.
how.resolve contains RESOLVE_NO_SYMLINKS, and one of the path components was a symbolic link (or magic link).
how.resolve contains RESOLVE_NO_MAGICLINKS, and one of the path components was a magic link.
how.resolve contains either RESOLVE_IN_ROOT or RESOLVE_BENEATH, and an escape from the root during path resolution was detected.
how.resolve contains RESOLVE_NO_XDEV, and a path component crosses a mount point.

Linux.

Linux 5.6.

The semantics of RESOLVE_BENEATH were modeled after FreeBSD's O_BENEATH.

In order to allow for future extensibility, openat2() requires the user-space application to specify the size of the open_how structure that it is passing. By providing this information, it is possible for openat2() to provide both forwards- and backwards-compatibility, with size acting as an implicit version number. (Because new extension fields will always be appended, the structure size will always increase.) This extensibility design is very similar to other system calls such as sched_setattr(2), perf_event_open(2), and clone3(2).

If we let usize be the size of the structure as specified by the user-space application, and ksize be the size of the structure which the kernel supports, then there are three cases to consider:

If ksize equals usize, then there is no version mismatch and how can be used verbatim.
If ksize is larger than usize, then there are some extension fields that the kernel supports which the user-space application is unaware of. Because a zero value in any added extension field signifies a no-op, the kernel treats all of the extension fields not provided by the user-space application as having zero values. This provides backwards-compatibility.
If ksize is smaller than usize, then there are some extension fields which the user-space application is aware of but which the kernel does not support. Because any extension field must have its zero values signify a no-op, the kernel can safely ignore the unsupported extension fields if they are all-zero. If any unsupported extension fields are nonzero, then -1 is returned and errno is set to E2BIG. This provides forwards-compatibility.

Because the definition of struct open_how may change in the future (with new fields being added when system headers are updated), user-space applications should zero-fill struct open_how to ensure that recompiling the program with new headers will not result in spurious errors at run time. The simplest way is to use a designated initializer:


struct open_how how = { .flags = O_RDWR,
                        .resolve = RESOLVE_IN_ROOT };

or explicitly using memset(3) or similar:


struct open_how how;
memset(&how, 0, sizeof(how));
how.flags = O_RDWR;
how.resolve = RESOLVE_IN_ROOT;

A user-space application that wishes to determine which extensions the running kernel supports can do so by conducting a binary search on size with a structure which has every byte nonzero (to find the largest value which doesn't produce an error of E2BIG).

openat(2), open_how(2type), path_resolution(7), symlink(7)

2024-02-25 Linux man-pages 6.7