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/*
Copyright (c) 2007-2010 iMatix Corporation
This file is part of 0MQ.
0MQ is free software; you can redistribute it and/or modify it under
the terms of the Lesser GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
0MQ 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
Lesser GNU General Public License for more details.
You should have received a copy of the Lesser GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "../include/zmq.h"
#include "xrep.hpp"
#include "err.hpp"
#include "pipe.hpp"
zmq::xrep_t::xrep_t (class ctx_t *parent_, uint32_t slot_) :
socket_base_t (parent_, slot_),
current_in (0),
prefetched (false),
more_in (false),
current_out (NULL),
more_out (false),
terminating (false)
{
options.type = ZMQ_XREP;
options.requires_in = true;
options.requires_out = true;
// On connect, pipes are created only after initial handshaking.
// That way we are aware of the peer's identity when binding to the pipes.
options.immediate_connect = false;
}
zmq::xrep_t::~xrep_t ()
{
zmq_assert (inpipes.empty ());
zmq_assert (outpipes.empty ());
}
void zmq::xrep_t::xattach_pipes (reader_t *inpipe_, writer_t *outpipe_,
const blob_t &peer_identity_)
{
zmq_assert (inpipe_ && outpipe_);
outpipe_->set_event_sink (this);
// TODO: What if new connection has same peer identity as the old one?
outpipe_t outpipe = {outpipe_, true};
bool ok = outpipes.insert (std::make_pair (
peer_identity_, outpipe)).second;
zmq_assert (ok);
inpipe_->set_event_sink (this);
inpipe_t inpipe = {inpipe_, peer_identity_, true};
inpipes.push_back (inpipe);
if (terminating) {
register_term_acks (1);
inpipe_->terminate ();
}
}
void zmq::xrep_t::process_term ()
{
terminating = true;
register_term_acks (inpipes.size () + outpipes.size ());
for (inpipes_t::iterator it = inpipes.begin (); it != inpipes.end ();
it++)
it->reader->terminate ();
for (outpipes_t::iterator it = outpipes.begin (); it != outpipes.end ();
it++)
it->second.writer->terminate ();
socket_base_t::process_term ();
}
void zmq::xrep_t::terminated (reader_t *pipe_)
{
for (inpipes_t::iterator it = inpipes.begin (); it != inpipes.end ();
it++) {
if (it->reader == pipe_) {
inpipes.erase (it);
if (terminating)
unregister_term_ack ();
if (current_in >= inpipes.size ())
current_in = 0;
return;
}
}
zmq_assert (false);
}
void zmq::xrep_t::terminated (writer_t *pipe_)
{
for (outpipes_t::iterator it = outpipes.begin ();
it != outpipes.end (); ++it) {
if (it->second.writer == pipe_) {
outpipes.erase (it);
if (pipe_ == current_out)
current_out = NULL;
if (terminating)
unregister_term_ack ();
return;
}
}
zmq_assert (false);
}
void zmq::xrep_t::activated (reader_t *pipe_)
{
for (inpipes_t::iterator it = inpipes.begin (); it != inpipes.end ();
it++) {
if (it->reader == pipe_) {
zmq_assert (!it->active);
it->active = true;
return;
}
}
zmq_assert (false);
}
void zmq::xrep_t::activated (writer_t *pipe_)
{
for (outpipes_t::iterator it = outpipes.begin ();
it != outpipes.end (); ++it) {
if (it->second.writer == pipe_) {
zmq_assert (!it->second.active);
it->second.active = true;
return;
}
}
zmq_assert (false);
}
int zmq::xrep_t::xsend (zmq_msg_t *msg_, int flags_)
{
// If this is the first part of the message it's the identity of the
// peer to send the message to.
if (!more_out) {
zmq_assert (!current_out);
// If we have malformed message (prefix with no subsequent message)
// then just silently drop the message.
if ((msg_->flags & ZMQ_MSG_MORE) == 0)
return 0;
more_out = true;
// Find the pipe associated with the identity stored in the prefix.
// If there's no such pipe just silently drop the message.
blob_t identity ((unsigned char*) zmq_msg_data (msg_),
zmq_msg_size (msg_));
outpipes_t::iterator it = outpipes.find (identity);
if (it == outpipes.end ())
return 0;
// Remember the outgoing pipe.
current_out = it->second.writer;
return 0;
}
// Check whether this is the last part of the message.
more_out = msg_->flags & ZMQ_MSG_MORE;
// Push the message into the pipe. If there's no out pipe, just drop it.
if (current_out) {
bool ok = current_out->write (msg_);
zmq_assert (ok);
if (!more_out) {
current_out->flush ();
current_out = NULL;
}
}
else {
int rc = zmq_msg_close (msg_);
zmq_assert (rc == 0);
}
// Detach the message from the data buffer.
int rc = zmq_msg_init (msg_);
zmq_assert (rc == 0);
return 0;
}
int zmq::xrep_t::xrecv (zmq_msg_t *msg_, int flags_)
{
// If there is a prefetched message, return it.
if (prefetched) {
zmq_msg_move (msg_, &prefetched_msg);
more_in = msg_->flags & ZMQ_MSG_MORE;
prefetched = false;
return 0;
}
// Deallocate old content of the message.
zmq_msg_close (msg_);
// If we are in the middle of reading a message, just grab next part of it.
if (more_in) {
zmq_assert (inpipes [current_in].active);
bool fetched = inpipes [current_in].reader->read (msg_);
zmq_assert (fetched);
more_in = msg_->flags & ZMQ_MSG_MORE;
if (!more_in) {
current_in++;
if (current_in >= inpipes.size ())
current_in = 0;
}
return 0;
}
// Round-robin over the pipes to get the next message.
for (int count = inpipes.size (); count != 0; count--) {
// Try to fetch new message.
if (inpipes [current_in].active)
prefetched = inpipes [current_in].reader->read (&prefetched_msg);
// If we have a message, create a prefix and return it to the caller.
if (prefetched) {
int rc = zmq_msg_init_size (msg_,
inpipes [current_in].identity.size ());
zmq_assert (rc == 0);
memcpy (zmq_msg_data (msg_), inpipes [current_in].identity.data (),
zmq_msg_size (msg_));
msg_->flags = ZMQ_MSG_MORE;
return 0;
}
// If me don't have a message, mark the pipe as passive and
// move to next pipe.
inpipes [current_in].active = false;
current_in++;
if (current_in >= inpipes.size ())
current_in = 0;
}
// No message is available. Initialise the output parameter
// to be a 0-byte message.
zmq_msg_init (msg_);
errno = EAGAIN;
return -1;
}
bool zmq::xrep_t::xhas_in ()
{
// There are subsequent parts of the partly-read message available.
if (prefetched || more_in)
return true;
// Note that messing with current doesn't break the fairness of fair
// queueing algorithm. If there are no messages available current will
// get back to its original value. Otherwise it'll point to the first
// pipe holding messages, skipping only pipes with no messages available.
for (int count = inpipes.size (); count != 0; count--) {
if (inpipes [current_in].active &&
inpipes [current_in].reader->check_read ())
return true;
// If me don't have a message, mark the pipe as passive and
// move to next pipe.
inpipes [current_in].active = false;
current_in++;
if (current_in >= inpipes.size ())
current_in = 0;
}
return false;
}
bool zmq::xrep_t::xhas_out ()
{
// In theory, XREP socket is always ready for writing. Whether actual
// attempt to write succeeds depends on whitch pipe the message is going
// to be routed to.
return true;
}
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