void nn_req_init (struct nn_req *self,
const struct nn_sockbase_vfptr *vfptr, void *hint)
{
nn_req_handle hndl;
nn_xreq_init (&self->xreq, vfptr, hint);
nn_fsm_init_root (&self->fsm, nn_req_handler, nn_req_shutdown,
nn_sockbase_getctx (&self->xreq.sockbase));
self->state = NN_REQ_STATE_IDLE;
/* Start assigning request IDs beginning with a random number. This way
there should be no key clashes even if the executable is re-started. */
nn_random_generate (&self->lastid, sizeof (self->lastid));
self->task.sent_to = NULL;
nn_msg_init (&self->task.request, 0);
nn_msg_init (&self->task.reply, 0);
nn_timer_init (&self->task.timer, NN_REQ_SRC_RESEND_TIMER, &self->fsm);
self->resend_ivl = NN_REQ_DEFAULT_RESEND_IVL;
/* For now, handle is empty. */
memset (&hndl, 0, sizeof (hndl));
nn_task_init (&self->task, self->lastid, hndl);
/* Start the state machine. */
nn_fsm_start (&self->fsm);
}
void nn_stream_init (struct nn_stream *self, struct nn_epbase *epbase,
struct nn_usock *usock)
{
int rc;
int protocol;
size_t sz;
struct nn_iobuf iobuf;
/* Redirect the underlying socket's events to this state machine. */
self->usock = usock;
self->sink = &nn_stream_state_start;
self->original_sink = nn_usock_setsink (usock, &self->sink);
/* Initialise the pipe to communicate with the user. */
rc = nn_pipebase_init (&self->pipebase, &nn_stream_pipebase_vfptr, epbase);
nn_assert (rc == 0);
nn_msg_init (&self->inmsg, 0);
nn_msg_init (&self->outmsg, 0);
/* Start the header timeout timer. */
nn_timer_init (&self->hdr_timeout, &self->sink, usock->cp);
nn_timer_start (&self->hdr_timeout, 1000);
/* Send the protocol header. */
sz = sizeof (protocol);
nn_epbase_getopt (epbase, NN_SOL_SOCKET, NN_PROTOCOL, &protocol, &sz);
errnum_assert (rc == 0, -rc);
nn_assert (sz == sizeof (protocol));
memcpy (self->protohdr, "\0\0SP\0\0\0\0", 8);
nn_puts (self->protohdr + 4, (uint16_t) protocol);
iobuf.iov_base = self->protohdr;
iobuf.iov_len = 8;
nn_usock_send (usock, &iobuf, 1);
}
void nn_backoff_init (struct nn_backoff *self, int src, int minivl, int maxivl,
struct nn_fsm *owner)
{
nn_timer_init (&self->timer, src, owner);
self->minivl = minivl;
self->maxivl = maxivl;
self->n = 1;
}
void nn_streamhdr_init (struct nn_streamhdr *self, int src,
struct nn_fsm *owner)
{
nn_fsm_init (&self->fsm, nn_streamhdr_handler, src, self, owner);
self->state = NN_STREAMHDR_STATE_IDLE;
nn_timer_init (&self->timer, NN_STREAMHDR_SRC_TIMER, &self->fsm);
nn_fsm_event_init (&self->done);
self->usock = NULL;
self->usock_owner.src = -1;
self->usock_owner.fsm = NULL;
self->pipebase = NULL;
}
int nn_cstream_init (struct nn_cstream *self, const char *addr, void *hint,
int (*initsockfn) (struct nn_usock *sock, int sndbuf, int rcvbuf,
struct nn_cp *cp), int (*resolvefn) (const char *addr,
struct sockaddr_storage *ss, socklen_t *sslen))
{
int rc;
int sndbuf;
int rcvbuf;
size_t sz;
self->initsockfn = initsockfn;
self->resolvefn = resolvefn;
/* TODO: Check the syntax of the address and return error if it is
not a valid address string. Don't do any blocking DNS operations
though! */
/* Initialise the base class. */
nn_epbase_init (&self->epbase, &nn_cstream_epbase_vfptr, addr, hint);
/* Get the current values of NN_SNDBUF and NN_RCVBUF options. */
sz = sizeof (sndbuf);
nn_epbase_getopt (&self->epbase, NN_SOL_SOCKET, NN_SNDBUF, &sndbuf, &sz);
nn_assert (sz == sizeof (sndbuf));
sz = sizeof (rcvbuf);
nn_epbase_getopt (&self->epbase, NN_SOL_SOCKET, NN_RCVBUF, &rcvbuf, &sz);
nn_assert (sz == sizeof (rcvbuf));
/* Open a socket. */
rc = self->initsockfn (&self->usock, sndbuf, rcvbuf,
nn_epbase_getcp (&self->epbase));
errnum_assert (rc == 0, -rc);
nn_usock_setsink (&self->usock, &self->sink);
/* Initialise the retry timer. */
self->retry_ivl = -1;
nn_timer_init (&self->retry_timer, &self->sink,
nn_epbase_getcp (&self->epbase));
/* Pretend we were waiting for the re-connect timer and that the timer
have expired. */
self->sink = &nn_cstream_state_waiting;
nn_cstream_waiting_timeout (&self->sink, &self->retry_timer);
return 0;
}
static void nn_surveyor_init (struct nn_surveyor *self,
const struct nn_sockbase_vfptr *vfptr, void *hint)
{
nn_xsurveyor_init (&self->xsurveyor, vfptr, hint);
nn_fsm_init_root (&self->fsm, nn_surveyor_handler,
nn_sockbase_getctx (&self->xsurveyor.sockbase));
self->state = NN_SURVEYOR_STATE_IDLE;
/* Start assigning survey IDs beginning with a random number. This way
there should be no key clashes even if the executable is re-started. */
nn_random_generate (&self->surveyid, sizeof (self->surveyid));
nn_timer_init (&self->timer, NN_SURVEYOR_SRC_DEADLINE_TIMER, &self->fsm);
nn_msg_init (&self->tosend, 0);
self->deadline = NN_SURVEYOR_DEFAULT_DEADLINE;
/* Start the state machine. */
nn_fsm_start (&self->fsm);
}
static int nn_req_init (struct nn_req *self,
const struct nn_sockbase_vfptr *vfptr)
{
int rc;
rc = nn_xreq_init (&self->xreq, vfptr);
if (rc < 0)
return rc;
self->sink = &nn_req_sink;
/* Start assigning request IDs beginning with a random number. This way
there should be no key clashes even if the executable is re-started. */
nn_random_generate (&self->reqid, sizeof (self->reqid));
self->state = NN_REQ_STATE_IDLE;
self->resend_ivl = NN_REQ_DEFAULT_RESEND_IVL;
nn_timer_init (&self->resend_timer, &self->sink,
nn_sockbase_getcp (&self->xreq.sockbase));
return 0;
}
static int nn_surveyor_init (struct nn_surveyor *self,
const struct nn_sockbase_vfptr *vfptr)
{
int rc;
rc = nn_xsurveyor_init (&self->xsurveyor, vfptr);
if (rc < 0)
return rc;
self->sink = &nn_surveyor_sink;
self->flags = 0;
/* Start assigning survey IDs beginning with a random number. This way
there should be no key clashes even if the executable is re-started. */
nn_random_generate (&self->surveyid, sizeof (self->surveyid));
self->deadline = NN_SURVEYOR_DEFAULT_DEADLINE;
nn_timer_init (&self->deadline_timer, &self->sink,
nn_sockbase_getcp (&self->xsurveyor.sockbase));
return 0;
}
static void nn_global_init (void)
{
int i;
char *envvar;
int rc;
char *addr;
#if defined NN_HAVE_WINDOWS
WSADATA data;
#endif
/* Check whether the library was already initialised. If so, do nothing. */
if (self.socks)
return;
/* On Windows, initialise the socket library. */
#if defined NN_HAVE_WINDOWS
rc = WSAStartup (MAKEWORD (2, 2), &data);
nn_assert (rc == 0);
nn_assert (LOBYTE (data.wVersion) == 2 &&
HIBYTE (data.wVersion) == 2);
#endif
/* Initialise the memory allocation subsystem. */
nn_alloc_init ();
/* Seed the pseudo-random number generator. */
nn_random_seed ();
/* Allocate the global table of SP sockets. */
self.socks = nn_alloc ((sizeof (struct nn_sock*) * NN_MAX_SOCKETS) +
(sizeof (uint16_t) * NN_MAX_SOCKETS), "socket table");
alloc_assert (self.socks);
for (i = 0; i != NN_MAX_SOCKETS; ++i)
self.socks [i] = NULL;
self.nsocks = 0;
self.flags = 0;
/* Print connection and accepting errors to the stderr */
envvar = getenv("NN_PRINT_ERRORS");
/* any non-empty string is true */
self.print_errors = envvar && *envvar;
/* Print socket statistics to stderr */
envvar = getenv("NN_PRINT_STATISTICS");
self.print_statistics = envvar && *envvar;
/* Allocate the stack of unused file descriptors. */
self.unused = (uint16_t*) (self.socks + NN_MAX_SOCKETS);
alloc_assert (self.unused);
for (i = 0; i != NN_MAX_SOCKETS; ++i)
self.unused [i] = NN_MAX_SOCKETS - i - 1;
/* Initialise other parts of the global state. */
nn_list_init (&self.transports);
nn_list_init (&self.socktypes);
/* Plug in individual transports. */
nn_global_add_transport (nn_inproc);
nn_global_add_transport (nn_ipc);
nn_global_add_transport (nn_tcp);
nn_global_add_transport (nn_ws);
nn_global_add_transport (nn_tcpmux);
/* Plug in individual socktypes. */
nn_global_add_socktype (nn_pair_socktype);
nn_global_add_socktype (nn_xpair_socktype);
nn_global_add_socktype (nn_pub_socktype);
nn_global_add_socktype (nn_sub_socktype);
nn_global_add_socktype (nn_xpub_socktype);
nn_global_add_socktype (nn_xsub_socktype);
nn_global_add_socktype (nn_rep_socktype);
nn_global_add_socktype (nn_req_socktype);
nn_global_add_socktype (nn_xrep_socktype);
nn_global_add_socktype (nn_xreq_socktype);
nn_global_add_socktype (nn_push_socktype);
nn_global_add_socktype (nn_xpush_socktype);
nn_global_add_socktype (nn_pull_socktype);
nn_global_add_socktype (nn_xpull_socktype);
nn_global_add_socktype (nn_respondent_socktype);
nn_global_add_socktype (nn_surveyor_socktype);
nn_global_add_socktype (nn_xrespondent_socktype);
nn_global_add_socktype (nn_xsurveyor_socktype);
nn_global_add_socktype (nn_bus_socktype);
nn_global_add_socktype (nn_xbus_socktype);
/* Start the worker threads. */
nn_pool_init (&self.pool);
/* Start FSM */
nn_fsm_init_root (&self.fsm, nn_global_handler, nn_global_shutdown,
&self.ctx);
self.state = NN_GLOBAL_STATE_IDLE;
nn_ctx_init (&self.ctx, nn_global_getpool (), NULL);
nn_timer_init (&self.stat_timer, NN_GLOBAL_SRC_STAT_TIMER, &self.fsm);
nn_fsm_start (&self.fsm);
/* Initializing special sockets. */
addr = getenv ("NN_STATISTICS_SOCKET");
if (addr) {
self.statistics_socket = nn_global_create_socket (AF_SP, NN_PUB);
errno_assert (self.statistics_socket >= 0);
rc = nn_global_create_ep (self.statistics_socket, addr, 0);
errno_assert (rc >= 0);
} else {
self.statistics_socket = -1;
}
addr = getenv ("NN_APPLICATION_NAME");
if (addr) {
strncpy (self.appname, addr, 63);
self.appname[63] = '\0';
} else {
/* No cross-platform way to find out application binary.
Also, MSVC suggests using _getpid() instead of getpid(),
however, it's not clear whether the former is supported
by older versions of Windows/MSVC. */
#if defined _MSC_VER
#pragma warning (push)
#pragma warning (disable:4996)
#endif
sprintf (self.appname, "nanomsg.%d", getpid());
#if defined _MSC_VER
#pragma warning (pop)
#endif
}
addr = getenv ("NN_HOSTNAME");
if (addr) {
strncpy (self.hostname, addr, 63);
self.hostname[63] = '\0';
} else {
rc = gethostname (self.hostname, 63);
errno_assert (rc == 0);
self.hostname[63] = '\0';
}
}
