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/*
Copyright (c) 2007-2009 FastMQ Inc.
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 "platform.hpp"
#ifdef ZMQ_HAVE_OPENPGM
#ifdef ZMQ_HAVE_WINDOWS
#include "windows.hpp"
#endif
#ifdef ZMQ_HAVE_LINUX
#include <poll.h>
// Has to be defined befiore including pgm/pgm.h
#define CONFIG_HAVE_POLL
#endif
#include <pgm/pgm.h>
#include <string>
#include <iostream>
#include "options.hpp"
#include "pgm_socket.hpp"
#include "config.hpp"
#include "err.hpp"
#include "uuid.hpp"
zmq::pgm_socket_t::pgm_socket_t (bool receiver_, const options_t &options_) :
transport (NULL),
options (options_),
receiver (receiver_),
port_number (0),
udp_encapsulation (false),
pgm_msgv (NULL),
nbytes_rec (0),
nbytes_processed (0),
pgm_msgv_processed (0),
pgm_msgv_len (0)
{
}
int zmq::pgm_socket_t::init (bool udp_encapsulation_, const char *network_)
{
udp_encapsulation = udp_encapsulation_;
// Parse port number.
const char *port_delim = strchr (network_, ':');
if (!port_delim) {
errno = EINVAL;
return -1;
}
port_number = atoi (port_delim + 1);
if (port_delim - network_ >= (int) sizeof (network) - 1) {
errno = EINVAL;
return -1;
}
memset (network, '\0', sizeof (network));
memcpy (network, network_, port_delim - network_);
// Open PGM transport.
int rc = open_transport ();
if (rc != 0)
return -1;
// For receiver transport preallocate pgm_msgv array.
// in_batch_size configured in confing.hpp
if (receiver) {
pgm_msgv_len = get_max_apdu_at_once (in_batch_size);
pgm_msgv = new pgm_msgv_t [pgm_msgv_len];
}
return 0;
}
int zmq::pgm_socket_t::open_transport ()
{
// Can not open transport before destroying old one.
zmq_assert (transport == NULL);
// Zero counter used in msgrecv.
nbytes_rec = 0;
nbytes_processed = 0;
pgm_msgv_processed = 0;
// TODO: Converting bool to int? Not nice.
int pgm_ok = true;
GError *pgm_error = NULL;
// Init PGM transport.
// Ensure threading enabled, ensure timer enabled and find PGM protocol id.
//
// Note that if you want to use gettimeofday and sleep for openPGM timing,
// set environment variables PGM_TIMER to "GTOD"
// and PGM_SLEEP to "USLEEP".
int rc = pgm_init ();
if (rc != 0) {
errno = EINVAL;
return -1;
}
// PGM transport GSI.
pgm_gsi_t gsi;
std::string gsi_base;
if (options.identity.size () > 0) {
// Create gsi from identity string.
gsi_base = options.identity;
} else {
// Generate random gsi.
gsi_base = uuid_t ().to_string ();
}
rc = pgm_gsi_create_from_string (&gsi, gsi_base.c_str (), -1);
if (rc != pgm_ok) {
errno = EINVAL;
return -1;
}
//zmq_log (1, "Transport GSI: %s, %s(%i)\n", pgm_print_gsi (&gsi),
// __FILE__, __LINE__);
struct pgm_transport_info_t *res = NULL;
if (!pgm_if_get_transport_info (network, NULL, &res, &pgm_error)) {
errno = EINVAL;
return -1;
}
res->ti_gsi = gsi;
res->ti_dport = port_number;
// If we are using UDP encapsulation update gsr or res.
if (udp_encapsulation) {
res->ti_udp_encap_ucast_port = port_number;
res->ti_udp_encap_mcast_port = port_number;
}
if (!pgm_transport_create (&transport, res, &pgm_error)) {
pgm_if_free_transport_info (res);
// TODO: tranlate errors from glib into errnos.
errno = EINVAL;
return -1;
}
pgm_if_free_transport_info (res);
// Common parameters for receiver and sender.
// Set maximum transport protocol data unit size (TPDU).
rc = pgm_transport_set_max_tpdu (transport, pgm_max_tpdu);
if (rc != pgm_ok) {
errno = EINVAL;
return -1;
}
// Set maximum number of network hops to cross.
rc = pgm_transport_set_hops (transport, 16);
if (rc != pgm_ok) {
errno = EINVAL;
return -1;
}
// Set nonblocking send/recv sockets.
if (!pgm_transport_set_nonblocking (transport, true)) {
errno = EINVAL;
return -1;
}
if (receiver) {
// Receiver transport.
// Set transport->can_send_data = FALSE.
// Note that NAKs are still generated by the transport.
rc = pgm_transport_set_recv_only (transport, true, false);
zmq_assert (rc == pgm_ok);
// Set NAK transmit back-off interval [us].
rc = pgm_transport_set_nak_bo_ivl (transport, 50 * 1000);
zmq_assert (rc == pgm_ok);
// Set timeout before repeating NAK [us].
rc = pgm_transport_set_nak_rpt_ivl (transport, 200 * 1000);
zmq_assert (rc == pgm_ok);
// Set timeout for receiving RDATA.
rc = pgm_transport_set_nak_rdata_ivl (transport, 200 * 1000);
zmq_assert (rc == pgm_ok);
// Set retries for NAK without NCF/DATA (NAK_DATA_RETRIES).
rc = pgm_transport_set_nak_data_retries (transport, 5);
zmq_assert (rc == pgm_ok);
// Set retries for NCF after NAK (NAK_NCF_RETRIES).
rc = pgm_transport_set_nak_ncf_retries (transport, 2);
zmq_assert (rc == pgm_ok);
// Set timeout for removing a dead peer [us].
rc = pgm_transport_set_peer_expiry (transport, 5 * 8192 * 1000);
zmq_assert (rc == pgm_ok);
// Set expiration time of SPM Requests [us].
rc = pgm_transport_set_spmr_expiry (transport, 25 * 1000);
zmq_assert (rc == pgm_ok);
// Set the size of the receive window.
// Data rate is in [B/s]. options.rate is in [kb/s].
if (options.rate <= 0) {
errno = EINVAL;
return -1;
}
rc = pgm_transport_set_rxw_max_rte (transport,
options.rate * 1000 / 8);
if (rc != pgm_ok) {
errno = EINVAL;
return -1;
}
// Recovery interval [s].
if (options.recovery_ivl <= 0) {
errno = EINVAL;
return -1;
}
rc = pgm_transport_set_rxw_secs (transport, options.recovery_ivl);
if (rc != pgm_ok) {
errno = EINVAL;
return -1;
}
} else {
// Sender transport.
// Set transport->can_recv = FALSE, waiting_pipe will not be read.
rc = pgm_transport_set_send_only (transport, TRUE);
zmq_assert (rc == pgm_ok);
// Set the size of the send window.
// Data rate is in [B/s] options.rate is in [kb/s].
if (options.rate <= 0) {
errno = EINVAL;
return -1;
}
rc = pgm_transport_set_txw_max_rte (transport,
options.rate * 1000 / 8);
if (rc != pgm_ok) {
errno = EINVAL;
return -1;
}
// Recovery interval [s].
if (options.recovery_ivl <= 0) {
errno = EINVAL;
return -1;
}
rc = pgm_transport_set_txw_secs (transport, options.recovery_ivl);
if (rc != pgm_ok) {
errno = EINVAL;
return -1;
}
// Set interval of background SPM packets [us].
rc = pgm_transport_set_ambient_spm (transport, 8192 * 1000);
zmq_assert (rc == pgm_ok);
// Set intervals of data flushing SPM packets [us].
guint spm_heartbeat[] = {4 * 1000, 4 * 1000, 8 * 1000, 16 * 1000,
32 * 1000, 64 * 1000, 128 * 1000, 256 * 1000, 512 * 1000,
1024 * 1000, 2048 * 1000, 4096 * 1000, 8192 * 1000};
rc = pgm_transport_set_heartbeat_spm (transport, spm_heartbeat,
G_N_ELEMENTS(spm_heartbeat));
zmq_assert (rc == pgm_ok);
}
// Enable multicast loopback.
if (options.use_multicast_loop) {
rc = pgm_transport_set_multicast_loop (transport, true);
zmq_assert (rc == pgm_ok);
}
// Bind a transport to the specified network devices.
if (!pgm_transport_bind (transport, &pgm_error)) {
// TODO: tranlate errors from glib into errnos.
return -1;
}
return 0;
}
zmq::pgm_socket_t::~pgm_socket_t ()
{
// Celanup.
if (pgm_msgv) {
delete [] pgm_msgv;
}
if (transport)
close_transport ();
}
void zmq::pgm_socket_t::close_transport ()
{
// transport has to be valid.
zmq_assert (transport);
pgm_transport_destroy (transport, TRUE);
transport = NULL;
}
// Get receiver fds. recv_fd is from transport->recv_sock
// waiting_pipe_fd is from transport->waiting_pipe [0]
void zmq::pgm_socket_t::get_receiver_fds (int *receive_fd_,
int *waiting_pipe_fd_)
{
zmq_assert (receive_fd_);
zmq_assert (waiting_pipe_fd_);
// recv_sock2 should not be used - check it.
zmq_assert (transport->recv_sock2 == -1);
// Check if transport can receive data and can not send.
zmq_assert (transport->can_recv_data);
zmq_assert (!transport->can_send_data);
// Take FDs directly from transport.
*receive_fd_ = pgm_transport_get_recv_fd (transport);
*waiting_pipe_fd_ = pgm_transport_get_pending_fd (transport);
}
// Get fds and store them into user allocated memory.
// sender_fd is from pgm_transport->send_sock.
// receive_fd_ is from transport->recv_sock.
// rdata_notify_fd_ is from transport->rdata_notify (PGM2 only).
void zmq::pgm_socket_t::get_sender_fds (int *send_fd_, int *receive_fd_,
int *rdata_notify_fd_)
{
zmq_assert (send_fd_);
zmq_assert (receive_fd_);
zmq_assert (rdata_notify_fd_);
// recv_sock2 should not be used - check it.
zmq_assert (transport->recv_sock2 == -1);
// Check if transport can send data and can not receive.
zmq_assert (transport->can_send_data);
zmq_assert (!transport->can_recv_data);
// Take FDs directly from transport.
*receive_fd_ = pgm_transport_get_recv_fd (transport);
*rdata_notify_fd_ = pgm_transport_get_repair_fd (transport);
*send_fd_ = pgm_transport_get_send_fd (transport);
}
// Send one APDU, transmit window owned memory.
size_t zmq::pgm_socket_t::send (unsigned char *data_, size_t data_len_)
{
size_t nbytes = 0;
PGMIOStatus status = pgm_send (transport, data_, data_len_, &nbytes);
if (nbytes != data_len_) {
zmq_assert (status == PGM_IO_STATUS_RATE_LIMITED);
zmq_assert (nbytes == 0);
}
// We have to write all data as one packet.
if (nbytes > 0)
zmq_assert ((ssize_t) nbytes == (ssize_t) data_len_);
return nbytes;
}
// Return max TSDU size without fragmentation from current PGM transport.
size_t zmq::pgm_socket_t::get_max_tsdu_size ()
{
return (size_t)pgm_transport_max_tsdu (transport, false);
}
// Returns how many APDUs are needed to fill reading buffer.
size_t zmq::pgm_socket_t::get_max_apdu_at_once (size_t readbuf_size_)
{
zmq_assert (readbuf_size_ > 0);
// Read max TSDU size without fragmentation.
size_t max_tsdu_size = get_max_tsdu_size ();
// Calculate number of APDUs needed to fill the reading buffer.
size_t apdu_count = (int)readbuf_size_ / max_tsdu_size;
if ((int) readbuf_size_ % max_tsdu_size)
apdu_count ++;
// Have to have at least one APDU.
zmq_assert (apdu_count);
return apdu_count;
}
// Allocate buffer for one packet from the transmit window, The memory buffer
// is owned by the transmit window and so must be returned to the window with
// content via pgm_transport_send() calls or unused with pgm_packetv_free1().
void *zmq::pgm_socket_t::get_buffer (size_t *size_)
{
// Store size.
*size_ = get_max_tsdu_size ();
// Allocate buffer.
unsigned char *apdu_buff = new unsigned char [*size_];
zmq_assert (apdu_buff);
return apdu_buff;
}
// Return an unused packet allocated from the transmit window
// via pgm_packetv_alloc().
void zmq::pgm_socket_t::free_buffer (void *data_)
{
delete [] (unsigned char*) data_;
}
// pgm_transport_recvmsgv is called to fill the pgm_msgv array up to
// pgm_msgv_len. In subsequent calls data from pgm_msgv structure are
// returned.
ssize_t zmq::pgm_socket_t::receive (void **raw_data_, const pgm_tsi_t **tsi_)
{
size_t raw_data_len = 0;
// We just sent all data from pgm_transport_recvmsgv up
// and have to return 0 that another engine in this thread is scheduled.
if (nbytes_rec == nbytes_processed && nbytes_rec > 0) {
// Reset all the counters.
nbytes_rec = 0;
nbytes_processed = 0;
pgm_msgv_processed = 0;
return 0;
}
// If we have are going first time or if we have processed all pgm_msgv_t
// structure previously read from the pgm socket.
if (nbytes_rec == nbytes_processed) {
// Check program flow.
zmq_assert (pgm_msgv_processed == 0);
zmq_assert (nbytes_processed == 0);
zmq_assert (nbytes_rec == 0);
// Receive a vector of Application Protocol Domain Unit's (APDUs)
// from the transport.
GError *pgm_error = NULL;
const PGMIOStatus status = pgm_recvmsgv (transport, pgm_msgv,
pgm_msgv_len, MSG_DONTWAIT, &nbytes_rec, &pgm_error);
// In a case when no ODATA/RDATA fired POLLIN event (SPM...)
// pgm_recvmsg returns ?.
if (status == PGM_IO_STATUS_TIMER_PENDING) {
zmq_assert (nbytes_rec == 0);
// In case if no RDATA/ODATA caused POLLIN 0 is
// returned.
nbytes_rec = 0;
return 0;
}
// Data loss.
if (status == PGM_IO_STATUS_RESET) {
pgm_peer_t* peer = (pgm_peer_t*) transport->peers_pending->data;
// Save lost data TSI.
*tsi_ = &peer->tsi;
nbytes_rec = 0;
// In case of dala loss -1 is returned.
return -1;
}
// Catch the rest of the errors.
zmq_assert (status == PGM_IO_STATUS_NORMAL);
}
zmq_assert (nbytes_rec > 0);
// Only one APDU per pgm_msgv_t structure is allowed.
zmq_assert (pgm_msgv [pgm_msgv_processed].msgv_len == 1);
struct pgm_sk_buff_t* skb =
pgm_msgv [pgm_msgv_processed].msgv_skb [0];
// Take pointers from pgm_msgv_t structure.
*raw_data_ = skb->data;
raw_data_len = skb->len;
// Save current TSI.
*tsi_ = &skb->tsi;
// Move the the next pgm_msgv_t structure.
pgm_msgv_processed++;
nbytes_processed +=raw_data_len;
return raw_data_len;
}
void zmq::pgm_socket_t::process_upstream ()
{
pgm_msgv_t dummy_msg;
size_t dummy_bytes = 0;
GError *pgm_error = NULL;
PGMIOStatus status = pgm_recvmsgv (transport, &dummy_msg,
1, MSG_DONTWAIT, &dummy_bytes, &pgm_error);
// No data should be returned.
zmq_assert (dummy_bytes == 0 && (status == PGM_IO_STATUS_TIMER_PENDING ||
status == PGM_IO_STATUS_RATE_LIMITED));
}
#endif
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