Movatterモバイル変換

futex(2) — Linux manual page

NAME \|LIBRARY \|SYNOPSIS \|DESCRIPTION \|RETURN VALUE \|ERRORS \|STANDARDS \|HISTORY \|EXAMPLES \|SEE ALSO \|COLOPHON

futex(2)                   System Calls Manualfutex(2)

NAME top

       futex - fast user-space locking

LIBRARY top

       Standard C library (libc,-lc)

SYNOPSIS top

#include <linux/futex.h>/* Definition ofFUTEX_*constants */#include <sys/syscall.h>/* Definition ofSYS_*constants */#include <unistd.h>long syscall(SYS_futex, uint32_t *uaddr, intop, ...);

DESCRIPTION top

       Thefutex() system call provides a method for waiting until a       certain condition becomes true.  It is typically used as a       blocking construct in the context of shared-memory       synchronization.  When using futexes, the majority of the       synchronization operations are performed in user space.  A user-       space program employs thefutex() system call only when it is       likely that the program has to block for a longer time until the       condition becomes true.  Otherfutex() operations can be used to       wake any processes or threads waiting for a particular condition.       A futex is a 32-bit value—referred to below as afutex word—whose       address is supplied to thefutex() system call.  (Futexes are 32       bits in size on all platforms, including 64-bit systems.)  All       futex operations are governed by this value.  In order to share a       futex between processes, the futex is placed in a region of shared       memory, created using (for example)mmap(2) orshmat(2).  (Thus,       the futex word may have different virtual addresses in different       processes, but these addresses all refer to the same location in       physical memory.)  In a multithreaded program, it is sufficient to       place the futex word in a global variable shared by all threads.       When executing a futex operation that requests to block a thread,       the kernel will block only if the futex word has the value that       the calling thread supplied (as one of the arguments of thefutex() call) as the expected value of the futex word.  The       loading of the futex word's value, the comparison of that value       with the expected value, and the actual blocking will happen       atomically and will be totally ordered with respect to concurrent       operations performed by other threads on the same futex word.       Thus, the futex word is used to connect the synchronization in       user space with the implementation of blocking by the kernel.       Analogously to an atomic compare-and-exchange operation that       potentially changes shared memory, blocking via a futex is an       atomic compare-and-block operation.       One use of futexes is for implementing locks.  The state of the       lock (i.e., acquired or not acquired) can be represented as an       atomically accessed flag in shared memory.  In the uncontended       case, a thread can access or modify the lock state with atomic       instructions, for example atomically changing it from not acquired       to acquired using an atomic compare-and-exchange instruction.       (Such instructions are performed entirely in user mode, and the       kernel maintains no information about the lock state.)  On the       other hand, a thread may be unable to acquire a lock because it is       already acquired by another thread.  It then may pass the lock's       flag as a futex word and the value representing the acquired state       as the expected value to afutex() wait operation.  Thisfutex()       operation will block if and only if the lock is still acquired       (i.e., the value in the futex word still matches the "acquired       state").  When releasing the lock, a thread has to first reset the       lock state to not acquired and then execute a futex operation that       wakes threads blocked on the lock flag used as a futex word (this       can be further optimized to avoid unnecessary wake-ups).  Seefutex(7) for more detail on how to use futexes.       Besides the basic wait and wake-up futex functionality, there are       further futex operations aimed at supporting more complex use       cases.       Note that no explicit initialization or destruction is necessary       to use futexes; the kernel maintains a futex (i.e., the kernel-       internal implementation artifact) only while operations such asFUTEX_WAIT(2const) are being performed on a particular futex word.Arguments       Theuaddr argument points to the futex word.  On all platforms,       futexes are four-byte integers that must be aligned on a four-byte       boundary.  The operation to perform on the futex is specified in       theop argument.Futex operations       Theop argument consists of two parts: a command that specifies       the operation to be performed, bitwise ORed with zero or more       options that modify the behaviour of the operation.  The options       that may be included inop are as follows:FUTEX_PRIVATE_FLAG(since Linux 2.6.22)              This option bit can be employed with all futex operations.              It tells the kernel that the futex is process-private and              not shared with another process (i.e., it is being used for              synchronization only between threads of the same process).              This allows the kernel to make some additional performance              optimizations.              As a convenience,<linux/futex.h> defines a set of              constants with the suffix_PRIVATEthat are equivalents of              all of the operations listed below, but with theFUTEX_PRIVATE_FLAGORed into the constant value.  Thus,              there areFUTEX_WAIT_PRIVATE,FUTEX_WAKE_PRIVATE, and so              on.FUTEX_CLOCK_REALTIME(since Linux 2.6.28)              This option bit can be employed only with theFUTEX_WAIT_BITSET(2const),FUTEX_WAIT_REQUEUE_PI(2const),              (since Linux 4.5)FUTEX_WAIT(2const), and (since Linux              5.14)FUTEX_LOCK_PI2(2const) operations.              If this option is set, the kernel measures thetimeout              against theCLOCK_REALTIMEclock.              If this option is not set, the kernel measures thetimeout              against theCLOCK_MONOTONICclock.       The operation specified inop is one of the following:FUTEX_WAIT(2const)FUTEX_WAKE(2const)FUTEX_FD(2const)FUTEX_REQUEUE(2const)FUTEX_CMP_REQUEUE(2const)FUTEX_WAKE_OP(2const)FUTEX_WAIT_BITSET(2const)FUTEX_WAKE_BITSET(2const)Priority-inheritance futexes       Linux supports priority-inheritance (PI) futexes in order to       handle priority-inversion problems that can be encountered with       normal futex locks.  Priority inversion is the problem that occurs       when a high-priority task is blocked waiting to acquire a lock       held by a low-priority task, while tasks at an intermediate       priority continuously preempt the low-priority task from the CPU.       Consequently, the low-priority task makes no progress toward       releasing the lock, and the high-priority task remains blocked.       Priority inheritance is a mechanism for dealing with the priority-       inversion problem.  With this mechanism, when a high-priority task       becomes blocked by a lock held by a low-priority task, the       priority of the low-priority task is temporarily raised to that of       the high-priority task, so that it is not preempted by any       intermediate level tasks, and can thus make progress toward       releasing the lock.  To be effective, priority inheritance must be       transitive, meaning that if a high-priority task blocks on a lock       held by a lower-priority task that is itself blocked by a lock       held by another intermediate-priority task (and so on, for chains       of arbitrary length), then both of those tasks (or more generally,       all of the tasks in a lock chain) have their priorities raised to       be the same as the high-priority task.       From a user-space perspective, what makes a futex PI-aware is a       policy agreement (described below) between user space and the       kernel about the value of the futex word, coupled with the use of       the PI-futex operations described below.  (Unlike the other futex       operations described above, the PI-futex operations are designed       for the implementation of very specific IPC mechanisms.)       The PI-futex operations described below differ from the other       futex operations in that they impose policy on the use of the       value of the futex word:       •  If the lock is not acquired, the futex word's value shall be 0.       •  If the lock is acquired, the futex word's value shall be the          thread ID (TID; seegettid(2)) of the owning thread.       •  If the lock is owned and there are threads contending for the          lock, then theFUTEX_WAITERSbit shall be set in the futex          word's value; in other words, this value is:              FUTEX_WAITERS | TID          (Note that is invalid for a PI futex word to have no owner andFUTEX_WAITERSset.)       With this policy in place, a user-space application can acquire an       unacquired lock or release a lock using atomic instructions       executed in user mode (e.g., a compare-and-swap operation such ascmpxchg on the x86 architecture).  Acquiring a lock simply       consists of using compare-and-swap to atomically set the futex       word's value to the caller's TID if its previous value was 0.       Releasing a lock requires using compare-and-swap to set the futex       word's value to 0 if the previous value was the expected TID.       If a futex is already acquired (i.e., has a nonzero value),       waiters must employ theFUTEX_LOCK_PI(2const) orFUTEX_LOCK_PI2(2const) operations to acquire the lock.  If other       threads are waiting for the lock, then theFUTEX_WAITERSbit is       set in the futex value; in this case, the lock owner must employ       theFUTEX_UNLOCK_PI(2const) operation to release the lock.       In the cases where callers are forced into the kernel (i.e.,       required to perform afutex() call), they then deal directly with       a so-called RT-mutex, a kernel locking mechanism which implements       the required priority-inheritance semantics.  After the RT-mutex       is acquired, the futex value is updated accordingly, before the       calling thread returns to user space.       It is important to note that the kernel will update the futex       word's value prior to returning to user space.  (This prevents the       possibility of the futex word's value ending up in an invalid       state, such as having an owner but the value being 0, or having       waiters but not having theFUTEX_WAITERSbit set.)       If a futex has an associated RT-mutex in the kernel (i.e., there       are blocked waiters) and the owner of the futex/RT-mutex dies       unexpectedly, then the kernel cleans up the RT-mutex and hands it       over to the next waiter.  This in turn requires that the user-       space value is updated accordingly.  To indicate that this is       required, the kernel sets theFUTEX_OWNER_DIEDbit in the futex       word along with the thread ID of the new owner.  User space can       detect this situation via the presence of theFUTEX_OWNER_DIEDbit       and is then responsible for cleaning up the stale state left over       by the dead owner.       PI futexes are operated on by specifying one of the values listed       below inop.  Note that the PI futex operations must be used as       paired operations and are subject to some additional requirements:       •FUTEX_LOCK_PI(2const),FUTEX_LOCK_PI2(2const), andFUTEX_TRYLOCK_PI(2const) pair withFUTEX_UNLOCK_PI(2const).FUTEX_UNLOCK_PI(2const) must be called only on a futex owned by          the calling thread, as defined by the value policy, otherwise          the errorEPERMresults.       •FUTEX_WAIT_REQUEUE_PI(2const) pairs withFUTEX_CMP_REQUEUE_PI(2const).  This must be performed from a          non-PI futex to a distinct PI futex (or the errorEINVAL          results).  Additionally, the number of waiters to be woken must          be 1 (or the errorEINVALresults).       The PI futex operations are as follows:FUTEX_LOCK_PI(2const)FUTEX_LOCK_PI2(2const)FUTEX_TRYLOCK_PI(2const)FUTEX_UNLOCK_PI(2const)FUTEX_CMP_REQUEUE_PI(2const)FUTEX_WAIT_REQUEUE_PI(2const)       TheFUTEX_WAIT_REQUEUE_PI(2const) andFUTEX_CMP_REQUEUE_PI(2const)       were added to support a fairly specific use case: support for       priority-inheritance-aware POSIX threads condition variables.  The       idea is that these operations should always be paired, in order to       ensure that user space and the kernel remain in sync.  Thus, in       theFUTEX_WAIT_REQUEUE_PI(2const) operation, the user-space       application pre-specifies the target of the requeue that takes       place in theFUTEX_CMP_REQUEUE_PI(2const) operation.

RETURN VALUE top

       On error, -1 is returned, anderrno is set to indicate the error.       The return value on success depends on the operation.

ERRORS top

EACCESNo read access to the memory of a futex word.EFAULTuaddr did not point to a valid user-space address.EINVALuaddr does not point to a valid object—that is, the address              is not four-byte-aligned.EINVALInvalid argument.ENOSYSInvalid operation specified inop.ENOSYSTheFUTEX_CLOCK_REALTIMEoption was specified inop, but              the accompanying operation was neitherFUTEX_WAIT_BITSET(2const),FUTEX_WAIT_REQUEUE_PI(2const),              norFUTEX_LOCK_PI2(2const).

STANDARDS top

       Linux.

HISTORY top

       Linux 2.6.0.       Initial futex support was merged in Linux 2.5.7 but with different       semantics from what was described above.  A four-argument system       call with the semantics described in this page was introduced in       Linux 2.5.40.  A fifth argument was added in Linux 2.5.70, and a       sixth argument was added in Linux 2.6.7.

EXAMPLES top

       The program below demonstrates use of futexes in a program where a       parent process and a child process use a pair of futexes located       inside a shared anonymous mapping to synchronize access to a       shared resource: the terminal.  The two processes each writenloops (a command-line argument that defaults to 5 if omitted)       messages to the terminal and employ a synchronization protocol       that ensures that they alternate in writing messages.  Upon       running this program we see output such as the following:           $./futex_demo;           Parent (18534) 0           Child  (18535) 0           Parent (18534) 1           Child  (18535) 1           Parent (18534) 2           Child  (18535) 2           Parent (18534) 3           Child  (18535) 3           Parent (18534) 4           Child  (18535) 4Program source       /* futex_demo.c          Usage: futex_demo [nloops]                           (Default: 5)          Demonstrate the use of futexes in a program where parent and child          use a pair of futexes located inside a shared anonymous mapping to          synchronize access to a shared resource: the terminal. The two          processes each write 'num-loops' messages to the terminal and employ          a synchronization protocol that ensures that they alternate in          writing messages.       */       #define _GNU_SOURCE       #include <err.h>       #include <errno.h>       #include <linux/futex.h>       #include <stdatomic.h>       #include <stdint.h>       #include <stdio.h>       #include <stdlib.h>       #include <sys/mman.h>       #include <sys/syscall.h>       #include <sys/time.h>       #include <sys/wait.h>       #include <unistd.h>       static uint32_t *futex1, *futex2, *iaddr;       static int       futex(uint32_t *uaddr, int op, uint32_t val,             const struct timespec *timeout, uint32_t *uaddr2, uint32_t val3)       {           return syscall(SYS_futex, uaddr, op, val,                          timeout, uaddr2, val3);       }       /* Acquire the futex pointed to by 'futexp': wait for its value to          become 1, and then set the value to 0. */       static void       fwait(uint32_t *futexp)       {           long            s;           const uint32_t  one = 1;           /* atomic_compare_exchange_strong(ptr, oldval, newval)              atomically performs the equivalent of:                  if (*ptr == *oldval)                      *ptr = newval;              It returns true if the test yielded true and *ptr was updated. */           while (1) {               /* Is the futex available? */               if (atomic_compare_exchange_strong(futexp, &one, 0))                   break;      /* Yes */               /* Futex is not available; wait. */               s = futex(futexp, FUTEX_WAIT, 0, NULL, NULL, 0);               if (s == -1 && errno != EAGAIN)                   err(EXIT_FAILURE, "futex-FUTEX_WAIT");           }       }       /* Release the futex pointed to by 'futexp': if the futex currently          has the value 0, set its value to 1 and then wake any futex waiters,          so that if the peer is blocked in fwait(), it can proceed. */       static void       fpost(uint32_t *futexp)       {           long            s;           const uint32_t  zero = 0;           /* atomic_compare_exchange_strong() was described              in comments above. */           if (atomic_compare_exchange_strong(futexp, &zero, 1)) {               s = futex(futexp, FUTEX_WAKE, 1, NULL, NULL, 0);               if (s  == -1)                   err(EXIT_FAILURE, "futex-FUTEX_WAKE");           }       }       int       main(int argc, char *argv[])       {           pid_t         childPid;           unsigned int  nloops;           setbuf(stdout, NULL);           nloops = (argc > 1) ? atoi(argv[1]) : 5;           /* Create a shared anonymous mapping that will hold the futexes.              Since the futexes are being shared between processes, we              subsequently use the "shared" futex operations (i.e., not the              ones suffixed "_PRIVATE"). */           iaddr = mmap(NULL, sizeof(*iaddr) * 2, PROT_READ | PROT_WRITE,                        MAP_ANONYMOUS | MAP_SHARED, -1, 0);           if (iaddr == MAP_FAILED)               err(EXIT_FAILURE, "mmap");           futex1 = &iaddr[0];           futex2 = &iaddr[1];           *futex1 = 0;        /* State: unavailable */           *futex2 = 1;        /* State: available */           /* Create a child process that inherits the shared anonymous              mapping. */           childPid = fork();           if (childPid == -1)               err(EXIT_FAILURE, "fork");           if (childPid == 0) {        /* Child */               for (unsigned int j = 0; j < nloops; j++) {                   fwait(futex1);                   printf("Child  (%jd) %u\n", (intmax_t) getpid(), j);                   fpost(futex2);               }               exit(EXIT_SUCCESS);           }           /* Parent falls through to here. */           for (unsigned int j = 0; j < nloops; j++) {               fwait(futex2);               printf("Parent (%jd) %u\n", (intmax_t) getpid(), j);               fpost(futex1);           }           wait(NULL);           exit(EXIT_SUCCESS);       }

COLOPHON top

       This page is part of theman-pages (Linux kernel and C library       user-space interface documentation) project.  Information about       the project can be found at        ⟨https://www.kernel.org/doc/man-pages/⟩.  If you have a bug report       for this manual page, see       ⟨https://git.kernel.org/pub/scm/docs/man-pages/man-pages.git/tree/CONTRIBUTING⟩.       This page was obtained from the tarball man-pages-6.15.tar.gz       fetched from       ⟨https://mirrors.edge.kernel.org/pub/linux/docs/man-pages/⟩ on       2025-08-11.  If you discover any rendering problems in this HTML       version of the page, or you believe there is a better or more up-       to-date source for the page, or you have corrections or       improvements to the information in this COLOPHON (which isnot       part of the original manual page), send a mail to       man-pages@man7.orgLinux man-pages 6.15            2025-05-30futex(2)

Pages that refer to this page:clone(2), eventfd(2), FUTEX_CMP_REQUEUE(2const), FUTEX_CMP_REQUEUE_PI(2const), FUTEX_FD(2const), FUTEX_LOCK_PI2(2const), FUTEX_LOCK_PI(2const), FUTEX_REQUEUE(2const), FUTEX_TRYLOCK_PI(2const), FUTEX_UNLOCK_PI(2const), FUTEX_WAIT(2const), FUTEX_WAIT_BITSET(2const), FUTEX_WAIT_REQUEUE_PI(2const), FUTEX_WAKE(2const), FUTEX_WAKE_OP(2const), get_robust_list(2), mprotect(2), PR_FUTEX_HASH(2const), PR_SET_TIMERSLACK(2const), restart_syscall(2), set_tid_address(2), syscalls(2), io_uring_prep_futex_wait(3), io_uring_prep_futex_waitv(3), io_uring_prep_futex_wake(3), futex(7), pthreads(7), signal(7)