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libzmq/tests/test_proxy.cpp
Luca Boccassi 5934919f3e Problem: tests bind to hardcoded TCP ports
Solution: use ZMQ_LAST_ENDPOINT in most places. This alllows running
tests in paralle, and on over-booked shared machines where many of
the ports would be already in use.
Keep 3 tests with an hardcoded port, as there are some code paths that
require it (eg: connect before bind), but list those ports in
tests/testutil.hpp as macros so that they do not overlap and still
allow parallel runs.

These changes were inspired by a patch uploaded to Ubuntu by the
package maintainer, Steve Langasek <steve.langasek@ubuntu.com>.
Thank you Steve!
2017-05-01 22:57:05 +01:00

335 lines
12 KiB
C++

/*
Copyright (c) 2007-2017 Contributors as noted in the AUTHORS file
This file is part of libzmq, the ZeroMQ core engine in C++.
libzmq is free software; you can redistribute it and/or modify it under
the terms of the GNU Lesser General Public License (LGPL) as published
by the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
As a special exception, the Contributors give you permission to link
this library with independent modules to produce an executable,
regardless of the license terms of these independent modules, and to
copy and distribute the resulting executable under terms of your choice,
provided that you also meet, for each linked independent module, the
terms and conditions of the license of that module. An independent
module is a module which is not derived from or based on this library.
If you modify this library, you must extend this exception to your
version of the library.
libzmq 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 program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "testutil.hpp"
// Asynchronous client-to-server (DEALER to ROUTER) - pure libzmq
//
// While this example runs in a single process, that is to make
// it easier to start and stop the example. Each task may have its own
// context and conceptually acts as a separate process. To have this
// behaviour, it is necessary to replace the inproc transport of the
// control socket by a tcp transport.
// This is our client task
// It connects to the server, and then sends a request once per second
// It collects responses as they arrive, and it prints them out. We will
// run several client tasks in parallel, each with a different random ID.
#define CONTENT_SIZE 13
#define CONTENT_SIZE_MAX 32
#define ID_SIZE 10
#define ID_SIZE_MAX 32
#define QT_WORKERS 5
#define QT_CLIENTS 3
#define is_verbose 0
struct thread_data {
void *ctx;
int id;
};
static void
client_task (void *db)
{
struct thread_data *databag = (struct thread_data *)db;
// Endpoint socket gets random port to avoid test failing when port in use
void *endpoint = zmq_socket (databag->ctx, ZMQ_PAIR);
assert (endpoint);
int linger = 0;
int rc = zmq_setsockopt (endpoint, ZMQ_LINGER, &linger, sizeof (linger));
assert (rc == 0);
char endpoint_source [256];
sprintf (endpoint_source, "inproc://endpoint%d", databag->id);
rc = zmq_connect (endpoint, endpoint_source);
assert (rc == 0);
char *my_endpoint = s_recv (endpoint);
assert (my_endpoint);
void *client = zmq_socket (databag->ctx, ZMQ_DEALER);
assert (client);
// Control socket receives terminate command from main over inproc
void *control = zmq_socket (databag->ctx, ZMQ_SUB);
assert (control);
rc = zmq_setsockopt (control, ZMQ_SUBSCRIBE, "", 0);
assert (rc == 0);
rc = zmq_setsockopt (control, ZMQ_LINGER, &linger, sizeof (linger));
assert (rc == 0);
rc = zmq_connect (control, "inproc://control");
assert (rc == 0);
char content [CONTENT_SIZE_MAX];
// Set random identity to make tracing easier
char identity [ID_SIZE];
sprintf (identity, "%04X-%04X", rand() % 0xFFFF, rand() % 0xFFFF);
rc = zmq_setsockopt (client, ZMQ_IDENTITY, identity, ID_SIZE); // includes '\0' as an helper for printf
assert (rc == 0);
linger = 0;
rc = zmq_setsockopt (client, ZMQ_LINGER, &linger, sizeof (linger));
assert (rc == 0);
rc = zmq_connect (client, my_endpoint);
assert (rc == 0);
zmq_pollitem_t items [] = { { client, 0, ZMQ_POLLIN, 0 }, { control, 0, ZMQ_POLLIN, 0 } };
int request_nbr = 0;
bool run = true;
while (run) {
// Tick once per 200 ms, pulling in arriving messages
int centitick;
for (centitick = 0; centitick < 20; centitick++) {
zmq_poll (items, 2, 10);
if (items [0].revents & ZMQ_POLLIN) {
int rcvmore;
size_t sz = sizeof (rcvmore);
rc = zmq_recv (client, content, CONTENT_SIZE_MAX, 0);
assert (rc == CONTENT_SIZE);
if (is_verbose) printf("client receive - identity = %s content = %s\n", identity, content);
// Check that message is still the same
assert (memcmp (content, "request #", 9) == 0);
rc = zmq_getsockopt (client, ZMQ_RCVMORE, &rcvmore, &sz);
assert (rc == 0);
assert (!rcvmore);
}
if (items [1].revents & ZMQ_POLLIN) {
rc = zmq_recv (control, content, CONTENT_SIZE_MAX, 0);
if (is_verbose) printf("client receive - identity = %s command = %s\n", identity, content);
if (memcmp (content, "TERMINATE", 9) == 0) {
run = false;
break;
}
}
}
sprintf(content, "request #%03d", ++request_nbr); // CONTENT_SIZE
rc = zmq_send (client, content, CONTENT_SIZE, 0);
assert (rc == CONTENT_SIZE);
}
rc = zmq_close (client);
assert (rc == 0);
rc = zmq_close (control);
assert (rc == 0);
rc = zmq_close (endpoint);
assert (rc == 0);
free (my_endpoint);
}
// This is our server task.
// It uses the multithreaded server model to deal requests out to a pool
// of workers and route replies back to clients. One worker can handle
// one request at a time but one client can talk to multiple workers at
// once.
static void server_worker (void *ctx);
void
server_task (void *ctx)
{
// Frontend socket talks to clients over TCP
size_t len = MAX_SOCKET_STRING;
char my_endpoint[MAX_SOCKET_STRING];
void *frontend = zmq_socket (ctx, ZMQ_ROUTER);
assert (frontend);
int linger = 0;
int rc = zmq_setsockopt (frontend, ZMQ_LINGER, &linger, sizeof (linger));
assert (rc == 0);
rc = zmq_bind (frontend, "tcp://127.0.0.1:*");
assert (rc == 0);
rc = zmq_getsockopt (frontend, ZMQ_LAST_ENDPOINT, my_endpoint, &len);
assert (rc == 0);
// Backend socket talks to workers over inproc
void *backend = zmq_socket (ctx, ZMQ_DEALER);
assert (backend);
rc = zmq_setsockopt (backend, ZMQ_LINGER, &linger, sizeof (linger));
assert (rc == 0);
rc = zmq_bind (backend, "inproc://backend");
assert (rc == 0);
// Control socket receives terminate command from main over inproc
void *control = zmq_socket (ctx, ZMQ_SUB);
assert (control);
rc = zmq_setsockopt (control, ZMQ_SUBSCRIBE, "", 0);
assert (rc == 0);
rc = zmq_setsockopt (control, ZMQ_LINGER, &linger, sizeof (linger));
assert (rc == 0);
rc = zmq_connect (control, "inproc://control");
assert (rc == 0);
// Launch pool of worker threads, precise number is not critical
int thread_nbr;
void* threads [5];
for (thread_nbr = 0; thread_nbr < QT_WORKERS; thread_nbr++)
threads[thread_nbr] = zmq_threadstart (&server_worker, ctx);
// Endpoint socket sends random port to avoid test failing when port in use
void *endpoint_receivers [QT_CLIENTS];
char endpoint_source [256];
for (int i = 0; i < QT_CLIENTS; ++i) {
endpoint_receivers [i] = zmq_socket (ctx, ZMQ_PAIR);
assert (endpoint_receivers [i]);
rc = zmq_setsockopt (endpoint_receivers [i], ZMQ_LINGER, &linger,
sizeof (linger));
assert (rc == 0);
sprintf (endpoint_source, "inproc://endpoint%d", i);
rc = zmq_bind (endpoint_receivers [i], endpoint_source);
assert (rc == 0);
}
for (int i = 0; i < QT_CLIENTS; ++i) {
rc = s_send (endpoint_receivers [i], my_endpoint);
assert (rc > 0);
}
// Connect backend to frontend via a proxy
rc = zmq_proxy_steerable (frontend, backend, NULL, control);
assert (rc == 0);
for (thread_nbr = 0; thread_nbr < QT_WORKERS; thread_nbr++)
zmq_threadclose (threads[thread_nbr]);
rc = zmq_close (frontend);
assert (rc == 0);
rc = zmq_close (backend);
assert (rc == 0);
rc = zmq_close (control);
assert (rc == 0);
for (int i = 0; i < QT_CLIENTS; ++i) {
rc = zmq_close(endpoint_receivers [i]);
assert (rc == 0);
}
}
// Each worker task works on one request at a time and sends a random number
// of replies back, with random delays between replies:
// The comments in the first column, if suppressed, makes it a poller version
static void
server_worker (void *ctx)
{
void *worker = zmq_socket (ctx, ZMQ_DEALER);
assert (worker);
int linger = 0;
int rc = zmq_setsockopt (worker, ZMQ_LINGER, &linger, sizeof (linger));
assert (rc == 0);
rc = zmq_connect (worker, "inproc://backend");
assert (rc == 0);
// Control socket receives terminate command from main over inproc
void *control = zmq_socket (ctx, ZMQ_SUB);
assert (control);
rc = zmq_setsockopt (control, ZMQ_SUBSCRIBE, "", 0);
assert (rc == 0);
rc = zmq_setsockopt (control, ZMQ_LINGER, &linger, sizeof (linger));
assert (rc == 0);
rc = zmq_connect (control, "inproc://control");
assert (rc == 0);
char content [CONTENT_SIZE_MAX]; // bigger than what we need to check that
char identity [ID_SIZE_MAX]; // the size received is the size sent
bool run = true;
while (run) {
rc = zmq_recv (control, content, CONTENT_SIZE_MAX, ZMQ_DONTWAIT); // usually, rc == -1 (no message)
if (rc > 0) {
if (is_verbose)
printf("server_worker receives command = %s\n", content);
if (memcmp (content, "TERMINATE", 9) == 0)
run = false;
}
// The DEALER socket gives us the reply envelope and message
// if we don't poll, we have to use ZMQ_DONTWAIT, if we poll, we can block-receive with 0
rc = zmq_recv (worker, identity, ID_SIZE_MAX, ZMQ_DONTWAIT);
if (rc == ID_SIZE) {
rc = zmq_recv (worker, content, CONTENT_SIZE_MAX, 0);
assert (rc == CONTENT_SIZE);
if (is_verbose)
printf ("server receive - identity = %s content = %s\n", identity, content);
// Send 0..4 replies back
int reply, replies = rand() % 5;
for (reply = 0; reply < replies; reply++) {
// Sleep for some fraction of a second
msleep (rand () % 10 + 1);
// Send message from server to client
rc = zmq_send (worker, identity, ID_SIZE, ZMQ_SNDMORE);
assert (rc == ID_SIZE);
rc = zmq_send (worker, content, CONTENT_SIZE, 0);
assert (rc == CONTENT_SIZE);
}
}
}
rc = zmq_close (worker);
assert (rc == 0);
rc = zmq_close (control);
assert (rc == 0);
}
// The main thread simply starts several clients and a server, and then
// waits for the server to finish.
int main (void)
{
setup_test_environment ();
void *ctx = zmq_ctx_new ();
assert (ctx);
// Control socket receives terminate command from main over inproc
void *control = zmq_socket (ctx, ZMQ_PUB);
assert (control);
int linger = 0;
int rc = zmq_setsockopt (control, ZMQ_LINGER, &linger, sizeof (linger));
assert (rc == 0);
rc = zmq_bind (control, "inproc://control");
assert (rc == 0);
void *threads [QT_CLIENTS + 1];
struct thread_data databags [QT_CLIENTS + 1];
for (int i = 0; i < QT_CLIENTS; i++) {
databags [i].ctx = ctx;
databags [i].id = i;
threads[i] = zmq_threadstart (&client_task, &databags [i]);
}
threads[QT_CLIENTS] = zmq_threadstart (&server_task, ctx);
msleep (500); // Run for 500 ms then quit
rc = zmq_send (control, "TERMINATE", 9, 0);
assert (rc == 9);
rc = zmq_close (control);
assert (rc == 0);
for (int i = 0; i < QT_CLIENTS + 1; i++)
zmq_threadclose (threads[i]);
rc = zmq_ctx_term (ctx);
assert (rc == 0);
return 0;
}