예제 #1
0
파일: sendto.c 프로젝트: KimMui/i2sTest
static uint16_t sendto_interrupt(struct net_driver_s *dev, void *conn,
                                 void *pvpriv, uint16_t flags)
{
  FAR struct sendto_s *pstate = (FAR struct sendto_s *)pvpriv;

  nllvdbg("flags: %04x\n", flags);
  if (pstate)
    {
      /* Check if the outgoing packet is available.  It may have been claimed
       * by a sendto interrupt serving a different thread -OR- if the output
       * buffer currently contains unprocessed incoming data.  In these cases
       * we will just have to wait for the next polling cycle.
       */

      if (dev->d_sndlen > 0 || (flags & UDP_NEWDATA) != 0)
        {
           /* Another thread has beat us sending data or the buffer is busy,
            * Check for a timeout.  If not timed out, wait for the next
            * polling cycle and check again.
            */

#ifdef CONFIG_NET_SENDTO_TIMEOUT
          if (send_timeout(pstate))
            {
              /* Yes.. report the timeout */

              nlldbg("SEND timeout\n");
              pstate->st_sndlen = -ETIMEDOUT;
            }
          else
#endif /* CONFIG_NET_SENDTO_TIMEOUT */
            {
               /* No timeout.  Just wait for the next polling cycle */

               return flags;
            }
        }

      /* It looks like we are good to send the data */

      else
        {
          /* Copy the user data into d_snddata and send it */

          devif_send(dev, pstate->st_buffer, pstate->st_buflen);
          pstate->st_sndlen = pstate->st_buflen;
        }

      /* Don't allow any further call backs. */

      pstate->st_cb->flags   = 0;
      pstate->st_cb->priv    = NULL;
      pstate->st_cb->event   = NULL;

      /* Wake up the waiting thread */

      sem_post(&pstate->st_sem);
    }

  return flags;
}
예제 #2
0
static uint16_t tcpsend_interrupt(FAR struct net_driver_s *dev,
                                  FAR void *pvconn,
                                  FAR void *pvpriv, uint16_t flags)
{
  FAR struct tcp_conn_s *conn = (FAR struct tcp_conn_s *)pvconn;
  FAR struct send_s *pstate = (FAR struct send_s *)pvpriv;

#ifdef CONFIG_NETDEV_MULTINIC
  /* The TCP socket is connected and, hence, should be bound to a device.
   * Make sure that the polling device is the one that we are bound to.
   */

  DEBUGASSERT(conn->dev != NULL);
  if (dev != conn->dev)
    {
      return flags;
    }
#endif

  nllvdbg("flags: %04x acked: %d sent: %d\n",
          flags, pstate->snd_acked, pstate->snd_sent);

  /* If this packet contains an acknowledgement, then update the count of
   * acknowledged bytes.
   */

  if ((flags & TCP_ACKDATA) != 0)
    {
      FAR struct tcp_hdr_s *tcp;

      /* Update the timeout */

#ifdef CONFIG_NET_SOCKOPTS
      pstate->snd_time = clock_systimer();
#endif

      /* Get the offset address of the TCP header */

#ifdef CONFIG_NET_IPv4
#ifdef CONFIG_NET_IPv6
      if (conn->domain == PF_INET)
#endif
        {
          DEBUGASSERT(IFF_IS_IPv4(dev->d_flags));
          tcp = TCPIPv4BUF;
        }
#endif /* CONFIG_NET_IPv4 */

#ifdef CONFIG_NET_IPv6
#ifdef CONFIG_NET_IPv4
      else
#endif
        {
          DEBUGASSERT(IFF_IS_IPv6(dev->d_flags));
          tcp = TCPIPv6BUF;
        }
#endif /* CONFIG_NET_IPv6 */

      /* The current acknowledgement number number is the (relative) offset
       * of the of the next byte needed by the receiver.  The snd_isn is the
       * offset of the first byte to send to the receiver.  The difference
       * is the number of bytes to be acknowledged.
       */

      pstate->snd_acked = tcp_getsequence(tcp->ackno) - pstate->snd_isn;
      nllvdbg("ACK: acked=%d sent=%d buflen=%d\n",
              pstate->snd_acked, pstate->snd_sent, pstate->snd_buflen);

      /* Have all of the bytes in the buffer been sent and acknowledged? */

      if (pstate->snd_acked >= pstate->snd_buflen)
        {
          /* Yes.  Then pstate->snd_buflen should hold the number of bytes
           * actually sent.
           */

          goto end_wait;
        }

      /* No.. fall through to send more data if necessary */
    }

  /* Check if we are being asked to retransmit data */

  else if ((flags & TCP_REXMIT) != 0)
    {
      /* Yes.. in this case, reset the number of bytes that have been sent
       * to the number of bytes that have been ACKed.
       */

      pstate->snd_sent = pstate->snd_acked;

#if defined(CONFIG_NET_TCP_SPLIT)
      /* Reset the even/odd indicator to even since we need to
       * retransmit.
       */

      pstate->snd_odd = false;
#endif

      /* Fall through to re-send data from the last that was ACKed */
    }

  /* Check for a loss of connection */

  else if ((flags & TCP_DISCONN_EVENTS) != 0)
    {
      /* Report not connected */

      nllvdbg("Lost connection\n");

      net_lostconnection(pstate->snd_sock, flags);
      pstate->snd_sent = -ENOTCONN;
      goto end_wait;
    }

  /* Check if the outgoing packet is available (it may have been claimed
   * by a sendto interrupt serving a different thread).
   */

#if 0 /* We can't really support multiple senders on the same TCP socket */
  else if (dev->d_sndlen > 0)
    {
      /* Another thread has beat us sending data, wait for the next poll */

      return flags;
    }
#endif

  /* We get here if (1) not all of the data has been ACKed, (2) we have been
   * asked to retransmit data, (3) the connection is still healthy, and (4)
   * the outgoing packet is available for our use.  In this case, we are
   * now free to send more data to receiver -- UNLESS the buffer contains
   * unprocessed incoming data.  In that event, we will have to wait for the
   * next polling cycle.
   */

  if ((flags & TCP_NEWDATA) == 0 && pstate->snd_sent < pstate->snd_buflen)
    {
      uint32_t seqno;

      /* Get the amount of data that we can send in the next packet */

      uint32_t sndlen = pstate->snd_buflen - pstate->snd_sent;

#if defined(CONFIG_NET_TCP_SPLIT)

      /* RFC 1122 states that a host may delay ACKing for up to 500ms but
       * must respond to every second  segment).  This logic here will trick
       * the RFC 1122 recipient into responding sooner.  This logic will be
       * activated if:
       *
       *   1. An even number of packets has been send (where zero is an even
       *      number),
       *   2. There is more data be sent (more than or equal to
       *      CONFIG_NET_TCP_SPLIT_SIZE), but
       *   3. Not enough data for two packets.
       *
       * Then we will split the remaining, single packet into two partial
       * packets.  This will stimulate the RFC 1122 peer to ACK sooner.
       *
       * Don't try to split very small packets (less than CONFIG_NET_TCP_SPLIT_SIZE).
       * Only the first even packet and the last odd packets could have
       * sndlen less than CONFIG_NET_TCP_SPLIT_SIZE.  The value of sndlen on
       * the last even packet is guaranteed to be at least MSS/2 by the
       * logic below.
       */

      if (sndlen >= CONFIG_NET_TCP_SPLIT_SIZE)
        {
          /* sndlen is the number of bytes remaining to be sent.
           * conn->mss will provide the number of bytes that can sent
           * in one packet.  The difference, then, is the number of bytes
           * that would be sent in the next packet after this one.
           */

          int32_t next_sndlen = sndlen - conn->mss;

          /*  Is this the even packet in the packet pair transaction? */

          if (!pstate->snd_odd)
            {
              /* next_sndlen <= 0 means that the entire remaining data
               * could fit into this single packet.  This is condition
               * in which we must do the split.
               */

              if (next_sndlen <= 0)
                {
                  /* Split so that there will be an odd packet.  Here
                   * we know that 0 < sndlen <= MSS
                   */

                  sndlen = (sndlen / 2) + 1;
                }
            }

          /* No... this is the odd packet in the packet pair transaction */

          else
            {
              /* Will there be another (even) packet afer this one?
               * (next_sndlen > 0)  Will the split condition occur on that
               * next, even packet? ((next_sndlen - conn->mss) < 0) If
               * so, then perform the split now to avoid the case where the
               * byte count is less than CONFIG_NET_TCP_SPLIT_SIZE on the
               * next pair.
               */

              if (next_sndlen > 0 && (next_sndlen - conn->mss) < 0)
                {
                  /* Here, we know that sndlen must be MSS < sndlen <= 2*MSS
                   * and so (sndlen / 2) is <= MSS.
                   */

                  sndlen /= 2;
                }
            }
        }

      /* Toggle the even/odd indicator */

      pstate->snd_odd ^= true;

#endif /* CONFIG_NET_TCP_SPLIT */

      if (sndlen > conn->mss)
        {
          sndlen = conn->mss;
        }

      /* Check if we have "space" in the window */

      if ((pstate->snd_sent - pstate->snd_acked + sndlen) < conn->winsize)
        {
          /* Set the sequence number for this packet.  NOTE:  The network updates
           * sndseq on receipt of ACK *before* this function is called.  In that
           * case sndseq will point to the next unacknowledged byte (which might
           * have already been sent).  We will overwrite the value of sndseq
           * here before the packet is sent.
           */

          seqno = pstate->snd_sent + pstate->snd_isn;
          nllvdbg("SEND: sndseq %08x->%08x\n", conn->sndseq, seqno);
          tcp_setsequence(conn->sndseq, seqno);

#ifdef NEED_IPDOMAIN_SUPPORT
          /* If both IPv4 and IPv6 support are enabled, then we will need to
           * select which one to use when generating the outgoing packet.
           * If only one domain is selected, then the setup is already in
           * place and we need do nothing.
           */

          tcpsend_ipselect(dev, pstate);
#endif
          /* Then set-up to send that amount of data. (this won't actually
           * happen until the polling cycle completes).
           */

          devif_send(dev, &pstate->snd_buffer[pstate->snd_sent], sndlen);

          /* Check if the destination IP address is in the ARP  or Neighbor
           * table.  If not, then the send won't actually make it out... it
           * will be replaced with an ARP request or Neighbor Solicitation.
           */

          if (pstate->snd_sent != 0 || psock_send_addrchck(conn))
            {
              /* Update the amount of data sent (but not necessarily ACKed) */

              pstate->snd_sent += sndlen;
              nllvdbg("SEND: acked=%d sent=%d buflen=%d\n",
                      pstate->snd_acked, pstate->snd_sent, pstate->snd_buflen);

            }
        }
    }

#ifdef CONFIG_NET_SOCKOPTS
  /* All data has been sent and we are just waiting for ACK or re-transmit
   * indications to complete the send.  Check for a timeout.
   */

  if (send_timeout(pstate))
    {
      /* Yes.. report the timeout */

      nlldbg("SEND timeout\n");
      pstate->snd_sent = -ETIMEDOUT;
      goto end_wait;
    }
#endif /* CONFIG_NET_SOCKOPTS */

  /* Continue waiting */

  return flags;

end_wait:
  /* Do not allow any further callbacks */

  pstate->snd_cb->flags   = 0;
  pstate->snd_cb->priv    = NULL;
  pstate->snd_cb->event   = NULL;

  /* There are no outstanding, unacknowledged bytes */

  conn->unacked           = 0;

  /* Wake up the waiting thread */

  sem_post(&pstate->snd_sem);
  return flags;
}
예제 #3
0
static uint16_t sendto_interrupt(FAR struct net_driver_s *dev, FAR void *conn,
                                 FAR void *pvpriv, uint16_t flags)
{
  FAR struct sendto_s *pstate = (FAR struct sendto_s *)pvpriv;

  nllvdbg("flags: %04x\n", flags);
  if (pstate)
    {
      /* If the network device has gone down, then we will have terminate
       * the wait now with an error.
       */

      if ((flags & NETDEV_DOWN) != 0)
        {
          /* Terminate the transfer with an error. */

          nlldbg("ERROR: Network is down\n");
          pstate->st_sndlen = -ENETUNREACH;
        }

      /* Check if the outgoing packet is available.  It may have been claimed
       * by a sendto interrupt serving a different thread -OR- if the output
       * buffer currently contains unprocessed incoming data.  In these cases
       * we will just have to wait for the next polling cycle.
       */

      else if (dev->d_sndlen > 0 || (flags & UDP_NEWDATA) != 0)
        {
           /* Another thread has beat us sending data or the buffer is busy,
            * Check for a timeout.  If not timed out, wait for the next
            * polling cycle and check again.
            */

#ifdef CONFIG_NET_SENDTO_TIMEOUT
          if (send_timeout(pstate))
            {
              /* Yes.. report the timeout */

              nlldbg("ERROR: SEND timeout\n");
              pstate->st_sndlen = -ETIMEDOUT;
            }
          else
#endif /* CONFIG_NET_SENDTO_TIMEOUT */
            {
               /* No timeout.  Just wait for the next polling cycle */

               return flags;
            }
        }

      /* It looks like we are good to send the data */

      else
        {
#ifdef NEED_IPDOMAIN_SUPPORT
          /* If both IPv4 and IPv6 support are enabled, then we will need to
           * select which one to use when generating the outgoing packet.
           * If only one domain is selected, then the setup is already in
           * place and we need do nothing.
           */

          sendto_ipselect(dev, pstate);
#endif

          /* Copy the user data into d_appdata and send it */

          devif_send(dev, pstate->st_buffer, pstate->st_buflen);
          pstate->st_sndlen = pstate->st_buflen;
        }

      /* Don't allow any further call backs. */

      pstate->st_cb->flags   = 0;
      pstate->st_cb->priv    = NULL;
      pstate->st_cb->event   = NULL;

      /* Wake up the waiting thread */

      sem_post(&pstate->st_sem);
    }

  return flags;
}