/*
Unix SMB/CIFS implementation.
testing of the events subsystem
Copyright (C) Stefan Metzmacher 2006-2009
Copyright (C) Jeremy Allison 2013
** NOTE! The following LGPL license applies to the tevent
** library. This does NOT imply that all of Samba is released
** under the LGPL
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 3 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, see .
*/
#include "includes.h"
#define TEVENT_DEPRECATED 1
#include "tevent.h"
#include "system/filesys.h"
#include "system/select.h"
#include "system/network.h"
#include "torture/torture.h"
#include "torture/local/proto.h"
#include "lib/util/blocking.h"
#ifdef HAVE_PTHREAD
#include "system/threads.h"
#include
#endif
static struct tevent_context *
test_tevent_context_init(TALLOC_CTX *mem_ctx)
{
struct tevent_context *ev = NULL;
ev = tevent_context_init(mem_ctx);
if (ev != NULL) {
samba_tevent_set_debug(ev, "");
}
return ev;
}
static struct tevent_context *
test_tevent_context_init_byname(TALLOC_CTX *mem_ctx, const char *name)
{
struct tevent_context *ev = NULL;
ev = tevent_context_init_byname(mem_ctx, name);
if (ev != NULL) {
samba_tevent_set_debug(ev, name);
}
return ev;
}
static int fde_count;
static void do_read(int fd, void *buf, size_t count)
{
ssize_t ret;
do {
ret = read(fd, buf, count);
} while (ret == -1 && errno == EINTR);
}
static void fde_handler_read(struct tevent_context *ev_ctx, struct tevent_fd *f,
uint16_t flags, void *private_data)
{
int *fd = (int *)private_data;
char c;
#ifdef SA_SIGINFO
kill(getpid(), SIGUSR1);
#endif
kill(getpid(), SIGALRM);
do_read(fd[0], &c, 1);
fde_count++;
}
static void do_write(int fd, void *buf, size_t count)
{
ssize_t ret;
do {
ret = write(fd, buf, count);
} while (ret == -1 && errno == EINTR);
}
static void do_fill(int fd)
{
uint8_t buf[1024] = {0, };
ssize_t ret;
set_blocking(fd, false);
do {
do {
ret = write(fd, buf, ARRAY_SIZE(buf));
} while (ret == -1 && errno == EINTR);
} while (ret == ARRAY_SIZE(buf));
set_blocking(fd, true);
}
static void fde_handler_write(struct tevent_context *ev_ctx, struct tevent_fd *f,
uint16_t flags, void *private_data)
{
int *fd = (int *)private_data;
char c = 0;
do_write(fd[1], &c, 1);
}
/* This will only fire if the fd's returned from pipe() are bi-directional. */
static void fde_handler_read_1(struct tevent_context *ev_ctx, struct tevent_fd *f,
uint16_t flags, void *private_data)
{
int *fd = (int *)private_data;
char c;
#ifdef SA_SIGINFO
kill(getpid(), SIGUSR1);
#endif
kill(getpid(), SIGALRM);
do_read(fd[1], &c, 1);
fde_count++;
}
/* This will only fire if the fd's returned from pipe() are bi-directional. */
static void fde_handler_write_1(struct tevent_context *ev_ctx, struct tevent_fd *f,
uint16_t flags, void *private_data)
{
int *fd = (int *)private_data;
char c = 0;
do_write(fd[0], &c, 1);
}
static void finished_handler(struct tevent_context *ev_ctx, struct tevent_timer *te,
struct timeval tval, void *private_data)
{
int *finished = (int *)private_data;
(*finished) = 1;
}
static void count_handler(struct tevent_context *ev_ctx, struct tevent_signal *te,
int signum, int count, void *info, void *private_data)
{
int *countp = (int *)private_data;
(*countp) += count;
}
static bool test_event_context(struct torture_context *test,
const void *test_data)
{
struct tevent_context *ev_ctx;
int fd[2] = { -1, -1 };
const char *backend = (const char *)test_data;
int alarm_count=0, info_count=0;
struct tevent_fd *fde_read;
struct tevent_fd *fde_read_1;
struct tevent_fd *fde_write;
struct tevent_fd *fde_write_1;
#ifdef SA_RESTART
struct tevent_signal *se1 = NULL;
#endif
#ifdef SA_RESETHAND
struct tevent_signal *se2 = NULL;
#endif
#ifdef SA_SIGINFO
struct tevent_signal *se3 = NULL;
#endif
int finished=0;
struct timeval t;
int ret;
ev_ctx = test_tevent_context_init_byname(test, backend);
if (ev_ctx == NULL) {
torture_comment(test, "event backend '%s' not supported\n", backend);
return true;
}
torture_comment(test, "backend '%s' - %s\n",
backend, __FUNCTION__);
/* reset globals */
fde_count = 0;
/* create a pipe */
ret = pipe(fd);
torture_assert_int_equal(test, ret, 0, "pipe failed");
fde_read = tevent_add_fd(ev_ctx, ev_ctx, fd[0], TEVENT_FD_READ,
fde_handler_read, fd);
fde_write_1 = tevent_add_fd(ev_ctx, ev_ctx, fd[0], TEVENT_FD_WRITE,
fde_handler_write_1, fd);
fde_write = tevent_add_fd(ev_ctx, ev_ctx, fd[1], TEVENT_FD_WRITE,
fde_handler_write, fd);
fde_read_1 = tevent_add_fd(ev_ctx, ev_ctx, fd[1], TEVENT_FD_READ,
fde_handler_read_1, fd);
tevent_fd_set_auto_close(fde_read);
tevent_fd_set_auto_close(fde_write);
tevent_add_timer(ev_ctx, ev_ctx, timeval_current_ofs(2,0),
finished_handler, &finished);
#ifdef SA_RESTART
se1 = tevent_add_signal(ev_ctx, ev_ctx, SIGALRM, SA_RESTART, count_handler, &alarm_count);
torture_assert(test, se1 != NULL, "failed to setup se1");
#endif
#ifdef SA_RESETHAND
se2 = tevent_add_signal(ev_ctx, ev_ctx, SIGALRM, SA_RESETHAND, count_handler, &alarm_count);
torture_assert(test, se2 != NULL, "failed to setup se2");
#endif
#ifdef SA_SIGINFO
se3 = tevent_add_signal(ev_ctx, ev_ctx, SIGUSR1, SA_SIGINFO, count_handler, &info_count);
torture_assert(test, se3 != NULL, "failed to setup se3");
#endif
t = timeval_current();
while (!finished) {
errno = 0;
if (tevent_loop_once(ev_ctx) == -1) {
TALLOC_FREE(ev_ctx);
torture_fail(test, talloc_asprintf(test, "Failed event loop %s\n", strerror(errno)));
return false;
}
}
talloc_free(fde_read_1);
talloc_free(fde_write_1);
talloc_free(fde_read);
talloc_free(fde_write);
while (alarm_count < fde_count+1) {
if (tevent_loop_once(ev_ctx) == -1) {
break;
}
}
torture_comment(test, "Got %.2f pipe events/sec\n", fde_count/timeval_elapsed(&t));
#ifdef SA_RESTART
talloc_free(se1);
#endif
torture_assert_int_equal(test, alarm_count, 1+fde_count, "alarm count mismatch");
#ifdef SA_RESETHAND
/*
* we do not call talloc_free(se2)
* because it is already gone,
* after triggering the event handler.
*/
#endif
#ifdef SA_SIGINFO
talloc_free(se3);
torture_assert_int_equal(test, info_count, fde_count, "info count mismatch");
#endif
talloc_free(ev_ctx);
return true;
}
static void fde_handler_do_read(struct tevent_context *ev_ctx, struct tevent_fd *f,
uint16_t flags, void *private_data)
{
int *fd = (int *)private_data;
char c = 0;
do_read(fd[0], &c, 1);
fde_count++;
}
static void fde_handler_do_write(struct tevent_context *ev_ctx, struct tevent_fd *f,
uint16_t flags, void *private_data)
{
int *fd = (int *)private_data;
char c = 0;
do_write(fd[1], &c, 1);
}
static void fde_handler_ignore(struct tevent_context *ev_ctx, struct tevent_fd *f,
uint16_t flags, void *private_data)
{
}
static bool test_fd_speedX(struct torture_context *test,
const void *test_data,
size_t additional_fdes)
{
struct tevent_context *ev_ctx = NULL;
int fd[2] = { -1, -1 };
const char *backend = (const char *)test_data;
struct tevent_fd *fde_read = NULL;
struct tevent_fd *fde_write = NULL;
int finished=0;
struct timeval t;
size_t i;
int ret;
ev_ctx = test_tevent_context_init_byname(test, backend);
if (ev_ctx == NULL) {
torture_comment(test, "event backend '%s' not supported\n", backend);
return true;
}
torture_comment(test, "backend '%s' - test_fd_speed%zu\n",
backend, 1 + additional_fdes);
/* reset globals */
fde_count = 0;
/* create a pipe */
ret = pipe(fd);
torture_assert_int_equal(test, ret, 0, "pipe failed");
fde_read = tevent_add_fd(ev_ctx, ev_ctx, fd[0], TEVENT_FD_READ,
fde_handler_do_read, fd);
fde_write = tevent_add_fd(ev_ctx, ev_ctx, fd[1], TEVENT_FD_WRITE,
fde_handler_do_write, fd);
for (i = 0; i < additional_fdes; i++) {
tevent_add_fd(ev_ctx, ev_ctx, fd[0], TEVENT_FD_WRITE,
fde_handler_ignore, fd);
tevent_add_fd(ev_ctx, ev_ctx, fd[1], TEVENT_FD_READ,
fde_handler_ignore, fd);
}
tevent_fd_set_auto_close(fde_read);
tevent_fd_set_auto_close(fde_write);
tevent_add_timer(ev_ctx, ev_ctx, timeval_current_ofs(600,0),
finished_handler, &finished);
t = timeval_current();
while (!finished && fde_count < 1000000) {
errno = 0;
if (tevent_loop_once(ev_ctx) == -1) {
TALLOC_FREE(ev_ctx);
torture_fail(test, talloc_asprintf(test, "Failed event loop %s\n", strerror(errno)));
return false;
}
}
talloc_free(fde_read);
talloc_free(fde_write);
torture_comment(test, "Got %.2f pipe events\n", (double)fde_count);
torture_comment(test, "Got %.2f pipe events/sec\n", fde_count/timeval_elapsed(&t));
talloc_free(ev_ctx);
return true;
}
static bool test_fd_speed1(struct torture_context *test,
const void *test_data)
{
return test_fd_speedX(test, test_data, 0);
}
static bool test_fd_speed2(struct torture_context *test,
const void *test_data)
{
return test_fd_speedX(test, test_data, 1);
}
static bool test_fd_speed3(struct torture_context *test,
const void *test_data)
{
return test_fd_speedX(test, test_data, 2);
}
struct test_event_fd1_state {
struct torture_context *tctx;
const char *backend;
struct tevent_context *ev;
int sock[2];
struct tevent_timer *te;
struct tevent_fd *fde0;
struct tevent_fd *fde1;
bool got_write;
bool got_read;
bool drain;
bool drain_done;
unsigned loop_count;
bool finished;
const char *error;
};
static void test_event_fd1_fde_handler(struct tevent_context *ev_ctx,
struct tevent_fd *fde,
uint16_t flags,
void *private_data)
{
struct test_event_fd1_state *state =
(struct test_event_fd1_state *)private_data;
if (state->drain_done) {
state->finished = true;
state->error = __location__;
return;
}
if (state->drain) {
ssize_t ret;
uint8_t c = 0;
if (!(flags & TEVENT_FD_READ)) {
state->finished = true;
state->error = __location__;
return;
}
ret = read(state->sock[0], &c, 1);
if (ret == 1) {
return;
}
/*
* end of test...
*/
tevent_fd_set_flags(fde, 0);
state->drain_done = true;
return;
}
if (!state->got_write) {
uint8_t c = 0;
if (flags != TEVENT_FD_WRITE) {
state->finished = true;
state->error = __location__;
return;
}
state->got_write = true;
/*
* we write to the other socket...
*/
do_write(state->sock[1], &c, 1);
TEVENT_FD_NOT_WRITEABLE(fde);
TEVENT_FD_READABLE(fde);
return;
}
if (!state->got_read) {
if (flags != TEVENT_FD_READ) {
state->finished = true;
state->error = __location__;
return;
}
state->got_read = true;
TEVENT_FD_NOT_READABLE(fde);
return;
}
state->finished = true;
state->error = __location__;
return;
}
static void test_event_fd1_finished(struct tevent_context *ev_ctx,
struct tevent_timer *te,
struct timeval tval,
void *private_data)
{
struct test_event_fd1_state *state =
(struct test_event_fd1_state *)private_data;
if (state->drain_done) {
state->finished = true;
return;
}
if (!state->got_write) {
state->finished = true;
state->error = __location__;
return;
}
if (!state->got_read) {
state->finished = true;
state->error = __location__;
return;
}
state->loop_count++;
if (state->loop_count > 3) {
state->finished = true;
state->error = __location__;
return;
}
state->got_write = false;
state->got_read = false;
tevent_fd_set_flags(state->fde0, TEVENT_FD_WRITE);
if (state->loop_count > 2) {
state->drain = true;
TALLOC_FREE(state->fde1);
TEVENT_FD_READABLE(state->fde0);
}
state->te = tevent_add_timer(state->ev, state->ev,
timeval_current_ofs(0,2000),
test_event_fd1_finished, state);
}
static bool test_event_fd1(struct torture_context *tctx,
const void *test_data)
{
struct test_event_fd1_state state;
int ret;
ZERO_STRUCT(state);
state.tctx = tctx;
state.backend = (const char *)test_data;
state.ev = test_tevent_context_init_byname(tctx, state.backend);
if (state.ev == NULL) {
torture_skip(tctx, talloc_asprintf(tctx,
"event backend '%s' not supported\n",
state.backend));
return true;
}
torture_comment(tctx, "backend '%s' - %s\n",
state.backend, __FUNCTION__);
/*
* This tests the following:
*
* It monitors the state of state.sock[0]
* with tevent_fd, but we never read/write on state.sock[0]
* while state.sock[1] * is only used to write a few bytes.
*
* We have a loop:
* - we wait only for TEVENT_FD_WRITE on state.sock[0]
* - we write 1 byte to state.sock[1]
* - we wait only for TEVENT_FD_READ on state.sock[0]
* - we disable events on state.sock[0]
* - the timer event restarts the loop
* Then we close state.sock[1]
* We have a loop:
* - we wait for TEVENT_FD_READ/WRITE on state.sock[0]
* - we try to read 1 byte
* - if the read gets an error of returns 0
* we disable the event handler
* - the timer finishes the test
*/
state.sock[0] = -1;
state.sock[1] = -1;
ret = socketpair(AF_UNIX, SOCK_STREAM, 0, state.sock);
torture_assert(tctx, ret == 0, "socketpair() failed");
state.te = tevent_add_timer(state.ev, state.ev,
timeval_current_ofs(0,10000),
test_event_fd1_finished, &state);
state.fde0 = tevent_add_fd(state.ev, state.ev,
state.sock[0], TEVENT_FD_WRITE,
test_event_fd1_fde_handler, &state);
/* state.fde1 is only used to auto close */
state.fde1 = tevent_add_fd(state.ev, state.ev,
state.sock[1], 0,
test_event_fd1_fde_handler, &state);
tevent_fd_set_auto_close(state.fde0);
tevent_fd_set_auto_close(state.fde1);
while (!state.finished) {
errno = 0;
if (tevent_loop_once(state.ev) == -1) {
talloc_free(state.ev);
torture_fail(tctx, talloc_asprintf(tctx,
"Failed event loop %s\n",
strerror(errno)));
}
}
talloc_free(state.ev);
torture_assert(tctx, state.error == NULL, talloc_asprintf(tctx,
"%s", state.error));
return true;
}
struct test_event_fd2_state {
struct torture_context *tctx;
const char *backend;
struct tevent_context *ev;
struct tevent_timer *te;
struct test_event_fd2_sock {
struct test_event_fd2_state *state;
int fd;
struct tevent_fd *fde;
size_t num_written;
size_t num_read;
bool got_full;
} sock0, sock1;
bool finished;
const char *error;
};
static void test_event_fd2_sock_handler(struct tevent_context *ev_ctx,
struct tevent_fd *fde,
uint16_t flags,
void *private_data)
{
struct test_event_fd2_sock *cur_sock =
(struct test_event_fd2_sock *)private_data;
struct test_event_fd2_state *state = cur_sock->state;
struct test_event_fd2_sock *oth_sock = NULL;
uint8_t v = 0, c;
ssize_t ret;
if (cur_sock == &state->sock0) {
oth_sock = &state->sock1;
} else {
oth_sock = &state->sock0;
}
if (oth_sock->num_written == 1) {
if (flags != (TEVENT_FD_READ | TEVENT_FD_WRITE)) {
state->finished = true;
state->error = __location__;
return;
}
}
if (cur_sock->num_read == oth_sock->num_written) {
state->finished = true;
state->error = __location__;
return;
}
if (!(flags & TEVENT_FD_READ)) {
state->finished = true;
state->error = __location__;
return;
}
if (oth_sock->num_read >= PIPE_BUF) {
/*
* On Linux we become writable once we've read
* one byte. On Solaris we only become writable
* again once we've read 4096 bytes. PIPE_BUF
* is probably a safe bet to test against.
*
* There should be room to write a byte again
*/
if (!(flags & TEVENT_FD_WRITE)) {
state->finished = true;
state->error = __location__;
return;
}
}
if ((flags & TEVENT_FD_WRITE) && !cur_sock->got_full) {
v = (uint8_t)cur_sock->num_written;
ret = write(cur_sock->fd, &v, 1);
if (ret != 1) {
state->finished = true;
state->error = __location__;
return;
}
cur_sock->num_written++;
if (cur_sock->num_written > 0x80000000) {
state->finished = true;
state->error = __location__;
return;
}
return;
}
if (!cur_sock->got_full) {
cur_sock->got_full = true;
if (!oth_sock->got_full) {
/*
* cur_sock is full,
* lets wait for oth_sock
* to be filled
*/
tevent_fd_set_flags(cur_sock->fde, 0);
return;
}
/*
* oth_sock waited for cur_sock,
* lets restart it
*/
tevent_fd_set_flags(oth_sock->fde,
TEVENT_FD_READ|TEVENT_FD_WRITE);
}
ret = read(cur_sock->fd, &v, 1);
if (ret != 1) {
state->finished = true;
state->error = __location__;
return;
}
c = (uint8_t)cur_sock->num_read;
if (c != v) {
state->finished = true;
state->error = __location__;
return;
}
cur_sock->num_read++;
if (cur_sock->num_read < oth_sock->num_written) {
/* there is more to read */
return;
}
/*
* we read everything, we need to remove TEVENT_FD_WRITE
* to avoid spinning
*/
TEVENT_FD_NOT_WRITEABLE(cur_sock->fde);
if (oth_sock->num_read == cur_sock->num_written) {
/*
* both directions are finished
*/
state->finished = true;
}
return;
}
static void test_event_fd2_finished(struct tevent_context *ev_ctx,
struct tevent_timer *te,
struct timeval tval,
void *private_data)
{
struct test_event_fd2_state *state =
(struct test_event_fd2_state *)private_data;
/*
* this should never be triggered
*/
state->finished = true;
state->error = __location__;
}
static bool test_event_fd2(struct torture_context *tctx,
const void *test_data)
{
struct test_event_fd2_state state;
int sock[2];
uint8_t c = 0;
ZERO_STRUCT(state);
state.tctx = tctx;
state.backend = (const char *)test_data;
state.ev = test_tevent_context_init_byname(tctx, state.backend);
if (state.ev == NULL) {
torture_skip(tctx, talloc_asprintf(tctx,
"event backend '%s' not supported\n",
state.backend));
return true;
}
torture_comment(tctx, "backend '%s' - %s\n",
state.backend, __FUNCTION__);
/*
* This tests the following
*
* - We write 1 byte to each socket
* - We wait for TEVENT_FD_READ/WRITE on both sockets
* - When we get TEVENT_FD_WRITE we write 1 byte
* until both socket buffers are full, which
* means both sockets only get TEVENT_FD_READ.
* - Then we read 1 byte until we have consumed
* all bytes the other end has written.
*/
sock[0] = -1;
sock[1] = -1;
socketpair(AF_UNIX, SOCK_STREAM, 0, sock);
/*
* the timer should never expire
*/
state.te = tevent_add_timer(state.ev, state.ev,
timeval_current_ofs(600, 0),
test_event_fd2_finished, &state);
state.sock0.state = &state;
state.sock0.fd = sock[0];
state.sock0.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
TEVENT_FD_READ | TEVENT_FD_WRITE,
test_event_fd2_sock_handler,
&state.sock0);
state.sock1.state = &state;
state.sock1.fd = sock[1];
state.sock1.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
TEVENT_FD_READ | TEVENT_FD_WRITE,
test_event_fd2_sock_handler,
&state.sock1);
tevent_fd_set_auto_close(state.sock0.fde);
tevent_fd_set_auto_close(state.sock1.fde);
do_write(state.sock0.fd, &c, 1);
state.sock0.num_written++;
do_write(state.sock1.fd, &c, 1);
state.sock1.num_written++;
while (!state.finished) {
errno = 0;
if (tevent_loop_once(state.ev) == -1) {
talloc_free(state.ev);
torture_fail(tctx, talloc_asprintf(tctx,
"Failed event loop %s\n",
strerror(errno)));
}
}
talloc_free(state.ev);
torture_assert(tctx, state.error == NULL, talloc_asprintf(tctx,
"%s", state.error));
return true;
}
struct test_event_fd3_state {
struct torture_context *tctx;
const char *backend;
struct tevent_context *ev;
struct timeval start_time;
struct tevent_timer *te1, *te2, *te3, *te4, *te5;
struct test_event_fd3_sock {
struct test_event_fd3_state *state;
const char *sock_name;
int fd;
const char *phase_name;
uint64_t iteration_id;
uint64_t max_iterations;
uint16_t expected_flags;
uint8_t expected_count;
uint8_t actual_count;
struct test_event_fd3_fde {
struct test_event_fd3_sock *sock;
struct tevent_fd *fde;
uint64_t last_iteration_id;
} fde1, fde2, fde3, fde4, fde5, fde6, fde7, fde8, fde9;
void (*fde_callback)(struct test_event_fd3_fde *tfde,
uint16_t flags);
} sock0, sock1;
bool finished;
const char *error;
};
static void test_event_fd3_fde_callback(struct test_event_fd3_fde *tfde,
uint16_t flags)
{
struct test_event_fd3_sock *sock = tfde->sock;
struct test_event_fd3_state *state = sock->state;
uint16_t fde_flags = tevent_fd_get_flags(tfde->fde);
uint16_t expected_flags = sock->expected_flags & fde_flags;
if (expected_flags == 0) {
state->finished = true;
state->error = __location__;
return;
}
if (flags != expected_flags) {
state->finished = true;
state->error = __location__;
return;
}
if (tfde->last_iteration_id == sock->iteration_id) {
state->finished = true;
state->error = __location__;
return;
}
tfde->last_iteration_id = sock->iteration_id;
sock->actual_count += 1;
if (sock->actual_count > sock->expected_count) {
state->finished = true;
state->error = __location__;
return;
}
if (sock->actual_count == sock->expected_count) {
sock->actual_count = 0;
sock->iteration_id += 1;
}
if (sock->iteration_id > sock->max_iterations) {
torture_comment(state->tctx,
"%s: phase[%s] finished with %"PRIu64" iterations\n",
sock->sock_name,
sock->phase_name,
sock->max_iterations);
tevent_fd_set_flags(sock->fde1.fde, 0);
tevent_fd_set_flags(sock->fde2.fde, 0);
tevent_fd_set_flags(sock->fde3.fde, 0);
tevent_fd_set_flags(sock->fde4.fde, 0);
tevent_fd_set_flags(sock->fde5.fde, 0);
tevent_fd_set_flags(sock->fde6.fde, 0);
tevent_fd_set_flags(sock->fde7.fde, 0);
tevent_fd_set_flags(sock->fde8.fde, 0);
tevent_fd_set_flags(sock->fde9.fde, 0);
sock->fde_callback = NULL;
}
}
static void test_event_fd3_prepare_phase(struct test_event_fd3_sock *sock,
const char *phase_name,
uint64_t max_iterations,
uint16_t expected_flags,
uint8_t expected_count,
uint16_t flags1,
uint16_t flags2,
uint16_t flags3,
uint16_t flags4,
uint16_t flags5,
uint16_t flags6,
uint16_t flags7,
uint16_t flags8,
uint16_t flags9)
{
struct test_event_fd3_state *state = sock->state;
if (sock->fde_callback != NULL) {
state->finished = true;
state->error = __location__;
return;
}
sock->phase_name = phase_name;
sock->max_iterations = max_iterations;
sock->expected_flags = expected_flags;
sock->expected_count = expected_count;
sock->iteration_id = 1;
sock->actual_count = 0;
tevent_fd_set_flags(sock->fde1.fde, flags1);
sock->fde1.last_iteration_id = 0;
tevent_fd_set_flags(sock->fde2.fde, flags2);
sock->fde2.last_iteration_id = 0;
tevent_fd_set_flags(sock->fde3.fde, flags3);
sock->fde3.last_iteration_id = 0;
tevent_fd_set_flags(sock->fde4.fde, flags4);
sock->fde4.last_iteration_id = 0;
tevent_fd_set_flags(sock->fde5.fde, flags5);
sock->fde5.last_iteration_id = 0;
tevent_fd_set_flags(sock->fde6.fde, flags6);
sock->fde6.last_iteration_id = 0;
tevent_fd_set_flags(sock->fde7.fde, flags7);
sock->fde7.last_iteration_id = 0;
tevent_fd_set_flags(sock->fde8.fde, flags8);
sock->fde8.last_iteration_id = 0;
tevent_fd_set_flags(sock->fde9.fde, flags9);
sock->fde9.last_iteration_id = 0;
sock->fde_callback = test_event_fd3_fde_callback;
}
static void test_event_fd3_sock_handler(struct tevent_context *ev_ctx,
struct tevent_fd *fde,
uint16_t flags,
void *private_data)
{
struct test_event_fd3_fde *tfde =
(struct test_event_fd3_fde *)private_data;
struct test_event_fd3_sock *sock = tfde->sock;
struct test_event_fd3_state *state = sock->state;
if (sock->fd == -1) {
state->finished = true;
state->error = __location__;
return;
}
if (sock->fde_callback == NULL) {
state->finished = true;
state->error = __location__;
return;
}
sock->fde_callback(tfde, flags);
return;
}
static bool test_event_fd3_assert_timeout(struct test_event_fd3_state *state,
double expected_elapsed,
const char *func)
{
double e = timeval_elapsed(&state->start_time);
double max_latency = 0.05;
if (e < expected_elapsed) {
torture_comment(state->tctx,
"%s: elapsed=%.6f < expected_elapsed=%.6f\n",
func, e, expected_elapsed);
state->finished = true;
state->error = __location__;
return false;
}
if (e > (expected_elapsed + max_latency)) {
torture_comment(state->tctx,
"%s: elapsed=%.6f > "
"(expected_elapsed=%.6f + max_latency=%.6f)\n",
func, e, expected_elapsed, max_latency);
state->finished = true;
state->error = __location__;
return false;
}
torture_comment(state->tctx, "%s: elapsed=%.6f\n", __func__, e);
return true;
}
static void test_event_fd3_writeable(struct tevent_context *ev_ctx,
struct tevent_timer *te,
struct timeval tval,
void *private_data)
{
struct test_event_fd3_state *state =
(struct test_event_fd3_state *)private_data;
if (!test_event_fd3_assert_timeout(state, 1, __func__)) {
return;
}
test_event_fd3_prepare_phase(&state->sock0,
__func__,
INT8_MAX,
TEVENT_FD_WRITE,
5,
TEVENT_FD_WRITE,
0,
TEVENT_FD_READ,
TEVENT_FD_WRITE,
TEVENT_FD_READ|TEVENT_FD_WRITE,
TEVENT_FD_READ,
TEVENT_FD_WRITE,
TEVENT_FD_READ|TEVENT_FD_WRITE,
0);
test_event_fd3_prepare_phase(&state->sock1,
__func__,
INT8_MAX,
TEVENT_FD_WRITE,
9,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR);
}
static void test_event_fd3_readable(struct tevent_context *ev_ctx,
struct tevent_timer *te,
struct timeval tval,
void *private_data)
{
struct test_event_fd3_state *state =
(struct test_event_fd3_state *)private_data;
uint8_t c = 0;
if (!test_event_fd3_assert_timeout(state, 2, __func__)) {
return;
}
do_write(state->sock0.fd, &c, 1);
do_write(state->sock1.fd, &c, 1);
test_event_fd3_prepare_phase(&state->sock0,
__func__,
INT8_MAX,
TEVENT_FD_READ|TEVENT_FD_WRITE,
9,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR);
test_event_fd3_prepare_phase(&state->sock1,
__func__,
INT8_MAX,
TEVENT_FD_READ|TEVENT_FD_WRITE,
7,
TEVENT_FD_READ,
TEVENT_FD_READ|TEVENT_FD_WRITE,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
0,
TEVENT_FD_READ,
TEVENT_FD_WRITE,
TEVENT_FD_ERROR,
TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE);
}
static void test_event_fd3_not_writeable(struct tevent_context *ev_ctx,
struct tevent_timer *te,
struct timeval tval,
void *private_data)
{
struct test_event_fd3_state *state =
(struct test_event_fd3_state *)private_data;
if (!test_event_fd3_assert_timeout(state, 3, __func__)) {
return;
}
do_fill(state->sock0.fd);
do_fill(state->sock1.fd);
test_event_fd3_prepare_phase(&state->sock0,
__func__,
INT8_MAX,
TEVENT_FD_READ,
5,
TEVENT_FD_READ|TEVENT_FD_WRITE,
TEVENT_FD_WRITE,
TEVENT_FD_READ,
0,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_ERROR,
TEVENT_FD_ERROR,
TEVENT_FD_READ);
test_event_fd3_prepare_phase(&state->sock1,
__func__,
INT8_MAX,
TEVENT_FD_READ,
9,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR);
}
static void test_event_fd3_off(struct tevent_context *ev_ctx,
struct tevent_timer *te,
struct timeval tval,
void *private_data)
{
struct test_event_fd3_state *state =
(struct test_event_fd3_state *)private_data;
if (!test_event_fd3_assert_timeout(state, 4, __func__)) {
return;
}
TALLOC_FREE(state->sock0.fde1.fde);
state->sock0.fd = -1;
test_event_fd3_prepare_phase(&state->sock1,
__func__,
INT8_MAX,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
7,
TEVENT_FD_READ|TEVENT_FD_WRITE,
TEVENT_FD_WRITE,
TEVENT_FD_READ,
0,
TEVENT_FD_READ|TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_WRITE|TEVENT_FD_ERROR,
TEVENT_FD_READ|TEVENT_FD_ERROR,
TEVENT_FD_ERROR,
TEVENT_FD_READ);
}
static void test_event_fd3_finished(struct tevent_context *ev_ctx,
struct tevent_timer *te,
struct timeval tval,
void *private_data)
{
struct test_event_fd3_state *state =
(struct test_event_fd3_state *)private_data;
if (!test_event_fd3_assert_timeout(state, 5, __func__)) {
return;
}
/*
* this should never be triggered
*/
if (state->sock0.fde_callback != NULL) {
state->finished = true;
state->error = __location__;
return;
}
if (state->sock1.fde_callback != NULL) {
state->finished = true;
state->error = __location__;
return;
}
state->finished = true;
}
static bool test_event_fd3(struct torture_context *tctx,
const void *test_data)
{
struct test_event_fd3_state state = {
.tctx = tctx,
.backend = (const char *)test_data,
};
int rc;
int sock[2];
state.ev = test_tevent_context_init_byname(tctx, state.backend);
if (state.ev == NULL) {
torture_skip(tctx, talloc_asprintf(tctx,
"event backend '%s' not supported\n",
state.backend));
return true;
}
torture_comment(tctx, "backend '%s' - %s\n",
state.backend, __FUNCTION__);
sock[0] = -1;
sock[1] = -1;
rc = socketpair(AF_UNIX, SOCK_STREAM, 0, sock);
torture_assert_int_equal(tctx, rc, 0, "socketpair()");
state.start_time = timeval_current();
state.te1 = tevent_add_timer(state.ev, state.ev,
timeval_add(&state.start_time, 5, 0),
test_event_fd3_finished, &state);
torture_assert(tctx, state.te1 != NULL, "tevent_add_timer()");
state.te2 = tevent_add_timer(state.ev, state.ev,
timeval_add(&state.start_time, 1, 0),
test_event_fd3_writeable, &state);
torture_assert(tctx, state.te2 != NULL, "tevent_add_timer()");
state.te3 = tevent_add_timer(state.ev, state.ev,
timeval_add(&state.start_time, 2, 0),
test_event_fd3_readable, &state);
torture_assert(tctx, state.te3 != NULL, "tevent_add_timer()");
state.te4 = tevent_add_timer(state.ev, state.ev,
timeval_add(&state.start_time, 3, 0),
test_event_fd3_not_writeable, &state);
torture_assert(tctx, state.te4 != NULL, "tevent_add_timer()");
state.te5 = tevent_add_timer(state.ev, state.ev,
timeval_add(&state.start_time, 4, 0),
test_event_fd3_off, &state);
torture_assert(tctx, state.te5 != NULL, "tevent_add_timer()");
state.sock0.state = &state;
state.sock0.sock_name = "sock0";
state.sock0.fd = sock[0];
state.sock0.fde1.sock = &state.sock0;
state.sock0.fde1.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
0,
test_event_fd3_sock_handler,
&state.sock0.fde1);
torture_assert(tctx, state.sock0.fde1.fde != NULL, "tevent_add_fd()");
tevent_fd_set_auto_close(state.sock0.fde1.fde);
state.sock0.fde2.sock = &state.sock0;
state.sock0.fde2.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
0,
test_event_fd3_sock_handler,
&state.sock0.fde2);
torture_assert(tctx, state.sock0.fde2.fde != NULL, "tevent_add_fd()");
state.sock0.fde3.sock = &state.sock0;
state.sock0.fde3.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
0,
test_event_fd3_sock_handler,
&state.sock0.fde3);
torture_assert(tctx, state.sock0.fde3.fde != NULL, "tevent_add_fd()");
state.sock0.fde4.sock = &state.sock0;
state.sock0.fde4.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
0,
test_event_fd3_sock_handler,
&state.sock0.fde4);
torture_assert(tctx, state.sock0.fde4.fde != NULL, "tevent_add_fd()");
state.sock0.fde5.sock = &state.sock0;
state.sock0.fde5.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
0,
test_event_fd3_sock_handler,
&state.sock0.fde5);
torture_assert(tctx, state.sock0.fde5.fde != NULL, "tevent_add_fd()");
state.sock0.fde6.sock = &state.sock0;
state.sock0.fde6.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
0,
test_event_fd3_sock_handler,
&state.sock0.fde6);
torture_assert(tctx, state.sock0.fde6.fde != NULL, "tevent_add_fd()");
state.sock0.fde7.sock = &state.sock0;
state.sock0.fde7.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
0,
test_event_fd3_sock_handler,
&state.sock0.fde7);
torture_assert(tctx, state.sock0.fde7.fde != NULL, "tevent_add_fd()");
state.sock0.fde8.sock = &state.sock0;
state.sock0.fde8.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
0,
test_event_fd3_sock_handler,
&state.sock0.fde8);
torture_assert(tctx, state.sock0.fde8.fde != NULL, "tevent_add_fd()");
state.sock0.fde9.sock = &state.sock0;
state.sock0.fde9.fde = tevent_add_fd(state.ev, state.ev,
state.sock0.fd,
0,
test_event_fd3_sock_handler,
&state.sock0.fde9);
torture_assert(tctx, state.sock0.fde9.fde != NULL, "tevent_add_fd()");
state.sock1.state = &state;
state.sock1.sock_name = "sock1";
state.sock1.fd = sock[1];
state.sock1.fde1.sock = &state.sock1;
state.sock1.fde1.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
1,
test_event_fd3_sock_handler,
&state.sock1.fde1);
torture_assert(tctx, state.sock1.fde1.fde != NULL, "tevent_add_fd()");
tevent_fd_set_auto_close(state.sock1.fde1.fde);
state.sock1.fde2.sock = &state.sock1;
state.sock1.fde2.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
0,
test_event_fd3_sock_handler,
&state.sock1.fde2);
torture_assert(tctx, state.sock1.fde2.fde != NULL, "tevent_add_fd()");
state.sock1.fde3.sock = &state.sock1;
state.sock1.fde3.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
0,
test_event_fd3_sock_handler,
&state.sock1.fde3);
torture_assert(tctx, state.sock1.fde3.fde != NULL, "tevent_add_fd()");
state.sock1.fde4.sock = &state.sock1;
state.sock1.fde4.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
0,
test_event_fd3_sock_handler,
&state.sock1.fde4);
torture_assert(tctx, state.sock1.fde4.fde != NULL, "tevent_add_fd()");
state.sock1.fde5.sock = &state.sock1;
state.sock1.fde5.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
0,
test_event_fd3_sock_handler,
&state.sock1.fde5);
torture_assert(tctx, state.sock1.fde5.fde != NULL, "tevent_add_fd()");
state.sock1.fde6.sock = &state.sock1;
state.sock1.fde6.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
0,
test_event_fd3_sock_handler,
&state.sock1.fde6);
torture_assert(tctx, state.sock1.fde6.fde != NULL, "tevent_add_fd()");
state.sock1.fde7.sock = &state.sock1;
state.sock1.fde7.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
0,
test_event_fd3_sock_handler,
&state.sock1.fde7);
torture_assert(tctx, state.sock1.fde7.fde != NULL, "tevent_add_fd()");
state.sock1.fde8.sock = &state.sock1;
state.sock1.fde8.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
0,
test_event_fd3_sock_handler,
&state.sock1.fde8);
torture_assert(tctx, state.sock1.fde8.fde != NULL, "tevent_add_fd()");
state.sock1.fde9.sock = &state.sock1;
state.sock1.fde9.fde = tevent_add_fd(state.ev, state.ev,
state.sock1.fd,
0,
test_event_fd3_sock_handler,
&state.sock1.fde9);
torture_assert(tctx, state.sock1.fde9.fde != NULL, "tevent_add_fd()");
while (!state.finished) {
errno = 0;
if (tevent_loop_once(state.ev) == -1) {
talloc_free(state.ev);
torture_fail(tctx, talloc_asprintf(tctx,
"Failed event loop %s\n",
strerror(errno)));
}
}
talloc_free(state.ev);
torture_assert(tctx, state.error == NULL, talloc_asprintf(tctx,
"%s", state.error));
return true;
}
struct test_wrapper_state {
struct torture_context *tctx;
int num_events;
int num_wrap_handlers;
};
static bool test_wrapper_before_use(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
return true;
}
static void test_wrapper_after_use(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
}
static void test_wrapper_before_fd_handler(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
struct tevent_fd *fde,
uint16_t flags,
const char *handler_name,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
}
static void test_wrapper_after_fd_handler(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
struct tevent_fd *fde,
uint16_t flags,
const char *handler_name,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
}
static void test_wrapper_before_timer_handler(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
struct tevent_timer *te,
struct timeval requested_time,
struct timeval trigger_time,
const char *handler_name,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
}
static void test_wrapper_after_timer_handler(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
struct tevent_timer *te,
struct timeval requested_time,
struct timeval trigger_time,
const char *handler_name,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
}
static void test_wrapper_before_immediate_handler(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
struct tevent_immediate *im,
const char *handler_name,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
}
static void test_wrapper_after_immediate_handler(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
struct tevent_immediate *im,
const char *handler_name,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
}
static void test_wrapper_before_signal_handler(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
struct tevent_signal *se,
int signum,
int count,
void *siginfo,
const char *handler_name,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
}
static void test_wrapper_after_signal_handler(struct tevent_context *wrap_ev,
void *private_data,
struct tevent_context *main_ev,
struct tevent_signal *se,
int signum,
int count,
void *siginfo,
const char *handler_name,
const char *location)
{
struct test_wrapper_state *state =
talloc_get_type_abort(private_data,
struct test_wrapper_state);
torture_comment(state->tctx, "%s\n", __func__);
state->num_wrap_handlers++;
}
static const struct tevent_wrapper_ops test_wrapper_ops = {
.name = "test_wrapper",
.before_use = test_wrapper_before_use,
.after_use = test_wrapper_after_use,
.before_fd_handler = test_wrapper_before_fd_handler,
.after_fd_handler = test_wrapper_after_fd_handler,
.before_timer_handler = test_wrapper_before_timer_handler,
.after_timer_handler = test_wrapper_after_timer_handler,
.before_immediate_handler = test_wrapper_before_immediate_handler,
.after_immediate_handler = test_wrapper_after_immediate_handler,
.before_signal_handler = test_wrapper_before_signal_handler,
.after_signal_handler = test_wrapper_after_signal_handler,
};
static void test_wrapper_timer_handler(struct tevent_context *ev,
struct tevent_timer *te,
struct timeval tv,
void *private_data)
{
struct test_wrapper_state *state =
(struct test_wrapper_state *)private_data;
torture_comment(state->tctx, "timer handler\n");
state->num_events++;
talloc_free(te);
return;
}
static void test_wrapper_fd_handler(struct tevent_context *ev,
struct tevent_fd *fde,
unsigned short fd_flags,
void *private_data)
{
struct test_wrapper_state *state =
(struct test_wrapper_state *)private_data;
torture_comment(state->tctx, "fd handler\n");
state->num_events++;
talloc_free(fde);
return;
}
static void test_wrapper_immediate_handler(struct tevent_context *ev,
struct tevent_immediate *im,
void *private_data)
{
struct test_wrapper_state *state =
(struct test_wrapper_state *)private_data;
state->num_events++;
talloc_free(im);
torture_comment(state->tctx, "immediate handler\n");
return;
}
static void test_wrapper_signal_handler(struct tevent_context *ev,
struct tevent_signal *se,
int signum,
int count,
void *siginfo,
void *private_data)
{
struct test_wrapper_state *state =
(struct test_wrapper_state *)private_data;
torture_comment(state->tctx, "signal handler\n");
state->num_events++;
talloc_free(se);
return;
}
static bool test_wrapper(struct torture_context *tctx,
const void *test_data)
{
struct test_wrapper_state *state = NULL;
int sock[2] = { -1, -1};
uint8_t c = 0;
const int num_events = 4;
const char *backend = (const char *)test_data;
struct tevent_context *ev = NULL;
struct tevent_context *wrap_ev = NULL;
struct tevent_fd *fde = NULL;
struct tevent_timer *te = NULL;
struct tevent_signal *se = NULL;
struct tevent_immediate *im = NULL;
int ret;
bool ok = false;
bool ret2;
ev = test_tevent_context_init_byname(tctx, backend);
if (ev == NULL) {
torture_skip(tctx, talloc_asprintf(tctx,
"event backend '%s' not supported\n",
backend));
return true;
}
torture_comment(tctx, "tevent backend '%s'\n", backend);
wrap_ev = tevent_context_wrapper_create(
ev, ev, &test_wrapper_ops, &state, struct test_wrapper_state);
torture_assert_not_null_goto(tctx, wrap_ev, ok, done,
"tevent_context_wrapper_create failed\n");
*state = (struct test_wrapper_state) {
.tctx = tctx,
};
ret = socketpair(AF_UNIX, SOCK_STREAM, 0, sock);
torture_assert_goto(tctx, ret == 0, ok, done, "socketpair failed\n");
te = tevent_add_timer(wrap_ev, wrap_ev,
timeval_current_ofs(0, 0),
test_wrapper_timer_handler, state);
torture_assert_not_null_goto(tctx, te, ok, done,
"tevent_add_timer failed\n");
fde = tevent_add_fd(wrap_ev, wrap_ev,
sock[1],
TEVENT_FD_READ,
test_wrapper_fd_handler,
state);
torture_assert_not_null_goto(tctx, fde, ok, done,
"tevent_add_fd failed\n");
im = tevent_create_immediate(wrap_ev);
torture_assert_not_null_goto(tctx, im, ok, done,
"tevent_create_immediate failed\n");
se = tevent_add_signal(wrap_ev, wrap_ev,
SIGUSR1,
0,
test_wrapper_signal_handler,
state);
torture_assert_not_null_goto(tctx, se, ok, done,
"tevent_add_signal failed\n");
do_write(sock[0], &c, 1);
kill(getpid(), SIGUSR1);
tevent_schedule_immediate(im,
wrap_ev,
test_wrapper_immediate_handler,
state);
ret2 = tevent_context_push_use(wrap_ev);
torture_assert_goto(tctx, ret2, ok, done, "tevent_context_push_use(wrap_ev) failed\n");
ret2 = tevent_context_push_use(ev);
torture_assert_goto(tctx, ret2, ok, pop_use, "tevent_context_push_use(ev) failed\n");
tevent_context_pop_use(ev);
tevent_context_pop_use(wrap_ev);
ret = tevent_loop_wait(ev);
torture_assert_int_equal_goto(tctx, ret, 0, ok, done, "tevent_loop_wait failed\n");
torture_comment(tctx, "Num events: %d\n", state->num_events);
torture_comment(tctx, "Num wrap handlers: %d\n",
state->num_wrap_handlers);
torture_assert_int_equal_goto(tctx, state->num_events, num_events, ok, done,
"Wrong event count\n");
torture_assert_int_equal_goto(tctx, state->num_wrap_handlers,
num_events*2+2,
ok, done, "Wrong wrapper count\n");
ok = true;
done:
TALLOC_FREE(wrap_ev);
TALLOC_FREE(ev);
if (sock[0] != -1) {
close(sock[0]);
}
if (sock[1] != -1) {
close(sock[1]);
}
return ok;
pop_use:
tevent_context_pop_use(wrap_ev);
goto done;
}
static void test_free_wrapper_signal_handler(struct tevent_context *ev,
struct tevent_signal *se,
int signum,
int count,
void *siginfo,
void *private_data)
{
struct torture_context *tctx =
talloc_get_type_abort(private_data,
struct torture_context);
torture_comment(tctx, "signal handler\n");
talloc_free(se);
/*
* signal handlers have highest priority in tevent, so this signal
* handler will always be started before the other handlers
* below. Freeing the (wrapper) event context here tests that the
* wrapper implementation correctly handles the wrapper ev going away
* with pending events.
*/
talloc_free(ev);
return;
}
static void test_free_wrapper_fd_handler(struct tevent_context *ev,
struct tevent_fd *fde,
unsigned short fd_flags,
void *private_data)
{
/*
* This should never be called as
* test_free_wrapper_signal_handler()
* already destroyed the wrapper tevent_context.
*/
abort();
}
static void test_free_wrapper_immediate_handler(struct tevent_context *ev,
struct tevent_immediate *im,
void *private_data)
{
/*
* This should never be called as
* test_free_wrapper_signal_handler()
* already destroyed the wrapper tevent_context.
*/
abort();
}
static void test_free_wrapper_timer_handler(struct tevent_context *ev,
struct tevent_timer *te,
struct timeval tv,
void *private_data)
{
/*
* This should never be called as
* test_free_wrapper_signal_handler()
* already destroyed the wrapper tevent_context.
*/
abort();
}
static bool test_free_wrapper(struct torture_context *tctx,
const void *test_data)
{
struct test_wrapper_state *state = NULL;
int sock[2] = { -1, -1};
uint8_t c = 0;
const char *backend = (const char *)test_data;
TALLOC_CTX *frame = talloc_stackframe();
struct tevent_context *ev = NULL;
struct tevent_context *wrap_ev = NULL;
struct tevent_fd *fde = NULL;
struct tevent_timer *te = NULL;
struct tevent_signal *se = NULL;
struct tevent_immediate *im = NULL;
int ret;
bool ok = false;
ev = test_tevent_context_init_byname(frame, backend);
if (ev == NULL) {
torture_skip(tctx, talloc_asprintf(tctx,
"event backend '%s' not supported\n",
backend));
return true;
}
torture_comment(tctx, "tevent backend '%s'\n", backend);
wrap_ev = tevent_context_wrapper_create(
ev, ev, &test_wrapper_ops, &state, struct test_wrapper_state);
torture_assert_not_null_goto(tctx, wrap_ev, ok, done,
"tevent_context_wrapper_create failed\n");
*state = (struct test_wrapper_state) {
.tctx = tctx,
};
ret = socketpair(AF_UNIX, SOCK_STREAM, 0, sock);
torture_assert_goto(tctx, ret == 0, ok, done, "socketpair failed\n");
fde = tevent_add_fd(wrap_ev, frame,
sock[1],
TEVENT_FD_READ,
test_free_wrapper_fd_handler,
NULL);
torture_assert_not_null_goto(tctx, fde, ok, done,
"tevent_add_fd failed\n");
te = tevent_add_timer(wrap_ev, frame,
timeval_current_ofs(0, 0),
test_free_wrapper_timer_handler, NULL);
torture_assert_not_null_goto(tctx, te, ok, done,
"tevent_add_timer failed\n");
im = tevent_create_immediate(frame);
torture_assert_not_null_goto(tctx, im, ok, done,
"tevent_create_immediate failed\n");
se = tevent_add_signal(wrap_ev, frame,
SIGUSR1,
0,
test_free_wrapper_signal_handler,
tctx);
torture_assert_not_null_goto(tctx, se, ok, done,
"tevent_add_signal failed\n");
do_write(sock[0], &c, 1);
kill(getpid(), SIGUSR1);
tevent_schedule_immediate(im,
wrap_ev,
test_free_wrapper_immediate_handler,
NULL);
ret = tevent_loop_wait(ev);
torture_assert_goto(tctx, ret == 0, ok, done, "tevent_loop_wait failed\n");
ok = true;
done:
TALLOC_FREE(frame);
if (sock[0] != -1) {
close(sock[0]);
}
if (sock[1] != -1) {
close(sock[1]);
}
return ok;
}
#ifdef HAVE_PTHREAD
static pthread_mutex_t threaded_mutex = PTHREAD_MUTEX_INITIALIZER;
static bool do_shutdown = false;
static void test_event_threaded_lock(void)
{
int ret;
ret = pthread_mutex_lock(&threaded_mutex);
assert(ret == 0);
}
static void test_event_threaded_unlock(void)
{
int ret;
ret = pthread_mutex_unlock(&threaded_mutex);
assert(ret == 0);
}
static void test_event_threaded_trace(enum tevent_trace_point point,
void *private_data)
{
switch (point) {
case TEVENT_TRACE_BEFORE_WAIT:
test_event_threaded_unlock();
break;
case TEVENT_TRACE_AFTER_WAIT:
test_event_threaded_lock();
break;
case TEVENT_TRACE_BEFORE_LOOP_ONCE:
case TEVENT_TRACE_AFTER_LOOP_ONCE:
break;
}
}
static void test_event_threaded_timer(struct tevent_context *ev,
struct tevent_timer *te,
struct timeval current_time,
void *private_data)
{
return;
}
static void *test_event_poll_thread(void *private_data)
{
struct tevent_context *ev = (struct tevent_context *)private_data;
test_event_threaded_lock();
while (true) {
int ret;
ret = tevent_loop_once(ev);
assert(ret == 0);
if (do_shutdown) {
test_event_threaded_unlock();
return NULL;
}
}
}
static void test_event_threaded_read_handler(struct tevent_context *ev,
struct tevent_fd *fde,
uint16_t flags,
void *private_data)
{
int *pfd = (int *)private_data;
char c;
ssize_t nread;
if ((flags & TEVENT_FD_READ) == 0) {
return;
}
do {
nread = read(*pfd, &c, 1);
} while ((nread == -1) && (errno == EINTR));
assert(nread == 1);
}
static bool test_event_context_threaded(struct torture_context *test,
const void *test_data)
{
struct tevent_context *ev;
struct tevent_timer *te;
struct tevent_fd *fde;
pthread_t poll_thread;
int fds[2];
int ret;
char c = 0;
ev = test_tevent_context_init_byname(test, "poll_mt");
torture_assert(test, ev != NULL, "poll_mt not supported");
tevent_set_trace_callback(ev, test_event_threaded_trace, NULL);
te = tevent_add_timer(ev, ev, timeval_current_ofs(5, 0),
test_event_threaded_timer, NULL);
torture_assert(test, te != NULL, "Could not add timer");
ret = pthread_create(&poll_thread, NULL, test_event_poll_thread, ev);
torture_assert(test, ret == 0, "Could not create poll thread");
ret = pipe(fds);
torture_assert(test, ret == 0, "Could not create pipe");
poll(NULL, 0, 100);
test_event_threaded_lock();
fde = tevent_add_fd(ev, ev, fds[0], TEVENT_FD_READ,
test_event_threaded_read_handler, &fds[0]);
torture_assert(test, fde != NULL, "Could not add fd event");
test_event_threaded_unlock();
poll(NULL, 0, 100);
do_write(fds[1], &c, 1);
poll(NULL, 0, 100);
test_event_threaded_lock();
do_shutdown = true;
test_event_threaded_unlock();
do_write(fds[1], &c, 1);
ret = pthread_join(poll_thread, NULL);
torture_assert(test, ret == 0, "pthread_join failed");
return true;
}
#define NUM_TEVENT_THREADS 100
/* Ugly, but needed for torture_comment... */
static struct torture_context *thread_test_ctx;
static pthread_t thread_map[NUM_TEVENT_THREADS];
static unsigned thread_counter;
/* Called in master thread context */
static void callback_nowait(struct tevent_context *ev,
struct tevent_immediate *im,
void *private_ptr)
{
pthread_t *thread_id_ptr =
talloc_get_type_abort(private_ptr, pthread_t);
unsigned i;
for (i = 0; i < NUM_TEVENT_THREADS; i++) {
if (pthread_equal(*thread_id_ptr,
thread_map[i])) {
break;
}
}
torture_comment(thread_test_ctx,
"Callback %u from thread %u\n",
thread_counter,
i);
thread_counter++;
}
/* Blast the master tevent_context with a callback, no waiting. */
static void *thread_fn_nowait(void *private_ptr)
{
struct tevent_thread_proxy *master_tp =
talloc_get_type_abort(private_ptr, struct tevent_thread_proxy);
struct tevent_immediate *im;
pthread_t *thread_id_ptr;
im = tevent_create_immediate(NULL);
if (im == NULL) {
return NULL;
}
thread_id_ptr = talloc(NULL, pthread_t);
if (thread_id_ptr == NULL) {
return NULL;
}
*thread_id_ptr = pthread_self();
tevent_thread_proxy_schedule(master_tp,
&im,
callback_nowait,
&thread_id_ptr);
return NULL;
}
static void timeout_fn(struct tevent_context *ev,
struct tevent_timer *te,
struct timeval tv, void *p)
{
thread_counter = NUM_TEVENT_THREADS * 10;
}
static bool test_multi_tevent_threaded(struct torture_context *test,
const void *test_data)
{
unsigned i;
struct tevent_context *master_ev;
struct tevent_thread_proxy *tp;
talloc_disable_null_tracking();
/* Ugly global stuff. */
thread_test_ctx = test;
thread_counter = 0;
master_ev = test_tevent_context_init(NULL);
if (master_ev == NULL) {
return false;
}
tp = tevent_thread_proxy_create(master_ev);
if (tp == NULL) {
torture_fail(test,
talloc_asprintf(test,
"tevent_thread_proxy_create failed\n"));
talloc_free(master_ev);
return false;
}
for (i = 0; i < NUM_TEVENT_THREADS; i++) {
int ret = pthread_create(&thread_map[i],
NULL,
thread_fn_nowait,
tp);
if (ret != 0) {
torture_fail(test,
talloc_asprintf(test,
"Failed to create thread %i, %d\n",
i, ret));
return false;
}
}
/* Ensure we don't wait more than 10 seconds. */
tevent_add_timer(master_ev,
master_ev,
timeval_current_ofs(10,0),
timeout_fn,
NULL);
while (thread_counter < NUM_TEVENT_THREADS) {
int ret = tevent_loop_once(master_ev);
torture_assert(test, ret == 0, "tevent_loop_once failed");
}
torture_assert(test, thread_counter == NUM_TEVENT_THREADS,
"thread_counter fail\n");
talloc_free(master_ev);
return true;
}
struct reply_state {
struct tevent_thread_proxy *reply_tp;
pthread_t thread_id;
int *p_finished;
};
static void thread_timeout_fn(struct tevent_context *ev,
struct tevent_timer *te,
struct timeval tv, void *p)
{
int *p_finished = (int *)p;
*p_finished = 2;
}
/* Called in child-thread context */
static void thread_callback(struct tevent_context *ev,
struct tevent_immediate *im,
void *private_ptr)
{
struct reply_state *rsp =
talloc_get_type_abort(private_ptr, struct reply_state);
talloc_steal(ev, rsp);
*rsp->p_finished = 1;
}
/* Called in master thread context */
static void master_callback(struct tevent_context *ev,
struct tevent_immediate *im,
void *private_ptr)
{
struct reply_state *rsp =
talloc_get_type_abort(private_ptr, struct reply_state);
unsigned i;
talloc_steal(ev, rsp);
for (i = 0; i < NUM_TEVENT_THREADS; i++) {
if (pthread_equal(rsp->thread_id,
thread_map[i])) {
break;
}
}
torture_comment(thread_test_ctx,
"Callback %u from thread %u\n",
thread_counter,
i);
/* Now reply to the thread ! */
tevent_thread_proxy_schedule(rsp->reply_tp,
&im,
thread_callback,
&rsp);
thread_counter++;
}
static void *thread_fn_1(void *private_ptr)
{
struct tevent_thread_proxy *master_tp =
talloc_get_type_abort(private_ptr, struct tevent_thread_proxy);
struct tevent_thread_proxy *tp;
struct tevent_immediate *im;
struct tevent_context *ev;
struct reply_state *rsp;
int finished = 0;
int ret;
ev = tevent_context_init(NULL);
if (ev == NULL) {
return NULL;
}
tp = tevent_thread_proxy_create(ev);
if (tp == NULL) {
talloc_free(ev);
return NULL;
}
im = tevent_create_immediate(ev);
if (im == NULL) {
talloc_free(ev);
return NULL;
}
rsp = talloc(ev, struct reply_state);
if (rsp == NULL) {
talloc_free(ev);
return NULL;
}
rsp->thread_id = pthread_self();
rsp->reply_tp = tp;
rsp->p_finished = &finished;
/* Introduce a little randomness into the mix.. */
usleep(random() % 7000);
tevent_thread_proxy_schedule(master_tp,
&im,
master_callback,
&rsp);
/* Ensure we don't wait more than 10 seconds. */
tevent_add_timer(ev,
ev,
timeval_current_ofs(10,0),
thread_timeout_fn,
&finished);
while (finished == 0) {
ret = tevent_loop_once(ev);
assert(ret == 0);
}
if (finished > 1) {
/* Timeout ! */
abort();
}
/*
* NB. We should talloc_free(ev) here, but if we do
* we currently get hit by helgrind Fix #323432
* "When calling pthread_cond_destroy or pthread_mutex_destroy
* with initializers as argument Helgrind (incorrectly) reports errors."
*
* http://valgrind.10908.n7.nabble.com/Helgrind-3-9-0-false-positive-
* with-pthread-mutex-destroy-td47757.html
*
* Helgrind doesn't understand that the request/reply
* messages provide synchronization between the lock/unlock
* in tevent_thread_proxy_schedule(), and the pthread_destroy()
* when the struct tevent_thread_proxy object is talloc_free'd.
*
* As a work-around for now return ev for the parent thread to free.
*/
return ev;
}
static bool test_multi_tevent_threaded_1(struct torture_context *test,
const void *test_data)
{
unsigned i;
struct tevent_context *master_ev;
struct tevent_thread_proxy *master_tp;
int ret;
talloc_disable_null_tracking();
/* Ugly global stuff. */
thread_test_ctx = test;
thread_counter = 0;
master_ev = test_tevent_context_init(NULL);
if (master_ev == NULL) {
return false;
}
master_tp = tevent_thread_proxy_create(master_ev);
if (master_tp == NULL) {
torture_fail(test,
talloc_asprintf(test,
"tevent_thread_proxy_create failed\n"));
talloc_free(master_ev);
return false;
}
for (i = 0; i < NUM_TEVENT_THREADS; i++) {
ret = pthread_create(&thread_map[i],
NULL,
thread_fn_1,
master_tp);
if (ret != 0) {
torture_fail(test,
talloc_asprintf(test,
"Failed to create thread %i, %d\n",
i, ret));
return false;
}
}
while (thread_counter < NUM_TEVENT_THREADS) {
ret = tevent_loop_once(master_ev);
torture_assert(test, ret == 0, "tevent_loop_once failed");
}
/* Wait for all the threads to finish - join 'em. */
for (i = 0; i < NUM_TEVENT_THREADS; i++) {
void *retval;
ret = pthread_join(thread_map[i], &retval);
torture_assert(test, ret == 0, "pthread_join failed");
/* Free the child thread event context. */
talloc_free(retval);
}
talloc_free(master_ev);
return true;
}
struct threaded_test_2 {
struct tevent_threaded_context *tctx;
struct tevent_immediate *im;
pthread_t thread_id;
};
static void master_callback_2(struct tevent_context *ev,
struct tevent_immediate *im,
void *private_data);
static void *thread_fn_2(void *private_data)
{
struct threaded_test_2 *state = private_data;
state->thread_id = pthread_self();
usleep(random() % 7000);
tevent_threaded_schedule_immediate(
state->tctx, state->im, master_callback_2, state);
return NULL;
}
static void master_callback_2(struct tevent_context *ev,
struct tevent_immediate *im,
void *private_data)
{
struct threaded_test_2 *state = private_data;
int i;
for (i = 0; i < NUM_TEVENT_THREADS; i++) {
if (pthread_equal(state->thread_id, thread_map[i])) {
break;
}
}
torture_comment(thread_test_ctx,
"Callback_2 %u from thread %u\n",
thread_counter,
i);
thread_counter++;
}
static bool test_multi_tevent_threaded_2(struct torture_context *test,
const void *test_data)
{
unsigned i;
struct tevent_context *ev;
struct tevent_threaded_context *tctx;
int ret;
thread_test_ctx = test;
thread_counter = 0;
ev = test_tevent_context_init(test);
torture_assert(test, ev != NULL, "tevent_context_init failed");
/*
* tevent_re_initialise used to have a bug where it did not
* re-initialise the thread support after taking it
* down. Exercise that code path.
*/
ret = tevent_re_initialise(ev);
torture_assert(test, ret == 0, "tevent_re_initialise failed");
tctx = tevent_threaded_context_create(ev, ev);
torture_assert(test, tctx != NULL,
"tevent_threaded_context_create failed");
for (i=0; itctx = tctx;
state->im = tevent_create_immediate(state);
torture_assert(test, state->im != NULL,
"tevent_create_immediate failed");
ret = pthread_create(&thread_map[i], NULL, thread_fn_2, state);
torture_assert(test, ret == 0, "pthread_create failed");
}
while (thread_counter < NUM_TEVENT_THREADS) {
ret = tevent_loop_once(ev);
torture_assert(test, ret == 0, "tevent_loop_once failed");
}
/* Wait for all the threads to finish - join 'em. */
for (i = 0; i < NUM_TEVENT_THREADS; i++) {
void *retval;
ret = pthread_join(thread_map[i], &retval);
torture_assert(test, ret == 0, "pthread_join failed");
/* Free the child thread event context. */
}
talloc_free(tctx);
talloc_free(ev);
return true;
}
struct test_cached_pid_thread_state {
pid_t thread_cached_pid;
pid_t thread_pid;
};
static void *test_cached_pid_thread(void *private_data)
{
struct test_cached_pid_thread_state *state =
(struct test_cached_pid_thread_state *)private_data;
state->thread_cached_pid = tevent_cached_getpid();
state->thread_pid = getpid();
return NULL;
}
#endif
static bool test_cached_pid(struct torture_context *test,
const void *test_data)
{
pid_t parent_pid = getpid();
pid_t child_pid;
pid_t finished_pid;
int child_status;
torture_assert(test, tevent_cached_getpid() == parent_pid, "tevent_cached_getpid()");
#ifdef HAVE_PTHREAD
{
struct test_cached_pid_thread_state state = { .thread_cached_pid = -1, };
pthread_t thread;
void *retval = NULL;
int ret;
ret = pthread_create(&thread, NULL, test_cached_pid_thread, &state);
torture_assert(test, ret == 0, "pthread_create failed");
ret = pthread_join(thread, &retval);
torture_assert(test, ret == 0, "pthread_join failed");
torture_assert(test, state.thread_pid == parent_pid, "getpid() in thread");
torture_assert(test, state.thread_cached_pid == parent_pid, "tevent_cached_getpid() in thread");
}
#endif /* HAVE_PTHREAD */
child_pid = fork();
if (child_pid == 0) {
/* child */
pid_t pid = getpid();
pid_t cached_pid = tevent_cached_getpid();
if (parent_pid == pid) {
exit(1);
}
if (pid != cached_pid) {
exit(2);
}
exit(0);
}
torture_assert(test, child_pid > 0, "fork failed");
finished_pid = waitpid(child_pid, &child_status, 0);
torture_assert(test, finished_pid == child_pid, "wrong child");
torture_assert(test, child_status == 0, "child_status");
return true;
}
struct torture_suite *torture_local_event(TALLOC_CTX *mem_ctx)
{
struct torture_suite *suite = torture_suite_create(mem_ctx, "event");
const char **list = tevent_backend_list(suite);
int i;
for (i=0;list && list[i];i++) {
struct torture_suite *backend_suite;
backend_suite = torture_suite_create(mem_ctx, list[i]);
torture_suite_add_simple_tcase_const(backend_suite,
"context",
test_event_context,
(const void *)list[i]);
torture_suite_add_simple_tcase_const(backend_suite,
"fd_speed1",
test_fd_speed1,
(const void *)list[i]);
torture_suite_add_simple_tcase_const(backend_suite,
"fd_speed2",
test_fd_speed2,
(const void *)list[i]);
torture_suite_add_simple_tcase_const(backend_suite,
"fd_speed3",
test_fd_speed3,
(const void *)list[i]);
torture_suite_add_simple_tcase_const(backend_suite,
"fd1",
test_event_fd1,
(const void *)list[i]);
torture_suite_add_simple_tcase_const(backend_suite,
"fd2",
test_event_fd2,
(const void *)list[i]);
torture_suite_add_simple_tcase_const(backend_suite,
"fd3",
test_event_fd3,
(const void *)list[i]);
torture_suite_add_simple_tcase_const(backend_suite,
"wrapper",
test_wrapper,
(const void *)list[i]);
torture_suite_add_simple_tcase_const(backend_suite,
"free_wrapper",
test_free_wrapper,
(const void *)list[i]);
torture_suite_add_suite(suite, backend_suite);
}
#ifdef HAVE_PTHREAD
torture_suite_add_simple_tcase_const(suite, "threaded_poll_mt",
test_event_context_threaded,
NULL);
torture_suite_add_simple_tcase_const(suite, "multi_tevent_threaded",
test_multi_tevent_threaded,
NULL);
torture_suite_add_simple_tcase_const(suite, "multi_tevent_threaded_1",
test_multi_tevent_threaded_1,
NULL);
torture_suite_add_simple_tcase_const(suite, "multi_tevent_threaded_2",
test_multi_tevent_threaded_2,
NULL);
#endif
torture_suite_add_simple_tcase_const(suite, "tevent_cached_getpid",
test_cached_pid,
NULL);
return suite;
}