1PTHREAD_CLEANUP_PUSH(3) Linux Programmer's Manual PTHREAD_CLEANUP_PUSH(3)
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6 pthread_cleanup_push, pthread_cleanup_pop - push and pop thread cancel‐
7 lation clean-up handlers
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10 #include <pthread.h>
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12 void pthread_cleanup_push(void (*routine)(void *),
13 void *arg);
14 void pthread_cleanup_pop(int execute);
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16 Compile and link with -pthread.
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19 These functions manipulate the calling thread's stack of thread-cancel‐
20 lation clean-up handlers. A clean-up handler is a function that is
21 automatically executed when a thread is canceled (or in various other
22 circumstances described below); it might, for example, unlock a mutex
23 so that it becomes available to other threads in the process.
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25 The pthread_cleanup_push() function pushes routine onto the top of the
26 stack of clean-up handlers. When routine is later invoked, it will be
27 given arg as its argument.
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29 The pthread_cleanup_pop() function removes the routine at the top of
30 the stack of clean-up handlers, and optionally executes it if execute
31 is nonzero.
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33 A cancellation clean-up handler is popped from the stack and executed
34 in the following circumstances:
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36 1. When a thread is canceled, all of the stacked clean-up handlers are
37 popped and executed in the reverse of the order in which they were
38 pushed onto the stack.
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40 2. When a thread terminates by calling pthread_exit(3), all clean-up
41 handlers are executed as described in the preceding point. (Clean-
42 up handlers are not called if the thread terminates by performing a
43 return from the thread start function.)
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45 3. When a thread calls pthread_cleanup_pop() with a nonzero execute
46 argument, the top-most clean-up handler is popped and executed.
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48 POSIX.1 permits pthread_cleanup_push() and pthread_cleanup_pop() to be
49 implemented as macros that expand to text containing '{' and '}',
50 respectively. For this reason, the caller must ensure that calls to
51 these functions are paired within the same function, and at the same
52 lexical nesting level. (In other words, a clean-up handler is estab‐
53 lished only during the execution of a specified section of code.)
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55 Calling longjmp(3) (siglongjmp(3)) produces undefined results if any
56 call has been made to pthread_cleanup_push() or pthread_cleanup_pop()
57 without the matching call of the pair since the jump buffer was filled
58 by setjmp(3) (sigsetjmp(3)). Likewise, calling longjmp(3) (sig‐
59 longjmp(3)) from inside a clean-up handler produces undefined results
60 unless the jump buffer was also filled by setjmp(3) (sigsetjmp(3))
61 inside the handler.
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64 These functions do not return a value.
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67 There are no errors.
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70 For an explanation of the terms used in this section, see
71 attributes(7).
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73 ┌────────────────────────┬───────────────┬─────────┐
74 │Interface │ Attribute │ Value │
75 ├────────────────────────┼───────────────┼─────────┤
76 │pthread_cleanup_push(), │ Thread safety │ MT-Safe │
77 │pthread_cleanup_pop() │ │ │
78 └────────────────────────┴───────────────┴─────────┘
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81 POSIX.1-2001, POSIX.1-2008.
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84 On Linux, the pthread_cleanup_push() and pthread_cleanup_pop() func‐
85 tions are implemented as macros that expand to text containing '{' and
86 '}', respectively. This means that variables declared within the scope
87 of paired calls to these functions will be visible within only that
88 scope.
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90 POSIX.1 says that the effect of using return, break, continue, or goto
91 to prematurely leave a block bracketed pthread_cleanup_push() and
92 pthread_cleanup_pop() is undefined. Portable applications should avoid
93 doing this.
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96 The program below provides a simple example of the use of the functions
97 described in this page. The program creates a thread that executes a
98 loop bracketed by pthread_cleanup_push() and pthread_cleanup_pop().
99 This loop increments a global variable, cnt, once each second. Depend‐
100 ing on what command-line arguments are supplied, the main thread sends
101 the other thread a cancellation request, or sets a global variable that
102 causes the other thread to exit its loop and terminate normally (by
103 doing a return).
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105 In the following shell session, the main thread sends a cancellation
106 request to the other thread:
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108 $ ./a.out
109 New thread started
110 cnt = 0
111 cnt = 1
112 Canceling thread
113 Called clean-up handler
114 Thread was canceled; cnt = 0
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116 From the above, we see that the thread was canceled, and that the can‐
117 cellation clean-up handler was called and it reset the value of the
118 global variable cnt to 0.
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120 In the next run, the main program sets a global variable that causes
121 other thread to terminate normally:
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123 $ ./a.out x
124 New thread started
125 cnt = 0
126 cnt = 1
127 Thread terminated normally; cnt = 2
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129 From the above, we see that the clean-up handler was not executed
130 (because cleanup_pop_arg was 0), and therefore the value of cnt was not
131 reset.
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133 In the next run, the main program sets a global variable that causes
134 the other thread to terminate normally, and supplies a nonzero value
135 for cleanup_pop_arg:
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137 $ ./a.out x 1
138 New thread started
139 cnt = 0
140 cnt = 1
141 Called clean-up handler
142 Thread terminated normally; cnt = 0
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144 In the above, we see that although the thread was not canceled, the
145 clean-up handler was executed, because the argument given to
146 pthread_cleanup_pop() was nonzero.
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148 Program source
149
150 #include <pthread.h>
151 #include <sys/types.h>
152 #include <stdio.h>
153 #include <stdlib.h>
154 #include <unistd.h>
155 #include <errno.h>
156
157 #define handle_error_en(en, msg) \
158 do { errno = en; perror(msg); exit(EXIT_FAILURE); } while (0)
159
160 static int done = 0;
161 static int cleanup_pop_arg = 0;
162 static int cnt = 0;
163
164 static void
165 cleanup_handler(void *arg)
166 {
167 printf("Called clean-up handler\n");
168 cnt = 0;
169 }
170
171 static void *
172 thread_start(void *arg)
173 {
174 time_t start, curr;
175
176 printf("New thread started\n");
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178 pthread_cleanup_push(cleanup_handler, NULL);
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180 curr = start = time(NULL);
181
182 while (!done) {
183 pthread_testcancel(); /* A cancellation point */
184 if (curr < time(NULL)) {
185 curr = time(NULL);
186 printf("cnt = %d\n", cnt); /* A cancellation point */
187 cnt++;
188 }
189 }
190
191 pthread_cleanup_pop(cleanup_pop_arg);
192 return NULL;
193 }
194
195 int
196 main(int argc, char *argv[])
197 {
198 pthread_t thr;
199 int s;
200 void *res;
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202 s = pthread_create(&thr, NULL, thread_start, NULL);
203 if (s != 0)
204 handle_error_en(s, "pthread_create");
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206 sleep(2); /* Allow new thread to run a while */
207
208 if (argc > 1) {
209 if (argc > 2)
210 cleanup_pop_arg = atoi(argv[2]);
211 done = 1;
212
213 } else {
214 printf("Canceling thread\n");
215 s = pthread_cancel(thr);
216 if (s != 0)
217 handle_error_en(s, "pthread_cancel");
218 }
219
220 s = pthread_join(thr, &res);
221 if (s != 0)
222 handle_error_en(s, "pthread_join");
223
224 if (res == PTHREAD_CANCELED)
225 printf("Thread was canceled; cnt = %d\n", cnt);
226 else
227 printf("Thread terminated normally; cnt = %d\n", cnt);
228 exit(EXIT_SUCCESS);
229 }
230
232 pthread_cancel(3), pthread_cleanup_push_defer_np(3), pthread_setcancel‐
233 state(3), pthread_testcancel(3), pthreads(7)
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236 This page is part of release 5.02 of the Linux man-pages project. A
237 description of the project, information about reporting bugs, and the
238 latest version of this page, can be found at
239 https://www.kernel.org/doc/man-pages/.
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243Linux 2019-03-06 PTHREAD_CLEANUP_PUSH(3)