Say I have a PUB
server that zmq_send()
\'s realtime messages to SUB
client. If client i
I'll answer my own question here. The setting ZMQ_CONFLATE "Keep only last message" seemed promising but it doesn't work with subscription filters. It only ever keeps one message in the queue. If you have more than one filter, both old and new messages of the other filters type gets thrown away.
Likewise the recommendation of the zeromq guide to simply to kill slow subscribers, but that doesn't seem like realistic solution. Having subscribers with different read speeds, subscribed to the same fast publisher, should be a normal use case. Some of these subscribers might live on slow computers others on fast ones, etc. ZeroMQ should be able to handle that somehow.
http://zguide.zeromq.org/page:all#Slow-Subscriber-Detection-Suicidal-Snail-Pattern
I ended up doing manual dropping of old queued up messages on the client side. It seems to work fine. I get subscribed messages to the client that are less than 3ms old (through tcp localhost) that way. This works even in cases where I have five thousand, 10 second old messages, in the queue in front of those few real-time message at the back. This is good enough for me.
I cant help but think this is something that should be provided by the library. It could probably do a better job of it.
Anyways here is the client side, old message dropping, code:
bool Empty(zmq::socket_t& socket) {
bool ret = true;
zmq::pollitem_t poll_item = { socket, 0, ZMQ_POLLIN, 0 };
zmq::poll(&poll_item, 1, 0); //0 = no wait
if (poll_item.revents & ZMQ_POLLIN) {
ret = false;
}
return ret;
}
std::vector GetRealtimeSubscribedMessageVec(zmq::socket_t& socket_sub, int timeout_ms)
{
std::vector ret;
struct MessageTmp {
int id_ = 0;
std::string data_;
boost::posix_time::ptime timestamp_;
};
std::map msg_map;
int read_msg_count = 0;
int time_in_loop = 0;
auto start_of_loop = boost::posix_time::microsec_clock::universal_time();
do {
read_msg_count++;
//msg format sent by publisher is: filter, timestamp, data
MessageTmp msg;
msg.id_ = boost::lexical_cast(s_recv(socket_sub));
msg.timestamp_ = boost::posix_time::time_from_string(s_recv(socket_sub));
msg.data_ = s_recv(socket_sub);
msg_map[msg.id_] = msg;
auto now = boost::posix_time::microsec_clock::universal_time();
time_in_loop = (now - start_of_loop).total_milliseconds();
if (time_in_loop > timeout_ms) {
std::cerr << "Timeout reached. Publisher is probably sending messages quicker than we can drop them." << std::endl;
break;
}
} while ((Empty(socket_sub) == false));
if (read_msg_count > 1) {
std::cout << "num of old queued up messages dropped: " << (read_msg_count - 1) << std::endl;
}
for (const auto &pair: msg_map) {
const auto& msg_tmp = pair.second;
auto now = boost::posix_time::microsec_clock::universal_time();
auto message_age_ms = (now - msg_tmp.timestamp_).total_milliseconds();
if (message_age_ms > timeout_ms) {
std::cerr << "[SUB] Newest message too old. f:" << msg_tmp.id_ << ", age: " << message_age_ms << "ms, s:" << msg_tmp.data_.size() << std::endl;
}
else {
std::cout << "[SUB] f:" << msg_tmp.id_ << ", age: " << message_age_ms << "ms, s:" << msg_tmp.data_.size() << std::endl;
ret.push_back(msg_tmp.data_);
}
}
return ret;
}