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kc3-lang/libevent/test/regress.c
Nick Mathewson
- test/regress.c
-
/* * Copyright (c) 2003-2007 Niels Provos <provos@citi.umich.edu> * Copyright (c) 2007-2009 Niels Provos and Nick Mathewson * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifdef WIN32 #include <winsock2.h> #include <windows.h> #endif #ifdef HAVE_CONFIG_H #include "event-config.h" #endif #include <sys/types.h> #include <sys/stat.h> #ifdef _EVENT_HAVE_SYS_TIME_H #include <sys/time.h> #endif #include <sys/queue.h> #ifndef WIN32 #include <sys/socket.h> #include <sys/wait.h> #include <signal.h> #include <unistd.h> #include <netdb.h> #endif #include <fcntl.h> #include <signal.h> #include <stdlib.h> #include <stdio.h> #include <string.h> #include <errno.h> #include <assert.h> #include "event2/event.h" #include "event2/event_struct.h" #include "event2/event_compat.h" #include "event2/tag.h" #include "event2/buffer.h" #include "event2/buffer_compat.h" #include "event2/util.h" #include "event-internal.h" #include "log-internal.h" #include "regress.h" #ifndef WIN32 #include "regress.gen.h" #endif int pair[2]; int test_ok; int called; struct event_base *global_base; static char wbuf[4096]; static char rbuf[4096]; static int woff; static int roff; static int usepersist; static struct timeval tset; static struct timeval tcalled; #define TEST1 "this is a test" #define SECONDS 1 #ifndef SHUT_WR #define SHUT_WR 1 #endif #ifdef WIN32 #define write(fd,buf,len) send((fd),(buf),(len),0) #define read(fd,buf,len) recv((fd),(buf),(len),0) #endif static void simple_read_cb(int fd, short event, void *arg) { char buf[256]; int len; len = read(fd, buf, sizeof(buf)); if (len) { if (!called) { if (event_add(arg, NULL) == -1) exit(1); } } else if (called == 1) test_ok = 1; called++; } static void simple_write_cb(int fd, short event, void *arg) { int len; len = write(fd, TEST1, strlen(TEST1) + 1); if (len == -1) test_ok = 0; else test_ok = 1; } static void multiple_write_cb(int fd, short event, void *arg) { struct event *ev = arg; int len; len = 128; if (woff + len >= sizeof(wbuf)) len = sizeof(wbuf) - woff; len = write(fd, wbuf + woff, len); if (len == -1) { fprintf(stderr, "%s: write\n", __func__); if (usepersist) event_del(ev); return; } woff += len; if (woff >= sizeof(wbuf)) { shutdown(fd, SHUT_WR); if (usepersist) event_del(ev); return; } if (!usepersist) { if (event_add(ev, NULL) == -1) exit(1); } } static void multiple_read_cb(int fd, short event, void *arg) { struct event *ev = arg; int len; len = read(fd, rbuf + roff, sizeof(rbuf) - roff); if (len == -1) fprintf(stderr, "%s: read\n", __func__); if (len <= 0) { if (usepersist) event_del(ev); return; } roff += len; if (!usepersist) { if (event_add(ev, NULL) == -1) exit(1); } } static void timeout_cb(int fd, short event, void *arg) { struct timeval tv; int diff; evutil_gettimeofday(&tcalled, NULL); if (evutil_timercmp(&tcalled, &tset, >)) evutil_timersub(&tcalled, &tset, &tv); else evutil_timersub(&tset, &tcalled, &tv); diff = tv.tv_sec*1000 + tv.tv_usec/1000 - SECONDS * 1000; if (diff < 0) diff = -diff; if (diff < 100) test_ok = 1; } struct both { struct event ev; int nread; }; static void combined_read_cb(int fd, short event, void *arg) { struct both *both = arg; char buf[128]; int len; len = read(fd, buf, sizeof(buf)); if (len == -1) fprintf(stderr, "%s: read\n", __func__); if (len <= 0) return; both->nread += len; if (event_add(&both->ev, NULL) == -1) exit(1); } static void combined_write_cb(int fd, short event, void *arg) { struct both *both = arg; char buf[128]; int len; len = sizeof(buf); if (len > both->nread) len = both->nread; len = write(fd, buf, len); if (len == -1) fprintf(stderr, "%s: write\n", __func__); if (len <= 0) { shutdown(fd, SHUT_WR); return; } both->nread -= len; if (event_add(&both->ev, NULL) == -1) exit(1); } /* Test infrastructure */ static int setup_test(const char *name) { if (in_legacy_test_wrapper) return 0; fprintf(stdout, "%s", name); if (evutil_socketpair(AF_UNIX, SOCK_STREAM, 0, pair) == -1) { fprintf(stderr, "%s: socketpair\n", __func__); exit(1); } if (evutil_make_socket_nonblocking(pair[0]) == -1) fprintf(stderr, "fcntl(O_NONBLOCK)"); if (evutil_make_socket_nonblocking(pair[1]) == -1) fprintf(stderr, "fcntl(O_NONBLOCK)"); test_ok = 0; called = 0; return (0); } static int cleanup_test(void) { if (in_legacy_test_wrapper) return 0; #ifndef WIN32 close(pair[0]); close(pair[1]); #else CloseHandle((HANDLE)pair[0]); CloseHandle((HANDLE)pair[1]); #endif if (test_ok) fprintf(stdout, "OK\n"); else { fprintf(stdout, "FAILED\n"); exit(1); } test_ok = 0; return (0); } static void test_simpleread(void) { struct event ev; /* Very simple read test */ setup_test("Simple read: "); write(pair[0], TEST1, strlen(TEST1)+1); shutdown(pair[0], SHUT_WR); event_set(&ev, pair[1], EV_READ, simple_read_cb, &ev); if (event_add(&ev, NULL) == -1) exit(1); event_dispatch(); cleanup_test(); } static void test_simplewrite(void) { struct event ev; /* Very simple write test */ setup_test("Simple write: "); event_set(&ev, pair[0], EV_WRITE, simple_write_cb, &ev); if (event_add(&ev, NULL) == -1) exit(1); event_dispatch(); cleanup_test(); } static void simpleread_multiple_cb(int fd, short event, void *arg) { if (++called == 2) test_ok = 1; } static void test_simpleread_multiple(void) { struct event one, two; /* Very simple read test */ setup_test("Simple read to multiple evens: "); write(pair[0], TEST1, strlen(TEST1)+1); shutdown(pair[0], SHUT_WR); event_set(&one, pair[1], EV_READ, simpleread_multiple_cb, NULL); if (event_add(&one, NULL) == -1) exit(1); event_set(&two, pair[1], EV_READ, simpleread_multiple_cb, NULL); if (event_add(&two, NULL) == -1) exit(1); event_dispatch(); cleanup_test(); } static void test_multiple(void) { struct event ev, ev2; int i; /* Multiple read and write test */ setup_test("Multiple read/write: "); memset(rbuf, 0, sizeof(rbuf)); for (i = 0; i < sizeof(wbuf); i++) wbuf[i] = i; roff = woff = 0; usepersist = 0; event_set(&ev, pair[0], EV_WRITE, multiple_write_cb, &ev); if (event_add(&ev, NULL) == -1) exit(1); event_set(&ev2, pair[1], EV_READ, multiple_read_cb, &ev2); if (event_add(&ev2, NULL) == -1) exit(1); event_dispatch(); if (roff == woff) test_ok = memcmp(rbuf, wbuf, sizeof(wbuf)) == 0; cleanup_test(); } static void test_persistent(void) { struct event ev, ev2; int i; /* Multiple read and write test with persist */ setup_test("Persist read/write: "); memset(rbuf, 0, sizeof(rbuf)); for (i = 0; i < sizeof(wbuf); i++) wbuf[i] = i; roff = woff = 0; usepersist = 1; event_set(&ev, pair[0], EV_WRITE|EV_PERSIST, multiple_write_cb, &ev); if (event_add(&ev, NULL) == -1) exit(1); event_set(&ev2, pair[1], EV_READ|EV_PERSIST, multiple_read_cb, &ev2); if (event_add(&ev2, NULL) == -1) exit(1); event_dispatch(); if (roff == woff) test_ok = memcmp(rbuf, wbuf, sizeof(wbuf)) == 0; cleanup_test(); } static void test_combined(void) { struct both r1, r2, w1, w2; setup_test("Combined read/write: "); memset(&r1, 0, sizeof(r1)); memset(&r2, 0, sizeof(r2)); memset(&w1, 0, sizeof(w1)); memset(&w2, 0, sizeof(w2)); w1.nread = 4096; w2.nread = 8192; event_set(&r1.ev, pair[0], EV_READ, combined_read_cb, &r1); event_set(&w1.ev, pair[0], EV_WRITE, combined_write_cb, &w1); event_set(&r2.ev, pair[1], EV_READ, combined_read_cb, &r2); event_set(&w2.ev, pair[1], EV_WRITE, combined_write_cb, &w2); if (event_add(&r1.ev, NULL) == -1) exit(1); if (event_add(&w1.ev, NULL)) exit(1); if (event_add(&r2.ev, NULL)) exit(1); if (event_add(&w2.ev, NULL)) exit(1); event_dispatch(); if (r1.nread == 8192 && r2.nread == 4096) test_ok = 1; cleanup_test(); } static void test_simpletimeout(void) { struct timeval tv; struct event ev; setup_test("Simple timeout: "); tv.tv_usec = 0; tv.tv_sec = SECONDS; evtimer_set(&ev, timeout_cb, NULL); evtimer_add(&ev, &tv); evutil_gettimeofday(&tset, NULL); event_dispatch(); cleanup_test(); } static void periodic_timeout_cb(int fd, short event, void *arg) { int *count = arg; (*count)++; if (*count == 6) { /* call loopexit only once - on slow machines(?), it is * apparently possible for this to get called twice. */ test_ok = 1; event_base_loopexit(global_base, NULL); } } static void test_persistent_timeout(void) { struct timeval tv; struct event ev; int count = 0; timerclear(&tv); tv.tv_usec = 10000; event_assign(&ev, global_base, -1, EV_TIMEOUT|EV_PERSIST, periodic_timeout_cb, &count); event_add(&ev, &tv); event_dispatch(); event_del(&ev); } #ifndef WIN32 static void signal_cb(int fd, short event, void *arg); extern struct event_base *current_base; static void child_signal_cb(int fd, short event, void *arg) { struct timeval tv; int *pint = arg; *pint = 1; tv.tv_usec = 500000; tv.tv_sec = 0; event_loopexit(&tv); } static void test_fork(void) { int status, got_sigchld = 0; struct event ev, sig_ev; pid_t pid; setup_test("After fork: "); write(pair[0], TEST1, strlen(TEST1)+1); event_set(&ev, pair[1], EV_READ, simple_read_cb, &ev); if (event_add(&ev, NULL) == -1) exit(1); evsignal_set(&sig_ev, SIGCHLD, child_signal_cb, &got_sigchld); evsignal_add(&sig_ev, NULL); if ((pid = fork()) == 0) { /* in the child */ if (event_reinit(current_base) == -1) { fprintf(stdout, "FAILED (reinit)\n"); exit(1); } evsignal_del(&sig_ev); called = 0; event_dispatch(); event_base_free(current_base); /* we do not send an EOF; simple_read_cb requires an EOF * to set test_ok. we just verify that the callback was * called. */ exit(test_ok != 0 || called != 2 ? -2 : 76); } /* wait for the child to read the data */ sleep(1); write(pair[0], TEST1, strlen(TEST1)+1); if (waitpid(pid, &status, 0) == -1) { fprintf(stdout, "FAILED (fork)\n"); exit(1); } if (WEXITSTATUS(status) != 76) { fprintf(stdout, "FAILED (exit): %d\n", WEXITSTATUS(status)); exit(1); } /* test that the current event loop still works */ write(pair[0], TEST1, strlen(TEST1)+1); shutdown(pair[0], SHUT_WR); event_dispatch(); if (!got_sigchld) { fprintf(stdout, "FAILED (sigchld)\n"); exit(1); } evsignal_del(&sig_ev); cleanup_test(); } static void signal_cb_sa(int sig) { test_ok = 2; } static void signal_cb(int fd, short event, void *arg) { struct event *ev = arg; evsignal_del(ev); test_ok = 1; } static void test_simplesignal(void) { struct event ev; struct itimerval itv; setup_test("Simple signal: "); evsignal_set(&ev, SIGALRM, signal_cb, &ev); evsignal_add(&ev, NULL); /* find bugs in which operations are re-ordered */ evsignal_del(&ev); evsignal_add(&ev, NULL); memset(&itv, 0, sizeof(itv)); itv.it_value.tv_sec = 1; if (setitimer(ITIMER_REAL, &itv, NULL) == -1) goto skip_simplesignal; event_dispatch(); skip_simplesignal: if (evsignal_del(&ev) == -1) test_ok = 0; cleanup_test(); } static void test_multiplesignal(void) { struct event ev_one, ev_two; struct itimerval itv; setup_test("Multiple signal: "); evsignal_set(&ev_one, SIGALRM, signal_cb, &ev_one); evsignal_add(&ev_one, NULL); evsignal_set(&ev_two, SIGALRM, signal_cb, &ev_two); evsignal_add(&ev_two, NULL); memset(&itv, 0, sizeof(itv)); itv.it_value.tv_sec = 1; if (setitimer(ITIMER_REAL, &itv, NULL) == -1) goto skip_simplesignal; event_dispatch(); skip_simplesignal: if (evsignal_del(&ev_one) == -1) test_ok = 0; if (evsignal_del(&ev_two) == -1) test_ok = 0; cleanup_test(); } static void test_immediatesignal(void) { struct event ev; test_ok = 0; printf("Immediate signal: "); evsignal_set(&ev, SIGUSR1, signal_cb, &ev); evsignal_add(&ev, NULL); raise(SIGUSR1); event_loop(EVLOOP_NONBLOCK); evsignal_del(&ev); cleanup_test(); } static void test_signal_dealloc(void) { /* make sure that evsignal_event is event_del'ed and pipe closed */ struct event ev; struct event_base *base = event_init(); printf("Signal dealloc: "); evsignal_set(&ev, SIGUSR1, signal_cb, &ev); evsignal_add(&ev, NULL); evsignal_del(&ev); event_base_free(base); /* If we got here without asserting, we're fine. */ test_ok = 1; cleanup_test(); } static void test_signal_pipeloss(void) { /* make sure that the base1 pipe is closed correctly. */ struct event_base *base1, *base2; int pipe1; test_ok = 0; printf("Signal pipeloss: "); base1 = event_init(); pipe1 = base1->sig.ev_signal_pair[0]; base2 = event_init(); event_base_free(base2); event_base_free(base1); if (close(pipe1) != -1 || errno!=EBADF) { /* fd must be closed, so second close gives -1, EBADF */ printf("signal pipe not closed. "); test_ok = 0; } else { test_ok = 1; } cleanup_test(); } /* * make two bases to catch signals, use both of them. this only works * for event mechanisms that use our signal pipe trick. kqueue handles * signals internally, and all interested kqueues get all the signals. */ static void test_signal_switchbase(void) { struct event ev1, ev2; struct event_base *base1, *base2; int is_kqueue; test_ok = 0; printf("Signal switchbase: "); base1 = event_init(); base2 = event_init(); is_kqueue = !strcmp(event_get_method(),"kqueue"); evsignal_set(&ev1, SIGUSR1, signal_cb, &ev1); evsignal_set(&ev2, SIGUSR1, signal_cb, &ev2); if (event_base_set(base1, &ev1) || event_base_set(base2, &ev2) || event_add(&ev1, NULL) || event_add(&ev2, NULL)) { fprintf(stderr, "%s: cannot set base, add\n", __func__); exit(1); } test_ok = 0; /* can handle signal before loop is called */ raise(SIGUSR1); event_base_loop(base2, EVLOOP_NONBLOCK); if (is_kqueue) { if (!test_ok) goto done; test_ok = 0; } event_base_loop(base1, EVLOOP_NONBLOCK); if (test_ok && !is_kqueue) { test_ok = 0; /* set base1 to handle signals */ event_base_loop(base1, EVLOOP_NONBLOCK); raise(SIGUSR1); event_base_loop(base1, EVLOOP_NONBLOCK); event_base_loop(base2, EVLOOP_NONBLOCK); } done: event_base_free(base1); event_base_free(base2); cleanup_test(); } /* * assert that a signal event removed from the event queue really is * removed - with no possibility of it's parent handler being fired. */ static void test_signal_assert(void) { struct event ev; struct event_base *base = event_init(); test_ok = 0; printf("Signal handler assert: "); /* use SIGCONT so we don't kill ourselves when we signal to nowhere */ evsignal_set(&ev, SIGCONT, signal_cb, &ev); evsignal_add(&ev, NULL); /* * if evsignal_del() fails to reset the handler, it's current handler * will still point to evsig_handler(). */ evsignal_del(&ev); raise(SIGCONT); /* only way to verify we were in evsig_handler() */ if (base->sig.evsig_caught) test_ok = 0; else test_ok = 1; event_base_free(base); cleanup_test(); return; } /* * assert that we restore our previous signal handler properly. */ static void test_signal_restore(void) { struct event ev; struct event_base *base = event_init(); #ifdef _EVENT_HAVE_SIGACTION struct sigaction sa; #endif test_ok = 0; printf("Signal handler restore: "); #ifdef _EVENT_HAVE_SIGACTION sa.sa_handler = signal_cb_sa; sa.sa_flags = 0x0; sigemptyset(&sa.sa_mask); if (sigaction(SIGUSR1, &sa, NULL) == -1) goto out; #else if (signal(SIGUSR1, signal_cb_sa) == SIG_ERR) goto out; #endif evsignal_set(&ev, SIGUSR1, signal_cb, &ev); evsignal_add(&ev, NULL); evsignal_del(&ev); raise(SIGUSR1); /* 1 == signal_cb, 2 == signal_cb_sa, we want our previous handler */ if (test_ok != 2) test_ok = 0; out: event_base_free(base); cleanup_test(); return; } static void signal_cb_swp(int sig, short event, void *arg) { called++; if (called < 5) raise(sig); else event_loopexit(NULL); } static void timeout_cb_swp(int fd, short event, void *arg) { if (called == -1) { struct timeval tv = {5, 0}; called = 0; evtimer_add((struct event *)arg, &tv); raise(SIGUSR1); return; } test_ok = 0; event_loopexit(NULL); } static void test_signal_while_processing(void) { struct event_base *base = event_init(); struct event ev, ev_timer; struct timeval tv = {0, 0}; setup_test("Receiving a signal while processing other signal: "); called = -1; test_ok = 1; signal_set(&ev, SIGUSR1, signal_cb_swp, NULL); signal_add(&ev, NULL); evtimer_set(&ev_timer, timeout_cb_swp, &ev_timer); evtimer_add(&ev_timer, &tv); event_dispatch(); event_base_free(base); cleanup_test(); return; } #endif static void test_free_active_base(void) { struct event_base *base1; struct event ev1; setup_test("Free active base: "); base1 = event_init(); event_set(&ev1, pair[1], EV_READ, simple_read_cb, &ev1); event_base_set(base1, &ev1); event_add(&ev1, NULL); /* event_del(&ev1); */ event_base_free(base1); test_ok = 1; cleanup_test(); event_base_free(global_base); global_base = event_init(); } static void test_event_base_new(void) { struct event_base *base; struct event ev1; setup_test("Event base new: "); write(pair[0], TEST1, strlen(TEST1)+1); shutdown(pair[0], SHUT_WR); base = event_base_new(); event_set(&ev1, pair[1], EV_READ, simple_read_cb, &ev1); event_base_set(base, &ev1); event_add(&ev1, NULL); event_base_dispatch(base); event_base_free(base); test_ok = 1; cleanup_test(); } static void test_loopexit(void) { struct timeval tv, tv_start, tv_end; struct event ev; setup_test("Loop exit: "); tv.tv_usec = 0; tv.tv_sec = 60*60*24; evtimer_set(&ev, timeout_cb, NULL); evtimer_add(&ev, &tv); tv.tv_usec = 0; tv.tv_sec = 1; event_loopexit(&tv); evutil_gettimeofday(&tv_start, NULL); event_dispatch(); evutil_gettimeofday(&tv_end, NULL); evutil_timersub(&tv_end, &tv_start, &tv_end); evtimer_del(&ev); if (tv.tv_sec < 2) test_ok = 1; cleanup_test(); } static void test_loopexit_multiple(void) { struct timeval tv; struct event_base *base; setup_test("Loop Multiple exit: "); base = event_base_new(); tv.tv_usec = 0; tv.tv_sec = 1; event_base_loopexit(base, &tv); tv.tv_usec = 0; tv.tv_sec = 2; event_base_loopexit(base, &tv); event_base_dispatch(base); event_base_free(base); test_ok = 1; cleanup_test(); } static void break_cb(int fd, short events, void *arg) { test_ok = 1; event_loopbreak(); } static void fail_cb(int fd, short events, void *arg) { test_ok = 0; } static void test_loopbreak(void) { struct event ev1, ev2; struct timeval tv; setup_test("Loop break: "); tv.tv_sec = 0; tv.tv_usec = 0; evtimer_set(&ev1, break_cb, NULL); evtimer_add(&ev1, &tv); evtimer_set(&ev2, fail_cb, NULL); evtimer_add(&ev2, &tv); event_dispatch(); evtimer_del(&ev1); evtimer_del(&ev2); cleanup_test(); } static struct event *readd_test_event_last_added = NULL; static void re_add_read_cb(int fd, short event, void *arg) { char buf[256]; int len; struct event *ev_other = arg; readd_test_event_last_added = ev_other; len = read(fd, buf, sizeof(buf)); event_add(ev_other, NULL); ++test_ok; } static void test_nonpersist_readd(void) { struct event ev1, ev2; int n, m; setup_test("Re-add nonpersistent events: "); event_set(&ev1, pair[0], EV_READ, re_add_read_cb, &ev2); event_set(&ev2, pair[1], EV_READ, re_add_read_cb, &ev1); n = write(pair[0], "Hello", 5); m = write(pair[1], "Hello", 5); if (event_add(&ev1, NULL) == -1 || event_add(&ev2, NULL) == -1) { test_ok = 0; } if (test_ok != 0) exit(1); event_loop(EVLOOP_ONCE); if (test_ok != 2) exit(1); /* At this point, we executed both callbacks. Whichever one got * called first added the second, but the second then immediately got * deleted before its callback was called. At this point, though, it * re-added the first. */ if (!readd_test_event_last_added) { test_ok = 0; } else if (readd_test_event_last_added == &ev1) { if (!event_pending(&ev1, EV_READ, NULL) || event_pending(&ev2, EV_READ, NULL)) test_ok = 0; } else { if (event_pending(&ev1, EV_READ, NULL) || !event_pending(&ev2, EV_READ, NULL)) test_ok = 0; } event_del(&ev1); event_del(&ev2); cleanup_test(); } struct test_pri_event { struct event ev; int count; }; static void test_priorities_cb(int fd, short what, void *arg) { struct test_pri_event *pri = arg; struct timeval tv; if (pri->count == 3) { event_loopexit(NULL); return; } pri->count++; evutil_timerclear(&tv); event_add(&pri->ev, &tv); } static void test_priorities_impl(int npriorities) { struct test_pri_event one, two; struct timeval tv; TT_BLATHER(("Testing Priorities %d: ", npriorities)); event_base_priority_init(global_base, npriorities); memset(&one, 0, sizeof(one)); memset(&two, 0, sizeof(two)); timeout_set(&one.ev, test_priorities_cb, &one); if (event_priority_set(&one.ev, 0) == -1) { fprintf(stderr, "%s: failed to set priority", __func__); exit(1); } timeout_set(&two.ev, test_priorities_cb, &two); if (event_priority_set(&two.ev, npriorities - 1) == -1) { fprintf(stderr, "%s: failed to set priority", __func__); exit(1); } evutil_timerclear(&tv); if (event_add(&one.ev, &tv) == -1) exit(1); if (event_add(&two.ev, &tv) == -1) exit(1); event_dispatch(); event_del(&one.ev); event_del(&two.ev); if (npriorities == 1) { if (one.count == 3 && two.count == 3) test_ok = 1; } else if (npriorities == 2) { /* Two is called once because event_loopexit is priority 1 */ if (one.count == 3 && two.count == 1) test_ok = 1; } else { if (one.count == 3 && two.count == 0) test_ok = 1; } } static void test_priorities(void) { test_priorities_impl(1); if (test_ok) test_priorities_impl(2); if (test_ok) test_priorities_impl(3); } static void test_multiple_cb(int fd, short event, void *arg) { if (event & EV_READ) test_ok |= 1; else if (event & EV_WRITE) test_ok |= 2; } static void test_multiple_events_for_same_fd(void) { struct event e1, e2; setup_test("Multiple events for same fd: "); event_set(&e1, pair[0], EV_READ, test_multiple_cb, NULL); event_add(&e1, NULL); event_set(&e2, pair[0], EV_WRITE, test_multiple_cb, NULL); event_add(&e2, NULL); event_loop(EVLOOP_ONCE); event_del(&e2); write(pair[1], TEST1, strlen(TEST1)+1); event_loop(EVLOOP_ONCE); event_del(&e1); if (test_ok != 3) test_ok = 0; cleanup_test(); } int evtag_decode_int(ev_uint32_t *pnumber, struct evbuffer *evbuf); int evtag_encode_tag(struct evbuffer *evbuf, ev_uint32_t number); int evtag_decode_tag(ev_uint32_t *pnumber, struct evbuffer *evbuf); static void read_once_cb(int fd, short event, void *arg) { char buf[256]; int len; len = read(fd, buf, sizeof(buf)); if (called) { test_ok = 0; } else if (len) { /* Assumes global pair[0] can be used for writing */ write(pair[0], TEST1, strlen(TEST1)+1); test_ok = 1; } called++; } static void test_want_only_once(void) { struct event ev; struct timeval tv; /* Very simple read test */ setup_test("Want read only once: "); write(pair[0], TEST1, strlen(TEST1)+1); /* Setup the loop termination */ evutil_timerclear(&tv); tv.tv_sec = 1; event_loopexit(&tv); event_set(&ev, pair[1], EV_READ, read_once_cb, &ev); if (event_add(&ev, NULL) == -1) exit(1); event_dispatch(); cleanup_test(); } #define TEST_MAX_INT 6 static void evtag_int_test(void) { struct evbuffer *tmp = evbuffer_new(); ev_uint32_t integers[TEST_MAX_INT] = { 0xaf0, 0x1000, 0x1, 0xdeadbeef, 0x00, 0xbef000 }; ev_uint32_t integer; int i; for (i = 0; i < TEST_MAX_INT; i++) { int oldlen, newlen; oldlen = EVBUFFER_LENGTH(tmp); encode_int(tmp, integers[i]); newlen = EVBUFFER_LENGTH(tmp); TT_BLATHER(("encoded 0x%08x with %d bytes", (unsigned)integers[i], newlen - oldlen)); } for (i = 0; i < TEST_MAX_INT; i++) { tt_assert(evtag_decode_int(&integer, tmp) != -1); tt_uint_op(integer, ==, integers[i]); } tt_uint_op(EVBUFFER_LENGTH(tmp), ==, 0); end: evbuffer_free(tmp); } static void evtag_fuzz(void) { u_char buffer[4096]; struct evbuffer *tmp = evbuffer_new(); struct timeval tv; int i, j; int not_failed = 0; for (j = 0; j < 100; j++) { for (i = 0; i < sizeof(buffer); i++) buffer[i] = rand(); evbuffer_drain(tmp, -1); evbuffer_add(tmp, buffer, sizeof(buffer)); if (evtag_unmarshal_timeval(tmp, 0, &tv) != -1) not_failed++; } /* The majority of decodes should fail */ tt_int_op(not_failed, <, 10); /* Now insert some corruption into the tag length field */ evbuffer_drain(tmp, -1); evutil_timerclear(&tv); tv.tv_sec = 1; evtag_marshal_timeval(tmp, 0, &tv); evbuffer_add(tmp, buffer, sizeof(buffer)); ((char *)EVBUFFER_DATA(tmp))[1] = 0xff; if (evtag_unmarshal_timeval(tmp, 0, &tv) != -1) { tt_abort_msg("evtag_unmarshal_timeval should have failed"); } end: evbuffer_free(tmp); } static void evtag_tag_encoding(void) { struct evbuffer *tmp = evbuffer_new(); ev_uint32_t integers[TEST_MAX_INT] = { 0xaf0, 0x1000, 0x1, 0xdeadbeef, 0x00, 0xbef000 }; ev_uint32_t integer; int i; for (i = 0; i < TEST_MAX_INT; i++) { int oldlen, newlen; oldlen = EVBUFFER_LENGTH(tmp); evtag_encode_tag(tmp, integers[i]); newlen = EVBUFFER_LENGTH(tmp); TT_BLATHER(("encoded 0x%08x with %d bytes", (unsigned)integers[i], newlen - oldlen)); } for (i = 0; i < TEST_MAX_INT; i++) { tt_int_op(evtag_decode_tag(&integer, tmp), !=, -1); tt_uint_op(integer, ==, integers[i]); } tt_uint_op(EVBUFFER_LENGTH(tmp), ==, 0); end: evbuffer_free(tmp); } static void test_evtag(void) { evtag_init(); evtag_int_test(); evtag_fuzz(); evtag_tag_encoding(); test_ok = 1; } static void test_methods(void *ptr) { const char **methods = event_get_supported_methods(); struct event_config *cfg = NULL; struct event_base *base = NULL; const char *backend; int n_methods = 0; tt_assert(methods); backend = methods[0]; while (*methods != NULL) { TT_BLATHER(("Support method: %s", *methods)); ++methods; ++n_methods; } if (n_methods == 1) { /* only one method supported; can't continue. */ goto end; } cfg = event_config_new(); assert(cfg != NULL); tt_int_op(event_config_avoid_method(cfg, backend), ==, 0); base = event_base_new_with_config(cfg); tt_assert(base); tt_str_op(backend, !=, event_base_get_method(base)); end: if (base) event_base_free(base); if (cfg) event_config_free(cfg); } struct testcase_t legacy_testcases[] = { /* Some converted-over tests */ { "methods", test_methods, TT_FORK, NULL, NULL }, /* These are still using the old API */ LEGACY(persistent_timeout, TT_FORK|TT_NEED_BASE), LEGACY(priorities, TT_FORK|TT_NEED_BASE), LEGACY(free_active_base, TT_FORK|TT_NEED_BASE), LEGACY(event_base_new, TT_FORK|TT_NEED_SOCKETPAIR), /* These legacy tests may not all need all of these flags. */ LEGACY(simpleread, TT_ISOLATED), LEGACY(simpleread_multiple, TT_ISOLATED), LEGACY(simplewrite, TT_ISOLATED), LEGACY(multiple, TT_ISOLATED), LEGACY(persistent, TT_ISOLATED), LEGACY(combined, TT_ISOLATED), LEGACY(simpletimeout, TT_ISOLATED), LEGACY(loopbreak, TT_ISOLATED), LEGACY(loopexit, TT_ISOLATED), LEGACY(loopexit_multiple, TT_ISOLATED), LEGACY(nonpersist_readd, TT_ISOLATED), LEGACY(multiple_events_for_same_fd, TT_ISOLATED), LEGACY(want_only_once, TT_ISOLATED), #ifndef WIN32 LEGACY(fork, TT_ISOLATED), #endif LEGACY(evtag, TT_ISOLATED), END_OF_TESTCASES }; struct testcase_t signal_testcases[] = { #ifndef WIN32 LEGACY(simplesignal, TT_ISOLATED), LEGACY(multiplesignal, TT_ISOLATED), LEGACY(immediatesignal, TT_ISOLATED), LEGACY(signal_dealloc, TT_ISOLATED), LEGACY(signal_pipeloss, TT_ISOLATED), LEGACY(signal_switchbase, TT_ISOLATED), LEGACY(signal_restore, TT_ISOLATED), LEGACY(signal_assert, TT_ISOLATED), LEGACY(signal_while_processing, TT_ISOLATED), #endif END_OF_TESTCASES };