1SHM_OPEN(3)                Linux Programmer's Manual               SHM_OPEN(3)
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4

NAME

6       shm_open,  shm_unlink  -  create/open  or  unlink  POSIX  shared memory
7       objects
8

SYNOPSIS

10       #include <sys/mman.h>
11       #include <sys/stat.h>        /* For mode constants */
12       #include <fcntl.h>           /* For O_* constants */
13
14       int shm_open(const char *name, int oflag, mode_t mode);
15
16       int shm_unlink(const char *name);
17
18       Link with -lrt.
19

DESCRIPTION

21       shm_open() creates and opens a new, or opens an existing, POSIX  shared
22       memory  object.   A  POSIX  shared  memory object is in effect a handle
23       which can be used by unrelated processes to mmap(2) the same region  of
24       shared  memory.  The shm_unlink() function performs the converse opera‐
25       tion, removing an object previously created by shm_open().
26
27       The operation of shm_open() is analogous  to  that  of  open(2).   name
28       specifies the shared memory object to be created or opened.  For porta‐
29       ble use, a shared memory object should be identified by a name  of  the
30       form  /somename;  that  is,  a null-terminated string of up to NAME_MAX
31       (i.e., 255) characters consisting of an initial slash, followed by  one
32       or more characters, none of which are slashes.
33
34       oflag  is  a bit mask created by ORing together exactly one of O_RDONLY
35       or O_RDWR and any of the other flags listed here:
36
37       O_RDONLY
38              Open the object for read access.  A shared memory object  opened
39              in this way can be mmap(2)ed only for read (PROT_READ) access.
40
41       O_RDWR Open the object for read-write access.
42
43       O_CREAT
44              Create  the shared memory object if it does not exist.  The user
45              and group ownership of the object are taken from the correspond‐
46              ing  effective IDs of the calling process, and the object's per‐
47              mission bits are set according to the low-order 9 bits of  mode,
48              except  that  those  bits  set in the process file mode creation
49              mask (see umask(2)) are cleared for the new object.   A  set  of
50              macro  constants  which  can be used to define mode is listed in
51              open(2).   (Symbolic  definitions  of  these  constants  can  be
52              obtained by including <sys/stat.h>.)
53
54              A new shared memory object initially has zero length—the size of
55              the object can be set using ftruncate(2).  The  newly  allocated
56              bytes of a shared memory object are automatically initialized to
57              0.
58
59       O_EXCL If O_CREAT was also specified, and a shared memory  object  with
60              the  given  name already exists, return an error.  The check for
61              the existence of the object, and its creation  if  it  does  not
62              exist, are performed atomically.
63
64       O_TRUNC
65              If  the shared memory object already exists, truncate it to zero
66              bytes.
67
68       Definitions  of  these  flag  values  can  be  obtained  by   including
69       <fcntl.h>.
70
71       On  successful  completion  shm_open()  returns  a  new file descriptor
72       referring to the shared memory object.  This file descriptor is guaran‐
73       teed  to  be  the lowest-numbered file descriptor not previously opened
74       within the process.  The FD_CLOEXEC flag (see fcntl(2)) is set for  the
75       file descriptor.
76
77       The  file  descriptor  is  normally  used in subsequent calls to ftrun‐
78       cate(2) (for a newly created object) and  mmap(2).   After  a  call  to
79       mmap(2)  the file descriptor may be closed without affecting the memory
80       mapping.
81
82       The operation of shm_unlink() is analogous to unlink(2): it  removes  a
83       shared  memory  object  name, and, once all processes have unmapped the
84       object, de-allocates and destroys the contents of the associated memory
85       region.   After  a  successful  shm_unlink(), attempts to shm_open() an
86       object with the same name fail (unless O_CREAT was specified, in  which
87       case a new, distinct object is created).
88

RETURN VALUE

90       On  success,  shm_open() returns a file descriptor (a nonnegative inte‐
91       ger).  On failure, shm_open() returns -1.  shm_unlink()  returns  0  on
92       success, or -1 on error.
93

ERRORS

95       On  failure,  errno  is set to indicate the cause of the error.  Values
96       which may appear in errno include the following:
97
98       EACCES Permission to shm_unlink() the shared memory object was denied.
99
100       EACCES Permission was denied to shm_open() name in the specified  mode,
101              or O_TRUNC was specified and the caller does not have write per‐
102              mission on the object.
103
104       EEXIST Both O_CREAT and O_EXCL were specified  to  shm_open()  and  the
105              shared memory object specified by name already exists.
106
107       EINVAL The name argument to shm_open() was invalid.
108
109       EMFILE The per-process limit on the number of open file descriptors has
110              been reached.
111
112       ENAMETOOLONG
113              The length of name exceeds PATH_MAX.
114
115       ENFILE The system-wide limit on the total number of open files has been
116              reached.
117
118       ENOENT An attempt was made to shm_open() a name that did not exist, and
119              O_CREAT was not specified.
120
121       ENOENT An attempt was to made to shm_unlink()  a  name  that  does  not
122              exist.
123

VERSIONS

125       These functions are provided in glibc 2.2 and later.
126

ATTRIBUTES

128       For   an   explanation   of   the  terms  used  in  this  section,  see
129       attributes(7).
130
131       ┌─────────────────────────┬───────────────┬────────────────┐
132Interface                Attribute     Value          
133       ├─────────────────────────┼───────────────┼────────────────┤
134shm_open(), shm_unlink() │ Thread safety │ MT-Safe locale │
135       └─────────────────────────┴───────────────┴────────────────┘
136

CONFORMING TO

138       POSIX.1-2001, POSIX.1-2008.
139
140       POSIX.1-2001 says that the group ownership of a  newly  created  shared
141       memory object is set to either the calling process's effective group ID
142       or "a system default group ID".  POSIX.1-2008 says that the group  own‐
143       ership  may  be  set to either the calling process's effective group ID
144       or, if the object is visible in the filesystem, the  group  ID  of  the
145       parent directory.
146

NOTES

148       POSIX  leaves  the  behavior of the combination of O_RDONLY and O_TRUNC
149       unspecified.  On Linux, this will  successfully  truncate  an  existing
150       shared memory object—this may not be so on other UNIX systems.
151
152       The  POSIX  shared memory object implementation on Linux makes use of a
153       dedicated tmpfs(5) filesystem that is normally mounted under /dev/shm.
154

EXAMPLES

156       The programs below employ POSIX shared memory and POSIX  unnamed  sema‐
157       phores  to  exchange a piece of data.  The "bounce" program (which must
158       be run first) raises the case of a  string  that  is  placed  into  the
159       shared  memory by the "send" program.  Once the data has been modified,
160       the "send" program then prints the contents of the modified shared mem‐
161       ory.  An example execution of the two programs is the following:
162
163           $ ./pshm_ucase_bounce /myshm &
164           [1] 270171
165           $ ./pshm_ucase_send /myshm hello
166           HELLO
167
168       Further detail about these programs is provided below.
169
170   Program source: pshm_ucase.h
171       The following header file is included by both programs below.  Its pri‐
172       mary purpose is to define a structure that will be imposed on the  mem‐
173       ory object that is shared between the two programs.
174
175           #include <sys/mman.h>
176           #include <fcntl.h>
177           #include <semaphore.h>
178           #include <sys/stat.h>
179           #include <stdio.h>
180           #include <stdlib.h>
181           #include <unistd.h>
182
183           #define errExit(msg)    do { perror(msg); exit(EXIT_FAILURE); \
184                                   } while (0)
185
186           #define BUF_SIZE 1024   /* Maximum size for exchanged string */
187
188           /* Define a structure that will be imposed on the shared
189              memory object */
190
191           struct shmbuf {
192               sem_t  sem1;            /* POSIX unnamed semaphore */
193               sem_t  sem2;            /* POSIX unnamed semaphore */
194               size_t cnt;             /* Number of bytes used in 'buf' */
195               char   buf[BUF_SIZE];   /* Data being transferred */
196           };
197
198   Program source: pshm_ucase_bounce.c
199       The  "bounce"  program creates a new shared memory object with the name
200       given in its command-line argument and sizes the object  to  match  the
201       size  of the shmbuf structure defined in the header file.  It then maps
202       the object into the process's address space, and initializes two  POSIX
203       semaphores inside the object to 0.
204
205       After  the  "send"  program has posted the first of the semaphores, the
206       "bounce" program upper cases the data that has been placed in the  mem‐
207       ory  by  the "send" program and then posts the second semaphore to tell
208       the "send" program that it may now access the shared memory.
209
210           /* pshm_ucase_bounce.c
211
212              Licensed under GNU General Public License v2 or later.
213           */
214           #include <ctype.h>
215           #include "pshm_ucase.h"
216
217           int
218           main(int argc, char *argv[])
219           {
220               if (argc != 2) {
221                   fprintf(stderr, "Usage: %s /shm-path\n", argv[0]);
222                   exit(EXIT_FAILURE);
223               }
224
225               char *shmpath = argv[1];
226
227               /* Create shared memory object and set its size to the size
228                  of our structure */
229
230               int fd = shm_open(shmpath, O_CREAT | O_EXCL | O_RDWR,
231                                 S_IRUSR | S_IWUSR);
232               if (fd == -1)
233                   errExit("shm_open");
234
235               if (ftruncate(fd, sizeof(struct shmbuf)) == -1)
236                   errExit("ftruncate");
237
238               /* Map the object into the caller's address space */
239
240               struct shmbuf *shmp = mmap(NULL, sizeof(struct shmbuf),
241                                          PROT_READ | PROT_WRITE,
242                                          MAP_SHARED, fd, 0);
243               if (shmp == MAP_FAILED)
244                   errExit("mmap");
245
246               /* Initialize semaphores as process-shared, with value 0 */
247
248               if (sem_init(&shmp->sem1, 1, 0) == -1)
249                   errExit("sem_init-sem1");
250               if (sem_init(&shmp->sem2, 1, 0) == -1)
251                   errExit("sem_init-sem2");
252
253               /* Wait for 'sem1' to be posted by peer before touching
254                  shared memory */
255
256               if (sem_wait(&shmp->sem1) == -1)
257                   errExit("sem_wait");
258
259               /* Convert data in shared memory into upper case */
260
261               for (int j = 0; j < shmp->cnt; j++)
262                   shmp->buf[j] = toupper((unsigned char) shmp->buf[j]);
263
264               /* Post 'sem2' to tell the to tell peer that it can now
265                  access the modified data in shared memory */
266
267               if (sem_post(&shmp->sem2) == -1)
268                   errExit("sem_post");
269
270               /* Unlink the shared memory object. Even if the peer process
271                  is still using the object, this is okay. The object will
272                  be removed only after all open references are closed. */
273
274               shm_unlink(shmpath);
275
276               exit(EXIT_SUCCESS);
277           }
278
279   Program source: pshm_ucase_send.c
280       The "send" program takes two command-line arguments: the pathname of  a
281       shared  memory  object previously created by the "bounce" program and a
282       string that is to be copied into that object.
283
284       The program opens the shared memory object and maps the object into its
285       address  space.   It then copies the data specified in its second argu‐
286       ment into the shared memory, and posts the first semaphore, which tells
287       the  "bounce"  program  that  it  can  now access that data.  After the
288       "bounce" program posts the second semaphore, the "send" program  prints
289       the contents of the shared memory on standard output.
290
291           /* pshm_ucase_send.c
292
293              Licensed under GNU General Public License v2 or later.
294           */
295           #include <string.h>
296           #include "pshm_ucase.h"
297
298           int
299           main(int argc, char *argv[])
300           {
301               if (argc != 3) {
302                   fprintf(stderr, "Usage: %s /shm-path string\n", argv[0]);
303                   exit(EXIT_FAILURE);
304               }
305
306               char *shmpath = argv[1];
307               char *string = argv[2];
308               size_t len = strlen(string);
309
310               if (len > BUF_SIZE) {
311                   fprintf(stderr, "String is too long\n");
312                   exit(EXIT_FAILURE);
313               }
314
315               /* Open the existing shared memory object and map it
316                  into the caller's address space */
317
318               int fd = shm_open(shmpath, O_RDWR, 0);
319               if (fd == -1)
320                   errExit("shm_open");
321
322               struct shmbuf *shmp = mmap(NULL, sizeof(struct shmbuf),
323                                          PROT_READ | PROT_WRITE,
324                                          MAP_SHARED, fd, 0);
325               if (shmp == MAP_FAILED)
326                   errExit("mmap");
327
328               /* Copy data into the shared memory object */
329
330               shmp->cnt = len;
331               memcpy(&shmp->buf, string, len);
332
333               /* Tell peer that it can now access shared memory */
334
335               if (sem_post(&shmp->sem1) == -1)
336                   errExit("sem_post");
337
338               /* Wait until peer says that it has finished accessing
339                  the shared memory */
340
341               if (sem_wait(&shmp->sem2) == -1)
342                   errExit("sem_wait");
343
344               /* Write modified data in shared memory to standard output */
345
346               write(STDOUT_FILENO, &shmp->buf, len);
347               write(STDOUT_FILENO, "\n", 1);
348
349               exit(EXIT_SUCCESS);
350           }
351

SEE ALSO

353       close(2),   fchmod(2),  fchown(2),  fcntl(2),  fstat(2),  ftruncate(2),
354       memfd_create(2), mmap(2), open(2), umask(2), shm_overview(7)
355

COLOPHON

357       This page is part of release 5.07 of the Linux  man-pages  project.   A
358       description  of  the project, information about reporting bugs, and the
359       latest    version    of    this    page,    can     be     found     at
360       https://www.kernel.org/doc/man-pages/.
361
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364Linux                             2020-04-11                       SHM_OPEN(3)
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