1SEMOP(2) Linux Programmer's Manual SEMOP(2)
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6 semop, semtimedop - System V semaphore operations
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9 #include <sys/types.h>
10 #include <sys/ipc.h>
11 #include <sys/sem.h>
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13 int semop(int semid, struct sembuf *sops, size_t nsops);
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15 int semtimedop(int semid, struct sembuf *sops, size_t nsops,
16 const struct timespec *timeout);
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18 Feature Test Macro Requirements for glibc (see feature_test_macros(7)):
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20 semtimedop(): _GNU_SOURCE
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23 Each semaphore in a System V semaphore set has the following associated
24 values:
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26 unsigned short semval; /* semaphore value */
27 unsigned short semzcnt; /* # waiting for zero */
28 unsigned short semncnt; /* # waiting for increase */
29 pid_t sempid; /* PID of process that last
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31 semop() performs operations on selected semaphores in the set indicated
32 by semid. Each of the nsops elements in the array pointed to by sops
33 is a structure that specifies an operation to be performed on a single
34 semaphore. The elements of this structure are of type struct sembuf,
35 containing the following members:
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37 unsigned short sem_num; /* semaphore number */
38 short sem_op; /* semaphore operation */
39 short sem_flg; /* operation flags */
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41 Flags recognized in sem_flg are IPC_NOWAIT and SEM_UNDO. If an opera‐
42 tion specifies SEM_UNDO, it will be automatically undone when the
43 process terminates.
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45 The set of operations contained in sops is performed in array order,
46 and atomically, that is, the operations are performed either as a com‐
47 plete unit, or not at all. The behavior of the system call if not all
48 operations can be performed immediately depends on the presence of the
49 IPC_NOWAIT flag in the individual sem_flg fields, as noted below.
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51 Each operation is performed on the sem_num-th semaphore of the sema‐
52 phore set, where the first semaphore of the set is numbered 0. There
53 are three types of operation, distinguished by the value of sem_op.
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55 If sem_op is a positive integer, the operation adds this value to the
56 semaphore value (semval). Furthermore, if SEM_UNDO is specified for
57 this operation, the system subtracts the value sem_op from the sema‐
58 phore adjustment (semadj) value for this semaphore. This operation can
59 always proceed—it never forces a thread to wait. The calling process
60 must have alter permission on the semaphore set.
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62 If sem_op is zero, the process must have read permission on the sema‐
63 phore set. This is a "wait-for-zero" operation: if semval is zero, the
64 operation can immediately proceed. Otherwise, if IPC_NOWAIT is speci‐
65 fied in sem_flg, semop() fails with errno set to EAGAIN (and none of
66 the operations in sops is performed). Otherwise, semzcnt (the count of
67 threads waiting until this semaphore's value becomes zero) is incre‐
68 mented by one and the thread sleeps until one of the following occurs:
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70 · semval becomes 0, at which time the value of semzcnt is decremented.
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72 · The semaphore set is removed: semop() fails, with errno set to
73 EIDRM.
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75 · The calling thread catches a signal: the value of semzcnt is decre‐
76 mented and semop() fails, with errno set to EINTR.
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78 If sem_op is less than zero, the process must have alter permission on
79 the semaphore set. If semval is greater than or equal to the absolute
80 value of sem_op, the operation can proceed immediately: the absolute
81 value of sem_op is subtracted from semval, and, if SEM_UNDO is speci‐
82 fied for this operation, the system adds the absolute value of sem_op
83 to the semaphore adjustment (semadj) value for this semaphore. If the
84 absolute value of sem_op is greater than semval, and IPC_NOWAIT is
85 specified in sem_flg, semop() fails, with errno set to EAGAIN (and none
86 of the operations in sops is performed). Otherwise, semncnt (the
87 counter of threads waiting for this semaphore's value to increase) is
88 incremented by one and the thread sleeps until one of the following
89 occurs:
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91 · semval becomes greater than or equal to the absolute value of
92 sem_op: the operation now proceeds, as described above.
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94 · The semaphore set is removed from the system: semop() fails, with
95 errno set to EIDRM.
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97 · The calling thread catches a signal: the value of semncnt is decre‐
98 mented and semop() fails, with errno set to EINTR.
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100 On successful completion, the sempid value for each semaphore specified
101 in the array pointed to by sops is set to the caller's process ID. In
102 addition, the sem_otime is set to the current time.
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104 semtimedop()
105 semtimedop() behaves identically to semop() except that in those cases
106 where the calling thread would sleep, the duration of that sleep is
107 limited by the amount of elapsed time specified by the timespec struc‐
108 ture whose address is passed in the timeout argument. (This sleep
109 interval will be rounded up to the system clock granularity, and kernel
110 scheduling delays mean that the interval may overrun by a small
111 amount.) If the specified time limit has been reached, semtimedop()
112 fails with errno set to EAGAIN (and none of the operations in sops is
113 performed). If the timeout argument is NULL, then semtimedop() behaves
114 exactly like semop().
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116 Note that if semtimedop() is interrupted by a signal, causing the call
117 to fail with the error EINTR, the contents of timeout are left
118 unchanged.
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121 If successful, semop() and semtimedop() return 0; otherwise they return
122 -1 with errno indicating the error.
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125 On failure, errno is set to one of the following:
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127 E2BIG The argument nsops is greater than SEMOPM, the maximum number of
128 operations allowed per system call.
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130 EACCES The calling process does not have the permissions required to
131 perform the specified semaphore operations, and does not have
132 the CAP_IPC_OWNER capability in the user namespace that governs
133 its IPC namespace.
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135 EAGAIN An operation could not proceed immediately and either IPC_NOWAIT
136 was specified in sem_flg or the time limit specified in timeout
137 expired.
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139 EFAULT An address specified in either the sops or the timeout argument
140 isn't accessible.
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142 EFBIG For some operation the value of sem_num is less than 0 or
143 greater than or equal to the number of semaphores in the set.
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145 EIDRM The semaphore set was removed.
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147 EINTR While blocked in this system call, the thread caught a signal;
148 see signal(7).
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150 EINVAL The semaphore set doesn't exist, or semid is less than zero, or
151 nsops has a nonpositive value.
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153 ENOMEM The sem_flg of some operation specified SEM_UNDO and the system
154 does not have enough memory to allocate the undo structure.
155
156 ERANGE For some operation sem_op+semval is greater than SEMVMX, the
157 implementation dependent maximum value for semval.
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160 semtimedop() first appeared in Linux 2.5.52, and was subsequently back‐
161 ported into kernel 2.4.22. Glibc support for semtimedop() first
162 appeared in version 2.3.3.
163
165 POSIX.1-2001, POSIX.1-2008, SVr4.
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168 The inclusion of <sys/types.h> and <sys/ipc.h> isn't required on Linux
169 or by any version of POSIX. However, some old implementations required
170 the inclusion of these header files, and the SVID also documented their
171 inclusion. Applications intended to be portable to such old systems
172 may need to include these header files.
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174 The sem_undo structures of a process aren't inherited by the child pro‐
175 duced by fork(2), but they are inherited across an execve(2) system
176 call.
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178 semop() is never automatically restarted after being interrupted by a
179 signal handler, regardless of the setting of the SA_RESTART flag when
180 establishing a signal handler.
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182 A semaphore adjustment (semadj) value is a per-process, per-semaphore
183 integer that is the negated sum of all operations performed on a sema‐
184 phore specifying the SEM_UNDO flag. Each process has a list of semadj
185 values—one value for each semaphore on which it has operated using
186 SEM_UNDO. When a process terminates, each of its per-semaphore semadj
187 values is added to the corresponding semaphore, thus undoing the effect
188 of that process's operations on the semaphore (but see BUGS below).
189 When a semaphore's value is directly set using the SETVAL or SETALL
190 request to semctl(2), the corresponding semadj values in all processes
191 are cleared. The clone(2) CLONE_SYSVSEM flag allows more than one
192 process to share a semadj list; see clone(2) for details.
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194 The semval, sempid, semzcnt, and semnct values for a semaphore can all
195 be retrieved using appropriate semctl(2) calls.
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197 Semaphore limits
198 The following limits on semaphore set resources affect the semop()
199 call:
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201 SEMOPM Maximum number of operations allowed for one semop() call.
202 Before Linux 3.19, the default value for this limit was 32.
203 Since Linux 3.19, the default value is 500. On Linux, this
204 limit can be read and modified via the third field of
205 /proc/sys/kernel/sem. Note: this limit should not be raised
206 above 1000, because of the risk of that semop() fails due to
207 kernel memory fragmentation when allocating memory to copy the
208 sops array.
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210 SEMVMX Maximum allowable value for semval: implementation dependent
211 (32767).
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213 The implementation has no intrinsic limits for the adjust on exit maxi‐
214 mum value (SEMAEM), the system wide maximum number of undo structures
215 (SEMMNU) and the per-process maximum number of undo entries system
216 parameters.
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219 When a process terminates, its set of associated semadj structures is
220 used to undo the effect of all of the semaphore operations it performed
221 with the SEM_UNDO flag. This raises a difficulty: if one (or more) of
222 these semaphore adjustments would result in an attempt to decrease a
223 semaphore's value below zero, what should an implementation do? One
224 possible approach would be to block until all the semaphore adjustments
225 could be performed. This is however undesirable since it could force
226 process termination to block for arbitrarily long periods. Another
227 possibility is that such semaphore adjustments could be ignored alto‐
228 gether (somewhat analogously to failing when IPC_NOWAIT is specified
229 for a semaphore operation). Linux adopts a third approach: decreasing
230 the semaphore value as far as possible (i.e., to zero) and allowing
231 process termination to proceed immediately.
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233 In kernels 2.6.x, x <= 10, there is a bug that in some circumstances
234 prevents a thread that is waiting for a semaphore value to become zero
235 from being woken up when the value does actually become zero. This bug
236 is fixed in kernel 2.6.11.
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239 The following code segment uses semop() to atomically wait for the
240 value of semaphore 0 to become zero, and then increment the semaphore
241 value by one.
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243 struct sembuf sops[2];
244 int semid;
245
246 /* Code to set semid omitted */
247
248 sops[0].sem_num = 0; /* Operate on semaphore 0 */
249 sops[0].sem_op = 0; /* Wait for value to equal 0 */
250 sops[0].sem_flg = 0;
251
252 sops[1].sem_num = 0; /* Operate on semaphore 0 */
253 sops[1].sem_op = 1; /* Increment value by one */
254 sops[1].sem_flg = 0;
255
256 if (semop(semid, sops, 2) == -1) {
257 perror("semop");
258 exit(EXIT_FAILURE);
259 }
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262 clone(2), semctl(2), semget(2), sigaction(2), capabilities(7),
263 sem_overview(7), svipc(7), time(7)
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266 This page is part of release 4.16 of the Linux man-pages project. A
267 description of the project, information about reporting bugs, and the
268 latest version of this page, can be found at
269 https://www.kernel.org/doc/man-pages/.
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273Linux 2017-09-15 SEMOP(2)