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libzmq/tests/test_zmq_ppoll_signals.cpp

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/* SPDX-License-Identifier: MPL-2.0 */
// author: E. G. Patrick Bos, Netherlands eScience Center, 2021
#include "testutil.hpp"
#include "testutil_unity.hpp"
#include <string.h> // memset
// types.h and wait.h for waitpid:
#include <sys/types.h>
#include <sys/wait.h>
static bool sigterm_received = false;
void handle_sigterm (int /*signum*/)
{
sigterm_received = true;
}
void recv_string_expect_success_or_eagain (void *socket_,
const char *str_,
int flags_)
{
const size_t len = str_ ? strlen (str_) : 0;
char buffer[255];
TEST_ASSERT_LESS_OR_EQUAL_MESSAGE (sizeof (buffer), len,
"recv_string_expect_success cannot be "
"used for strings longer than 255 "
"characters");
const int rc = zmq_recv (socket_, buffer, sizeof (buffer), flags_);
if (rc < 0) {
if (errno == EAGAIN) {
printf ("got EAGAIN\n");
return;
} else {
TEST_ASSERT_SUCCESS_ERRNO (rc);
}
} else {
TEST_ASSERT_EQUAL_INT ((int) len, rc);
if (str_)
TEST_ASSERT_EQUAL_STRING_LEN (str_, buffer, len);
}
}
void test_ppoll_signals ()
{
#ifdef ZMQ_HAVE_PPOLL
size_t len = MAX_SOCKET_STRING;
char my_endpoint[MAX_SOCKET_STRING];
pid_t child_pid;
/* Get a random TCP port first */
setup_test_context ();
void *sb = test_context_socket (ZMQ_REP);
bind_loopback (sb, 0, my_endpoint, len);
test_context_socket_close (sb);
teardown_test_context ();
do {
child_pid = fork ();
} while (child_pid == -1); // retry if fork fails
if (child_pid > 0) { // parent
setup_test_context ();
void *socket = test_context_socket (ZMQ_REQ);
// to make sure we don't hang when the child has already exited at the end, we set a receive timeout of five seconds
int recv_timeout = 5000;
TEST_ASSERT_SUCCESS_ERRNO (zmq_setsockopt (
socket, ZMQ_RCVTIMEO, &recv_timeout, sizeof (recv_timeout)));
TEST_ASSERT_SUCCESS_ERRNO (zmq_bind (socket, my_endpoint));
// bind is on the master process to avoid zombie children to hold on to binds
// first send a test message to check whether the signal mask is setup in the child process
send_string_expect_success (socket, "breaker breaker", 0);
recv_string_expect_success (socket, "one-niner", 0);
// then send the signal
kill (child_pid, SIGTERM);
// for good measure, and to make sure everything went as expected, close off with another handshake, which will trigger the second poll call on the other side
send_string_expect_success (socket, "breaker breaker", 0);
// in case the 1 second sleep was not enough on the child side, we are also fine with an EAGAIN here
recv_string_expect_success_or_eagain (socket, "one-niner", 0);
// finish
test_context_socket_close (socket);
teardown_test_context ();
// wait for child
int status = 0;
pid_t pid;
do {
pid = waitpid (child_pid, &status, 0);
} while (-1 == pid
&& EINTR == errno); // retry on interrupted system call
if (0 != status) {
if (WIFEXITED (status)) {
printf ("exited, status=%d\n", WEXITSTATUS (status));
} else if (WIFSIGNALED (status)) {
printf ("killed by signal %d\n", WTERMSIG (status));
} else if (WIFSTOPPED (status)) {
printf ("stopped by signal %d\n", WSTOPSIG (status));
} else if (WIFCONTINUED (status)) {
printf ("continued\n");
}
}
if (-1 == pid) {
printf ("waitpid returned -1, with errno %s\n", strerror (errno));
}
} else { // child
setup_test_context ();
// set up signal mask and install handler for SIGTERM
sigset_t sigmask, sigmask_without_sigterm;
sigemptyset (&sigmask);
sigaddset (&sigmask, SIGTERM);
sigprocmask (SIG_BLOCK, &sigmask, &sigmask_without_sigterm);
struct sigaction sa;
memset (&sa, '\0', sizeof (sa));
sa.sa_handler = handle_sigterm;
TEST_ASSERT_SUCCESS_ERRNO (sigaction (SIGTERM, &sa, NULL));
void *socket = test_context_socket (ZMQ_REP);
TEST_ASSERT_SUCCESS_ERRNO (zmq_connect (socket, my_endpoint));
zmq_pollitem_t pollitems[] = {
{socket, 0, ZMQ_POLLIN, 0},
};
// first receive test message and send back handshake
recv_string_expect_success (socket, "breaker breaker", 0);
send_string_expect_success (socket, "one-niner", 0);
// now start ppolling, which should exit with EINTR because of the SIGTERM
TEST_ASSERT_FAILURE_ERRNO (
EINTR, zmq_ppoll (pollitems, 1, -1, &sigmask_without_sigterm));
TEST_ASSERT_TRUE (sigterm_received);
// poll again for the final handshake
TEST_ASSERT_SUCCESS_ERRNO (
zmq_ppoll (pollitems, 1, -1, &sigmask_without_sigterm));
TEST_ASSERT_BITS_HIGH (ZMQ_POLLIN, pollitems[0].revents);
// receive and send back handshake
recv_string_expect_success (socket, "breaker breaker", 0);
send_string_expect_success (socket, "one-niner", 0);
// finish
// wait before closing socket, so that parent has time to receive
sleep (1);
test_context_socket_close (socket);
teardown_test_context ();
_Exit (0);
}
#else
TEST_IGNORE_MESSAGE ("libzmq without zmq_ppoll, ignoring test");
#endif // ZMQ_HAVE_PPOLL
}
// We note that using zmq_poll instead of zmq_ppoll in the test above, while
// also not using the sigmask, will fail most of the time, because it is
// impossible to predict during which call the signal will be handled. Of
// course, every call could be surrounded with an EINTR check and a subsequent
// check of sigterm_received's value, but even then a race condition can occur,
// see the explanation given here: https://250bpm.com/blog:12/
int main ()
{
UNITY_BEGIN ();
RUN_TEST (test_ppoll_signals);
return UNITY_END ();
}