Example #1
0
static void
do_disconnect(struct api_msg_msg *msg)
{

  switch (msg->conn->type) {
#if LWIP_RAW
  case NETCONN_RAW:
    /* Do nothing as connecting is only a helper for upper lwip layers */
    break;
#endif
#if LWIP_UDP
  case NETCONN_UDPLITE:
    /* FALLTHROUGH */
  case NETCONN_UDPNOCHKSUM:
    /* FALLTHROUGH */
  case NETCONN_UDP:
    udp_disconnect(msg->conn->pcb.udp);
    break;
#endif 
  case NETCONN_TCP:
    break;
  default:
    LWIP_ASSERT( "do_newconn: msg->conn->type unknown\n", 0 );
  }
  sys_mbox_post(msg->conn->mbox, NULL);
}
Example #2
0
static void
do_send(struct api_msg_msg *msg)
{
  if (msg->conn->pcb.tcp != NULL) {
    switch (msg->conn->type) {
#if LWIP_RAW
    case NETCONN_RAW:
      raw_send(msg->conn->pcb.raw, msg->msg.p);
      break;
#endif
#if LWIP_UDP
    case NETCONN_UDPLITE:
      /* FALLTHROUGH */
    case NETCONN_UDPNOCHKSUM:
      /* FALLTHROUGH */
    case NETCONN_UDP:
      udp_send(msg->conn->pcb.udp, msg->msg.p);
      break;
#endif /* LWIP_UDP */
    case NETCONN_TCP:
      break;
    default:
      LWIP_ASSERT( "do_newconn: msg->conn->type unknown\n", 0 );
    }
  }
  sys_mbox_post(msg->conn->mbox, NULL);
}
Example #3
0
File: tcpip.c Project: wosayttn/aos 
/**
 * Sends a message to TCPIP thread to call a function. Caller thread blocks on
 * on a provided semaphore, which ist NOT automatically signalled by TCPIP thread,
 * this has to be done by the user.
 * It is recommended to use LWIP_TCPIP_CORE_LOCKING since this is the way
 * with least runtime overhead.
 *
 * @param fn function to be called from TCPIP thread
 * @param apimsg argument to API function
 * @param sem semaphore to wait on
 * @return ERR_OK if the function was called, another err_t if not
 */
err_t
tcpip_send_msg_wait_sem(tcpip_callback_fn fn, void *apimsg, sys_sem_t* sem)
{
#if LWIP_TCPIP_CORE_LOCKING
  LWIP_UNUSED_ARG(sem);
  LOCK_TCPIP_CORE();
  fn(apimsg);
  UNLOCK_TCPIP_CORE();
  return ERR_OK;
#else /* LWIP_TCPIP_CORE_LOCKING */
  TCPIP_MSG_VAR_DECLARE(msg);

  LWIP_ASSERT("semaphore not initialized", sys_sem_valid(sem));
  LWIP_ASSERT("Invalid mbox", sys_mbox_valid_val(mbox));

  TCPIP_MSG_VAR_ALLOC(msg);
  TCPIP_MSG_VAR_REF(msg).type = TCPIP_MSG_API;
  TCPIP_MSG_VAR_REF(msg).msg.api_msg.function = fn;
  TCPIP_MSG_VAR_REF(msg).msg.api_msg.msg = apimsg;
  sys_mbox_post(&mbox, &TCPIP_MSG_VAR_REF(msg));
  sys_arch_sem_wait(sem, 0);
  TCPIP_MSG_VAR_FREE(msg);
  return ERR_OK;
#endif /* LWIP_TCPIP_CORE_LOCKING */
}
Example #4
0
/**
 * Call a specific function in the thread context of
 * tcpip_thread for easy access synchronization.
 * A function called in that way may access lwIP core code
 * without fearing concurrent access.
 *
 * @param f the function to call
 * @param ctx parameter passed to f
 * @param block 1 to block until the request is posted, 0 to non-blocking mode
 * @return ERR_OK if the function was called, another err_t if not
 */
err_t
tcpip_callback_with_block(tcpip_callback_fn function, void *ctx, u8_t block)
{
  struct tcpip_msg *msg;

  if (sys_mbox_valid(&mbox)) {
    msg = (struct tcpip_msg *)memp_malloc(MEMP_TCPIP_MSG_API);
    if (msg == NULL) {
      return ERR_MEM;
    }

    msg->type = TCPIP_MSG_CALLBACK;
    msg->msg.cb.function = function;
    msg->msg.cb.ctx = ctx;
    if (block) {
      sys_mbox_post(&mbox, msg);
    } else {
      if (sys_mbox_trypost(&mbox, msg) != ERR_OK) {
        memp_free(MEMP_TCPIP_MSG_API, msg);
        return ERR_MEM;
      }
    }
    return ERR_OK;
  }
  return ERR_VAL;
}
Example #5
0
/**
 * Call a specific function in the thread context of
 * tcpip_thread for easy access synchronization.
 * A function called in that way may access lwIP core code
 * without fearing concurrent access.
 *
 * @param f the function to call
 * @param ctx parameter passed to f
 * @param block 1 to block until the request is posted, 0 to non-blocking mode
 * @return ERR_OK if the function was called, another err_t if not
 */
err_t
tcpip_callback_with_block(void (*f)(void *ctx), void *ctx, u8_t block)
{
  struct tcpip_msg *msg;

  if (mbox != SYS_MBOX_NULL) {
    msg = memp_malloc(MEMP_TCPIP_MSG_API);
    if (msg == NULL) {
      return ERR_MEM;
    }

    msg->type = TCPIP_MSG_CALLBACK;
    msg->msg.cb.f = f;
    msg->msg.cb.ctx = ctx;
    if (block) {
      sys_mbox_post(mbox, msg);
    } else {
      if (sys_mbox_trypost(mbox, msg) != ERR_OK) {
        memp_free(MEMP_TCPIP_MSG_API, msg);
        return ERR_MEM;
      }
    }
    return ERR_OK;
  }
  return ERR_VAL;
}
Example #6
0
static void
recv_udp(void *arg, struct udp_pcb *pcb, struct pbuf *p,
   struct ip_addr *addr, u16_t port)
{
  struct netbuf *buf;
  struct netconn *conn;

  conn = arg;
  
  if (conn == NULL) {
    pbuf_free(p);
    return;
  }
  if (conn->recvmbox != SYS_MBOX_NULL) {
    buf = memp_malloc(MEMP_NETBUF);
    if (buf == NULL) {
      pbuf_free(p);
      return;
    } else {
      buf->p = p;
      buf->ptr = p;
      buf->fromaddr = addr;
      buf->fromport = port;
    }

  conn->recv_avail += p->tot_len;
    /* Register event with callback */
    if (conn->callback)
        (*conn->callback)(conn, NETCONN_EVT_RCVPLUS, p->tot_len);
    sys_mbox_post(conn->recvmbox, buf);
  }
}
Example #7
0
static void
do_close(struct api_msg_msg *msg)
{
  err_t err;

  err = ERR_OK;

  if (msg->conn->pcb.tcp != NULL) {
    switch (msg->conn->type) {
#if LWIP_RAW
    case NETCONN_RAW:
      break;
#endif
#if LWIP_UDP
    case NETCONN_UDPLITE:
      /* FALLTHROUGH */
    case NETCONN_UDPNOCHKSUM:
      /* FALLTHROUGH */
    case NETCONN_UDP:
      break;
#endif /* LWIP_UDP */
#if LWIP_TCP
    case NETCONN_TCP:
      if (msg->conn->pcb.tcp->state == LISTEN) {
  err = tcp_close(msg->conn->pcb.tcp);
      }
      msg->conn->err = err;      
#endif
    default:      
      break;
    }
  }
  sys_mbox_post(msg->conn->mbox, NULL);
}
Example #8
0
static err_t
recv_tcp(void *arg, struct tcp_pcb *pcb, struct pbuf *p, err_t err)
{
  struct netconn *conn;
  u16_t len;
  
  conn = arg;

  if (conn == NULL) {
    pbuf_free(p);
    return ERR_VAL;
  }

  if (conn->recvmbox != SYS_MBOX_NULL) {
        
    conn->err = err;
    if (p != NULL) {
        len = p->tot_len;
        conn->recv_avail += len;
    }
    else
        len = 0;
    /* Register event with callback */
    if (conn->callback)
        (*conn->callback)(conn, NETCONN_EVT_RCVPLUS, len);
    sys_mbox_post(conn->recvmbox, p);
  }  
  return ERR_OK;
}
Example #9
0
static u8_t
recv_raw(void *arg, struct raw_pcb *pcb, struct pbuf *p,
    struct ip_addr *addr)
{
  struct netbuf *buf;
  struct netconn *conn;

  conn = arg;
  if (!conn) return 0;

  if (conn->recvmbox != SYS_MBOX_NULL) {
    if (!(buf = memp_malloc(MEMP_NETBUF))) {
      return 0;
    }
    pbuf_ref(p);
    buf->p = p;
    buf->ptr = p;
    buf->fromaddr = addr;
    buf->fromport = pcb->protocol;

    conn->recv_avail += p->tot_len;
    /* Register event with callback */
    if (conn->callback)
        (*conn->callback)(conn, NETCONN_EVT_RCVPLUS, p->tot_len);
    sys_mbox_post(conn->recvmbox, buf);
  }

  return 0; /* do not eat the packet */
}
Example #10
0
err_t
sys_mbox_trypost(sys_mbox_t *mbox, void *msg)
{
    sys_mbox_post(mbox, msg);

    return ERR_OK;
}
Example #11
0
/**
 * Post a callback-message to the tcpip_thread mbox.
 *
 * This is used to send "static" messages.  Not necessarily "from
 * interrupt context" - avoiding unnecessary malloc() is always good.
 *
 * To prevent confusion and to provide API symmetry there's a
 * counterpart macro tcpip_trycallbackmsg() that aliases
 * tcpip_trycallback() above.
 *
 * @param msg pointer to the message to post
 * @return sys_mbox_trypost() return code
 */
err_t
tcpip_callbackmsg(struct tcpip_callback_msg* msg)
{
  if (!sys_mbox_valid(&mbox)) {
    return ERR_VAL;
  }
  sys_mbox_post(&mbox, msg);
  return ERR_OK;
}
Example #12
0
static err_t
accept_function(void *arg, struct tcp_pcb *newpcb, err_t err)
{
  sys_mbox_t mbox;
  struct netconn *newconn;
  struct netconn *conn;
  
#if API_MSG_DEBUG
#if TCP_DEBUG
  tcp_debug_print_state(newpcb->state);
#endif /* TCP_DEBUG */
#endif /* API_MSG_DEBUG */
  conn = (struct netconn *)arg;
  mbox = conn->acceptmbox;
  newconn = memp_malloc(MEMP_NETCONN);
  if (newconn == NULL) {
    return ERR_MEM;
  }
  newconn->recvmbox = sys_mbox_new();
  if (newconn->recvmbox == SYS_MBOX_NULL) {
    memp_free(MEMP_NETCONN, newconn);
    return ERR_MEM;
  }
  newconn->mbox = sys_mbox_new();
  if (newconn->mbox == SYS_MBOX_NULL) {
    sys_mbox_free(newconn->recvmbox);
    memp_free(MEMP_NETCONN, newconn);
    return ERR_MEM;
  }
  newconn->sem = sys_sem_new(0);
  if (newconn->sem == SYS_SEM_NULL) {
    sys_mbox_free(newconn->recvmbox);
    sys_mbox_free(newconn->mbox);
    memp_free(MEMP_NETCONN, newconn);
    return ERR_MEM;
  }
  /* Allocations were OK, setup the PCB etc */
  newconn->type = NETCONN_TCP;
  newconn->pcb.tcp = newpcb;
  setup_tcp(newconn);
  newconn->acceptmbox = SYS_MBOX_NULL;
  newconn->err = err;
  /* Register event with callback */
  if (conn->callback)
  {
    (*conn->callback)(conn, NETCONN_EVT_RCVPLUS, 0);
  }
  /* We have to set the callback here even though
   * the new socket is unknown. Mark the socket as -1. */
  newconn->callback = conn->callback;
  newconn->socket = -1;
  newconn->recv_avail = 0;
  
  sys_mbox_post(mbox, newconn);
  return ERR_OK;
}
Example #13
0
void
tcpip_terminate(void)
{
  struct tcpip_msg *msg;
  msg = memp_malloc(MEMP_TCPIP_MSG);
  if (msg == NULL) {
    return;
  }
  msg->type = TCPIP_MSG_TERM;
  sys_mbox_post(mbox, msg);
}
Example #14
0
void tcpip_apimsg(struct api_msg *apimsg)
{
  struct tcpip_msg *msg;
  msg = memp_malloc(MEMP_TCPIP_MSG);
  if (msg == NULL) {
    memp_free(MEMP_API_MSG, apimsg);
    return;
  }
  msg->type = TCPIP_MSG_API;
  msg->msg.apimsg = apimsg;
  sys_mbox_post(mbox, msg);
}
Example #15
0
static void
do_recv(struct api_msg_msg *msg)
{
#if LWIP_TCP
  if (msg->conn->pcb.tcp != NULL) {
    if (msg->conn->type == NETCONN_TCP) {
      tcp_recved(msg->conn->pcb.tcp, msg->msg.len);
    }
  }
#endif  
  sys_mbox_post(msg->conn->mbox, NULL);
}
Example #16
0
static void
do_delconn(struct api_msg_msg *msg)
{
  if (msg->conn->pcb.tcp != NULL) {
    switch (msg->conn->type) {
#if LWIP_RAW
    case NETCONN_RAW:
      raw_remove(msg->conn->pcb.raw);
      break;
#endif
#if LWIP_UDP
    case NETCONN_UDPLITE:
      /* FALLTHROUGH */
    case NETCONN_UDPNOCHKSUM:
      /* FALLTHROUGH */
    case NETCONN_UDP:
      msg->conn->pcb.udp->recv_arg = NULL;
      udp_remove(msg->conn->pcb.udp);
      break;
#endif /* LWIP_UDP */
#if LWIP_TCP      
    case NETCONN_TCP:
      if (msg->conn->pcb.tcp->state == LISTEN) {
  tcp_arg(msg->conn->pcb.tcp, NULL);
  tcp_accept(msg->conn->pcb.tcp, NULL);  
  tcp_close(msg->conn->pcb.tcp);
      } else {
  tcp_arg(msg->conn->pcb.tcp, NULL);
  tcp_sent(msg->conn->pcb.tcp, NULL);
  tcp_recv(msg->conn->pcb.tcp, NULL);  
  tcp_poll(msg->conn->pcb.tcp, NULL, 0);
  tcp_err(msg->conn->pcb.tcp, NULL);
  if (tcp_close(msg->conn->pcb.tcp) != ERR_OK) {
    tcp_abort(msg->conn->pcb.tcp);
  }
      }
#endif
    default:  
    break;
    }
  }
  /* Trigger select() in socket layer */
  if (msg->conn->callback)
  {
      (*msg->conn->callback)(msg->conn, NETCONN_EVT_RCVPLUS, 0);
      (*msg->conn->callback)(msg->conn, NETCONN_EVT_SENDPLUS, 0);
  }
  
  if (msg->conn->mbox != SYS_MBOX_NULL) {
    sys_mbox_post(msg->conn->mbox, NULL);
  }
}
Example #17
0
/**
 * Call the lower part of a netconn_* function
 * This function is then running in the thread context
 * of tcpip_thread and has exclusive access to lwIP core code.
 *
 * @param apimsg a struct containing the function to call and its parameters
 * @return ERR_OK if the function was called, another err_t if not
 */
err_t
tcpip_apimsg(struct api_msg *apimsg)
{
  struct tcpip_msg msg;
  
  if (mbox != SYS_MBOX_NULL) {
    msg.type = TCPIP_MSG_API;
    msg.msg.apimsg = apimsg;
    sys_mbox_post(mbox, &msg);
    sys_arch_sem_wait(apimsg->msg.conn->op_completed, 0);
    return ERR_OK;
  }
  return ERR_VAL;
}
Example #18
0
/*-----------------------------------------------------------------------------------*/
static void
do_bind(struct api_msg_msg *msg)
{
  if (msg->conn->pcb.tcp == NULL) {
    switch (msg->conn->type) {
#if LWIP_UDP
    case NETCONN_UDPLITE:
      msg->conn->pcb.udp = udp_new();
      udp_setflags(msg->conn->pcb.udp, UDP_FLAGS_UDPLITE);
      udp_recv(msg->conn->pcb.udp, recv_udp, msg->conn);
      break;
    case NETCONN_UDPNOCHKSUM:
      msg->conn->pcb.udp = udp_new();
      udp_setflags(msg->conn->pcb.udp, UDP_FLAGS_NOCHKSUM);
      udp_recv(msg->conn->pcb.udp, recv_udp, msg->conn);
      break;
    case NETCONN_UDP:
      msg->conn->pcb.udp = udp_new();
      udp_recv(msg->conn->pcb.udp, recv_udp, msg->conn);
      break;
#endif /* LWIP_UDP */
#if LWIP_TCP      
    case NETCONN_TCP:
      msg->conn->pcb.tcp = tcp_new();
      setup_tcp(msg->conn);
#endif /* LWIP_TCP */
    default:  
    break;
    }
  }
  switch (msg->conn->type) {
#if LWIP_UDP
  case NETCONN_UDPLITE:
    /* FALLTHROUGH */
  case NETCONN_UDPNOCHKSUM:
    /* FALLTHROUGH */
  case NETCONN_UDP:
    msg->conn->err = udp_bind(msg->conn->pcb.udp, msg->msg.bc.ipaddr, msg->msg.bc.port);
    break;
#endif /* LWIP_UDP */
#if LWIP_TCP
  case NETCONN_TCP:
    msg->conn->err = tcp_bind(msg->conn->pcb.tcp,
            msg->msg.bc.ipaddr, msg->msg.bc.port);
#endif /* LWIP_TCP */
  default:
    break;
  }
  sys_mbox_post(msg->conn->mbox, NULL);
}
Example #19
0
static void
do_write(struct api_msg_msg *msg)
{
#if LWIP_TCP  
  err_t err;
#endif  
  if (msg->conn->pcb.tcp != NULL) {
    switch (msg->conn->type) {
#if LWIP_RAW
    case NETCONN_RAW:
      msg->conn->err = ERR_VAL;
      break;
#endif
#if LWIP_UDP 
    case NETCONN_UDPLITE:
      /* FALLTHROUGH */
    case NETCONN_UDPNOCHKSUM:
      /* FALLTHROUGH */
    case NETCONN_UDP:
      msg->conn->err = ERR_VAL;
      break;
#endif /* LWIP_UDP */
#if LWIP_TCP 
    case NETCONN_TCP:      
      err = tcp_write(msg->conn->pcb.tcp, msg->msg.w.dataptr,
                      msg->msg.w.len, msg->msg.w.copy);
      /* This is the Nagle algorithm: inhibit the sending of new TCP
   segments when new outgoing data arrives from the user if any
   previously transmitted data on the connection remains
   unacknowledged. */
      if(err == ERR_OK && (msg->conn->pcb.tcp->unacked == NULL ||
        (msg->conn->pcb.tcp->flags & TF_NODELAY) || 
        (msg->conn->pcb.tcp->snd_queuelen) > 1)) {
          tcp_output(msg->conn->pcb.tcp);
      }
      msg->conn->err = err;
      if (msg->conn->callback)
          if (err == ERR_OK)
          {
              if (tcp_sndbuf(msg->conn->pcb.tcp) <= TCP_SNDLOWAT)
                  (*msg->conn->callback)(msg->conn, NETCONN_EVT_SENDMINUS, msg->msg.w.len);
          }
#endif
    default:
      break;
    }
  }
  sys_mbox_post(msg->conn->mbox, NULL);
}
Example #20
0
/* prio:10 */
static void task2(void *pdata)
{
	
	char *m1 = "task2 message1";
	char *m2 = "task2 message2";
	char *m3 = "task2 message3";
	char *m4 = "task2 message4";
    while(1)
    {
    		sys_mutex_lock(&sys_mutex);
		dprintf("task2,%s\r\n",pdata);
#if 0
		dprintf("task2 post m1\r\n");
		OSQPost(mbox, m1);
		dprintf("task2 post m2\r\n");
		OSQPost(mbox, m2);
		dprintf("task2 post m3\r\n");
		OSQPost(mbox, m3);
		dprintf("task2 post m4\r\n");
		OSQPost(mbox, m4);
#endif
		dprintf("task2 post message1\r\n");
		sys_mbox_post(&sys_mbox, m1);
		dprintf("task2 post message2\r\n");
		sys_mbox_post(&sys_mbox, m2);
		dprintf("task2 post message3\r\n");
		sys_mbox_post(&sys_mbox, m3);
		dprintf("task2 post message4\r\n");
		sys_mbox_post(&sys_mbox, m4);
		sys_mutex_unlock(&sys_mutex);
	    //OSTaskSuspend(OS_PRIO_SELF);
		//sys_sem_wait(&sys_sem);
		
	    //OSTaskResume(9);
    }
}
Example #21
0
err_t
tcpip_callback(void (*f)(void *ctx), void *ctx)
{
  struct tcpip_msg *msg;
  
  msg = memp_malloc(MEMP_TCPIP_MSG);
  if (msg == NULL) {
    return ERR_MEM;  
  }
  
  msg->type = TCPIP_MSG_CALLBACK;
  msg->msg.cb.f = f;
  msg->msg.cb.ctx = ctx;
  sys_mbox_post(tcp_mbox, msg);
  return ERR_OK;
}
Example #22
0
err_t
tcpip_input(struct pbuf *p, struct netif *inp)
{
  struct tcpip_msg *msg;
  
  msg = memp_malloc(MEMP_TCPIP_MSG);
  if (msg == NULL) {
    pbuf_free(p);    
    return ERR_MEM;  
  }
  
  msg->type = TCPIP_MSG_INPUT;
  msg->msg.inp.p = p;
  msg->msg.inp.netif = inp;
  sys_mbox_post(tcp_mbox, msg);
  return ERR_OK;
}
Example #23
0
/**
 * Call the lower part of a netconn_* function
 * This function is then running in the thread context
 * of tcpip_thread and has exclusive access to lwIP core code.
 *
 * @param apimsg a struct containing the function to call and its parameters
 * @return ERR_OK if the function was called, another err_t if not
 */
err_t
tcpip_apimsg(struct api_msg *apimsg)
{
  struct tcpip_msg msg;
  
  if (mbox != SYS_MBOX_NULL) {
    msg.type = TCPIP_MSG_API;
    msg.msg.apimsg = apimsg;
    //acoral_prints("\r\ntcpip_apimsg_post\r\n");
    sys_mbox_post(mbox, &msg);
    //lwip_printf("\r\n %s \r\n====\r\n", apimsg->msg.msg.w.dataptr);
	//acoral_prints("\r\ntcpip_apimsg_op_completed\r\n");    
    sys_arch_sem_wait(apimsg->msg.conn->op_completed, 0);
    return ERR_OK;
  }
  return ERR_VAL;
}
Example #24
0
File: tcpip.c Project: wosayttn/aos 
/**
 * call sys_untimeout in tcpip_thread
 *
 * @param h function to be called on timeout
 * @param arg argument to pass to timeout function h
 * @return ERR_MEM on memory error, ERR_OK otherwise
 */
err_t
tcpip_untimeout(sys_timeout_handler h, void *arg)
{
  struct tcpip_msg *msg;

  LWIP_ASSERT("Invalid mbox", sys_mbox_valid_val(mbox));

  msg = (struct tcpip_msg *)memp_malloc(MEMP_TCPIP_MSG_API);
  if (msg == NULL) {
    return ERR_MEM;
  }

  msg->type = TCPIP_MSG_UNTIMEOUT;
  msg->msg.tmo.h = h;
  msg->msg.tmo.arg = arg;
  sys_mbox_post(&mbox, msg);
  return ERR_OK;
}
Example #25
0
static err_t
do_connected(void *arg, struct tcp_pcb *pcb, err_t err)
{
  struct netconn *conn;

  conn = arg;

  if (conn == NULL) {
    return ERR_VAL;
  }
  
  conn->err = err;
  if (conn->type == NETCONN_TCP && err == ERR_OK) {
    setup_tcp(conn);
  }    
  sys_mbox_post(conn->mbox, NULL);
  return ERR_OK;
}
Example #26
0
/**
 * Call the lower part of a netconn_* function
 * This function is then running in the thread context
 * of tcpip_thread and has exclusive access to lwIP core code.
 *
 * @param apimsg a struct containing the function to call and its parameters
 * @return ERR_OK if the function was called, another err_t if not
 */
err_t
tcpip_apimsg(struct api_msg *apimsg)
{
  struct tcpip_msg msg;
#ifdef LWIP_DEBUG
  /* catch functions that don't set err */
  apimsg->msg.err = ERR_VAL;
#endif
  
  if (sys_mbox_valid(&mbox)) {
    msg.type = TCPIP_MSG_API;
    msg.msg.apimsg = apimsg;
    sys_mbox_post(&mbox, &msg);
    sys_arch_sem_wait(&apimsg->msg.conn->op_completed, 0);
    return apimsg->msg.err;
  }
  return ERR_VAL;
}
Example #27
0
static void
do_disconnect(struct api_msg_msg *msg)
{

  switch (msg->conn->type) {
#if LWIP_UDP
  case NETCONN_UDPLITE:
    /* FALLTHROUGH */
  case NETCONN_UDPNOCHKSUM:
    /* FALLTHROUGH */
  case NETCONN_UDP:
    udp_disconnect(msg->conn->pcb.udp);
    break;
#endif 
  case NETCONN_TCP:
    break;
  }
  sys_mbox_post(msg->conn->mbox, NULL);
}
Example #28
0
/**
 * call sys_untimeout in tcpip_thread
 *
 * @param msec time in miliseconds for timeout
 * @param h function to be called on timeout
 * @param arg argument to pass to timeout function h
 * @return ERR_MEM on memory error, ERR_OK otherwise
 */
err_t
tcpip_untimeout(sys_timeout_handler h, void *arg)
{
  struct tcpip_msg *msg;

  if (mbox != SYS_MBOX_NULL) {
    msg = memp_malloc(MEMP_TCPIP_MSG_API);
    if (msg == NULL) {
      return ERR_MEM;
    }

    msg->type = TCPIP_MSG_UNTIMEOUT;
    msg->msg.tmo.h = h;
    msg->msg.tmo.arg = arg;
    sys_mbox_post(mbox, msg);
    return ERR_OK;
  }
  return ERR_VAL;
}
Example #29
0
static void
do_listen(struct api_msg_msg *msg)
{
  if (msg->conn->pcb.tcp != NULL) {
    switch (msg->conn->type) {
#if LWIP_RAW
    case NETCONN_RAW:
      LWIP_DEBUGF(API_MSG_DEBUG, ("api_msg: listen RAW: cannot listen for RAW.\n"));
      break;
#endif
#if LWIP_UDP
    case NETCONN_UDPLITE:
      /* FALLTHROUGH */
    case NETCONN_UDPNOCHKSUM:
      /* FALLTHROUGH */
    case NETCONN_UDP:
      LWIP_DEBUGF(API_MSG_DEBUG, ("api_msg: listen UDP: cannot listen for UDP.\n"));
      break;
#endif /* LWIP_UDP */
#if LWIP_TCP      
    case NETCONN_TCP:
      msg->conn->pcb.tcp = tcp_listen(msg->conn->pcb.tcp);
      if (msg->conn->pcb.tcp == NULL) {
  msg->conn->err = ERR_MEM;
      } else {
  if (msg->conn->acceptmbox == SYS_MBOX_NULL) {
    msg->conn->acceptmbox = sys_mbox_new();
    if (msg->conn->acceptmbox == SYS_MBOX_NULL) {
      msg->conn->err = ERR_MEM;
      break;
    }
  }
  tcp_arg(msg->conn->pcb.tcp, msg->conn);
  tcp_accept(msg->conn->pcb.tcp, accept_function);
      }
#endif
    default:
      break;
    }
  }
  sys_mbox_post(msg->conn->mbox, NULL);
}
Example #30
0
/**
 * call sys_timeout in tcpip_thread
 *
 * @param msec time in milliseconds for timeout
 * @param h function to be called on timeout
 * @param arg argument to pass to timeout function h
 * @return ERR_MEM on memory error, ERR_OK otherwise
 */
err_t
tcpip_timeout(u32_t msecs, sys_timeout_handler h, void *arg)
{
  struct tcpip_msg *msg;

  if (sys_mbox_valid(&mbox)) {
    msg = (struct tcpip_msg *)memp_malloc(MEMP_TCPIP_MSG_API);
    if (msg == NULL) {
      return ERR_MEM;
    }

    msg->type = TCPIP_MSG_TIMEOUT;
    msg->msg.tmo.msecs = msecs;
    msg->msg.tmo.h = h;
    msg->msg.tmo.arg = arg;
    sys_mbox_post(&mbox, msg);
    return ERR_OK;
  }
  return ERR_VAL;
}