/*
Copyright (c) 2007-2016 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/>.
*/
#ifndef __ZMQ_PIPE_HPP_INCLUDED__
#define __ZMQ_PIPE_HPP_INCLUDED__
#include "msg.hpp"
#include "ypipe_base.hpp"
#include "config.hpp"
#include "object.hpp"
#include "stdint.hpp"
#include "array.hpp"
#include "blob.hpp"
namespace zmq
{
class object_t;
class pipe_t;
// Create a pipepair for bi-directional transfer of messages.
// First HWM is for messages passed from first pipe to the second pipe.
// Second HWM is for messages passed from second pipe to the first pipe.
// Delay specifies how the pipe behaves when the peer terminates. If true
// pipe receives all the pending messages before terminating, otherwise it
// terminates straight away.
// If conflate is true, only the most recently arrived message could be
// read (older messages are discarded)
int pipepair (zmq::object_t *parents_ [2], zmq::pipe_t* pipes_ [2],
int hwms_ [2], bool conflate_ [2]);
struct i_pipe_events
{
virtual ~i_pipe_events () {}
virtual void read_activated (zmq::pipe_t *pipe_) = 0;
virtual void write_activated (zmq::pipe_t *pipe_) = 0;
virtual void hiccuped (zmq::pipe_t *pipe_) = 0;
virtual void pipe_terminated (zmq::pipe_t *pipe_) = 0;
};
// Note that pipe can be stored in three different arrays.
// The array of inbound pipes (1), the array of outbound pipes (2) and
// the generic array of pipes to be deallocated (3).
class pipe_t :
public object_t,
public array_item_t <1>,
public array_item_t <2>,
public array_item_t <3>
{
// This allows pipepair to create pipe objects.
friend int pipepair (zmq::object_t *parents_ [2], zmq::pipe_t* pipes_ [2],
int hwms_ [2], bool conflate_ [2]);
public:
// Specifies the object to send events to.
void set_event_sink (i_pipe_events *sink_);
// Pipe endpoint can store an routing ID to be used by its clients.
void set_server_socket_routing_id (uint32_t routing_id_);
uint32_t get_server_socket_routing_id ();
// Pipe endpoint can store an opaque ID to be used by its clients.
void set_router_socket_routing_id (const blob_t &identity_);
const blob_t &get_routing_id ();
const blob_t &get_credential () const;
// Returns true if there is at least one message to read in the pipe.
bool check_read ();
// Reads a message to the underlying pipe.
bool read (msg_t *msg_);
// Checks whether messages can be written to the pipe. If the pipe is
// closed or if writing the message would cause high watermark the
// function returns false.
bool check_write ();
// Writes a message to the underlying pipe. Returns false if the
// message does not pass check_write. If false, the message object
// retains ownership of its message buffer.
bool write (msg_t *msg_);
// Remove unfinished parts of the outbound message from the pipe.
void rollback ();
// Flush the messages downstream.
void flush ();
// Temporarily disconnects the inbound message stream and drops
// all the messages on the fly. Causes 'hiccuped' event to be generated
// in the peer.
void hiccup ();
// Ensure the pipe won't block on receiving pipe_term.
void set_nodelay ();
// Ask pipe to terminate. The termination will happen asynchronously
// and user will be notified about actual deallocation by 'terminated'
// event. If delay is true, the pending messages will be processed
// before actual shutdown.
void terminate (bool delay_);
// Set the high water marks.
void set_hwms (int inhwm_, int outhwm_);
// Set the boost to high water marks, used by inproc sockets so total hwm are sum of connect and bind sockets watermarks
void set_hwms_boost(int inhwmboost_, int outhwmboost_);
// send command to peer for notify the change of hwm
void send_hwms_to_peer(int inhwm_, int outhwm_);
// Returns true if HWM is not reached
bool check_hwm () const;
private:
// Type of the underlying lock-free pipe.
typedef ypipe_base_t <msg_t> upipe_t;
// Command handlers.
void process_activate_read ();
void process_activate_write (uint64_t msgs_read_);
void process_hiccup (void *pipe_);
void process_pipe_term ();
void process_pipe_term_ack ();
void process_pipe_hwm (int inhwm_, int outhwm_);
// Handler for delimiter read from the pipe.
void process_delimiter ();
// Constructor is private. Pipe can only be created using
// pipepair function.
pipe_t (object_t *parent_, upipe_t *inpipe_, upipe_t *outpipe_,
int inhwm_, int outhwm_, bool conflate_);
// Pipepair uses this function to let us know about
// the peer pipe object.
void set_peer (pipe_t *pipe_);
// Destructor is private. Pipe objects destroy themselves.
~pipe_t ();
// Underlying pipes for both directions.
upipe_t *inpipe;
upipe_t *outpipe;
// Can the pipe be read from / written to?
bool in_active;
bool out_active;
// High watermark for the outbound pipe.
int hwm;
// Low watermark for the inbound pipe.
int lwm;
// boosts for high and low watermarks, used with inproc sockets so hwm are sum of send and recv hmws on each side of pipe
int inhwmboost;
int outhwmboost;
// Number of messages read and written so far.
uint64_t msgs_read;
uint64_t msgs_written;
// Last received peer's msgs_read. The actual number in the peer
// can be higher at the moment.
uint64_t peers_msgs_read;
// The pipe object on the other side of the pipepair.
pipe_t *peer;
// Sink to send events to.
i_pipe_events *sink;
// States of the pipe endpoint:
// active: common state before any termination begins,
// delimiter_received: delimiter was read from pipe before
// term command was received,
// waiting_for_delimiter: term command was already received
// from the peer but there are still pending messages to read,
// term_ack_sent: all pending messages were already read and
// all we are waiting for is ack from the peer,
// term_req_sent1: 'terminate' was explicitly called by the user,
// term_req_sent2: user called 'terminate' and then we've got
// term command from the peer as well.
enum {
active,
delimiter_received,
waiting_for_delimiter,
term_ack_sent,
term_req_sent1,
term_req_sent2
} state;
// If true, we receive all the pending inbound messages before
// terminating. If false, we terminate immediately when the peer
// asks us to.
bool delay;
// Routing id of the writer. Used uniquely by the reader side.
blob_t router_socket_routing_id;
// Routing id of the writer. Used uniquely by the reader side.
int server_socket_routing_id;
// Pipe's credential.
blob_t credential;
// Returns true if the message is delimiter; false otherwise.
static bool is_delimiter (const msg_t &msg_);
// Computes appropriate low watermark from the given high watermark.
static int compute_lwm (int hwm_);
const bool conflate;
// Disable copying.
pipe_t (const pipe_t&);
const pipe_t &operator = (const pipe_t&);
};
}
#endif