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/**

 * @file

 *

 * Transmission Control Protocol for IP

 *

 * This file contains common functions for the TCP implementation, such as functinos

 * for manipulating the data structures and the TCP timer functions. TCP functions

 * related to input and output is found in tcp_in.c and tcp_out.c respectively.

 *

 */

/*

 * Copyright (c) 2001-2004 Swedish Institute of Computer Science.

 * All rights reserved.

 *

 * Redistribution and use in source and binary forms, with or without modification,

 * are permitted provided that the following conditions are met:

 *

 * 1. Redistributions of source code must retain the above copyright notice,

 *    this list of conditions and the following disclaimer.

 * 2. Redistributions in binary form must reproduce the above copyright notice,

 *    this list of conditions and the following disclaimer in the documentation

 *    and/or other materials provided with the distribution.

 * 3. The name of the author may not be used to endorse or promote products

 *    derived from this software without specific prior written permission.

 *

 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED

 * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF

 * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT

 * SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,

 * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT

 * OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS

 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN

 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING

 * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY

 * OF SUCH DAMAGE.

 *

 * This file is part of the lwIP TCP/IP stack.

 *

 * Author: Adam Dunkels <adam@sics.se>

 *

 */

#include <string.h>

#include "lwip/opt.h"

#include "lwip/def.h"

#include "lwip/mem.h"

#include "lwip/memp.h"

#include "lwip/tcp.h"

#if LWIP_TCP

/* Incremented every coarse grained timer shot

   (typically every 500 ms, determined by TCP_COARSE_TIMEOUT). */

u32_t tcp_ticks;

const u8_t tcp_backoff[13] =

    { 1, 2, 3, 4, 5, 6, 7, 7, 7, 7, 7, 7, 7};

/* The TCP PCB lists. */

/** List of all TCP PCBs in LISTEN state */

union tcp_listen_pcbs_t tcp_listen_pcbs;

/** List of all TCP PCBs that are in a state in which

 * they accept or send data. */

struct tcp_pcb *tcp_active_pcbs;

/** List of all TCP PCBs in TIME-WAIT state */

struct tcp_pcb *tcp_tw_pcbs;

struct tcp_pcb *tcp_tmp_pcb;

static u8_t tcp_timer;

static u16_t tcp_new_port(void);

/**

 * Initializes the TCP layer.

 */

void

tcp_init(void)

{

  /* Clear globals. */

  tcp_listen_pcbs.listen_pcbs = NULL;

  tcp_active_pcbs = NULL;

  tcp_tw_pcbs = NULL;

  tcp_tmp_pcb = NULL;

  /* initialize timer */

  tcp_ticks = 0;

  tcp_timer = 0;

}

/**

 * Called periodically to dispatch TCP timers.

 *

 */

void

tcp_tmr(void)

{

  /* Call tcp_fasttmr() every 250 ms */

  tcp_fasttmr();

  if (++tcp_timer & 1) {

    /* Call tcp_tmr() every 500 ms, i.e., every other timer

       tcp_tmr() is called. */

    tcp_slowtmr();

  }

}

/**

 * Closes the connection held by the PCB.

 *

 */

err_t

tcp_close(struct tcp_pcb *pcb)

{

  err_t err;

#if TCP_DEBUG

  LWIP_DEBUGF(TCP_DEBUG, ("tcp_close: closing in state "));

  tcp_debug_print_state(pcb->state);

  LWIP_DEBUGF(TCP_DEBUG, ("\n"));

#endif /* TCP_DEBUG */

  switch (pcb->state) {

  case CLOSED:

    /* Closing a pcb in the CLOSED state might seem erroneous,

     * however, it is in this state once allocated and as yet unused

     * and the user needs some way to free it should the need arise.

     * Calling tcp_close() with a pcb that has already been closed, (i.e. twice)

     * or for a pcb that has been used and then entered the CLOSED state

     * is erroneous, but this should never happen as the pcb has in those cases

     * been freed, and so any remaining handles are bogus. */

    err = ERR_OK;

    memp_free(MEMP_TCP_PCB, pcb);

    pcb = NULL;

    break;

  case LISTEN:

    err = ERR_OK;

    tcp_pcb_remove((struct tcp_pcb **)&tcp_listen_pcbs.pcbs, pcb);

    memp_free(MEMP_TCP_PCB_LISTEN, pcb);

    pcb = NULL;

    break;

  case SYN_SENT:

    err = ERR_OK;

    tcp_pcb_remove(&tcp_active_pcbs, pcb);

    memp_free(MEMP_TCP_PCB, pcb);

    pcb = NULL;

    break;

  case SYN_RCVD:

  case ESTABLISHED:

    err = tcp_send_ctrl(pcb, TCP_FIN);

    if (err == ERR_OK) {

      pcb->state = FIN_WAIT_1;

    }

    break;

  case CLOSE_WAIT:

    err = tcp_send_ctrl(pcb, TCP_FIN);

    if (err == ERR_OK) {

      pcb->state = LAST_ACK;

    }

    break;

  default:

    /* Has already been closed, do nothing. */

    err = ERR_OK;

    pcb = NULL;

    break;

  }

  if (pcb != NULL && err == ERR_OK) {

    err = tcp_output(pcb);

  }

  return err;

}

/**

 * Aborts a connection by sending a RST to the remote host and deletes

 * the local protocol control block. This is done when a connection is

 * killed because of shortage of memory.

 *

 */

void

tcp_abort(struct tcp_pcb *pcb)

{

  u32_t seqno, ackno;

  u16_t remote_port, local_port;

  struct ip_addr remote_ip, local_ip;

#if LWIP_CALLBACK_API  

  void (* errf)(void *arg, err_t err);

#endif /* LWIP_CALLBACK_API */

  void *errf_arg;

  /* Figure out on which TCP PCB list we are, and remove us. If we

     are in an active state, call the receive function associated with

     the PCB with a NULL argument, and send an RST to the remote end. */

  if (pcb->state == TIME_WAIT) {

    tcp_pcb_remove(&tcp_tw_pcbs, pcb);

    memp_free(MEMP_TCP_PCB, pcb);

  } else {

    seqno = pcb->snd_nxt;

    ackno = pcb->rcv_nxt;

    ip_addr_set(&local_ip, &(pcb->local_ip));

    ip_addr_set(&remote_ip, &(pcb->remote_ip));

    local_port = pcb->local_port;

    remote_port = pcb->remote_port;

#if LWIP_CALLBACK_API

    errf = pcb->errf;

#endif /* LWIP_CALLBACK_API */

    errf_arg = pcb->callback_arg;

    tcp_pcb_remove(&tcp_active_pcbs, pcb);

    if (pcb->unacked != NULL) {

      tcp_segs_free(pcb->unacked);

    }

    if (pcb->unsent != NULL) {

      tcp_segs_free(pcb->unsent);

    }

#if TCP_QUEUE_OOSEQ    

    if (pcb->ooseq != NULL) {

      tcp_segs_free(pcb->ooseq);

    }

#endif /* TCP_QUEUE_OOSEQ */

    memp_free(MEMP_TCP_PCB, pcb);

    TCP_EVENT_ERR(errf, errf_arg, ERR_ABRT);

    LWIP_DEBUGF(TCP_RST_DEBUG, ("tcp_abort: sending RST\n"));

    tcp_rst(seqno, ackno, &local_ip, &remote_ip, local_port, remote_port);

  }

}

/**

 * Binds the connection to a local portnumber and IP address. If the

 * IP address is not given (i.e., ipaddr == NULL), the IP address of

 * the outgoing network interface is used instead.

 *

 */

err_t

tcp_bind(struct tcp_pcb *pcb, struct ip_addr *ipaddr, u16_t port)

{

  struct tcp_pcb *cpcb;

  if (port == 0) {

    port = tcp_new_port();

  }

  /* Check if the address already is in use. */

  for(cpcb = (struct tcp_pcb *)tcp_listen_pcbs.pcbs;

      cpcb != NULL; cpcb = cpcb->next) {

    if (cpcb->local_port == port) {

      if (ip_addr_isany(&(cpcb->local_ip)) ||

        ip_addr_isany(ipaddr) ||

        ip_addr_cmp(&(cpcb->local_ip), ipaddr)) {

          return ERR_USE;

      }

    }

  }

  for(cpcb = tcp_active_pcbs;

      cpcb != NULL; cpcb = cpcb->next) {

    if (cpcb->local_port == port) {

      if (ip_addr_isany(&(cpcb->local_ip)) ||

   ip_addr_isany(ipaddr) ||

   ip_addr_cmp(&(cpcb->local_ip), ipaddr)) {

  return ERR_USE;

      }

    }

  }

  if (!ip_addr_isany(ipaddr)) {

    pcb->local_ip = *ipaddr;

  }

  pcb->local_port = port;

  LWIP_DEBUGF(TCP_DEBUG, ("tcp_bind: bind to port %"U16_F"\n", port));

  return ERR_OK;

}

#if LWIP_CALLBACK_API

static err_t

tcp_accept_null(void *arg, struct tcp_pcb *pcb, err_t err)

{

  (void)arg;

  (void)pcb;

  (void)err;

  return ERR_ABRT;

}

#endif /* LWIP_CALLBACK_API */

/**

 * Set the state of the connection to be LISTEN, which means that it

 * is able to accept incoming connections. The protocol control block

 * is reallocated in order to consume less memory. Setting the

 * connection to LISTEN is an irreversible process.

 *

 */

struct tcp_pcb *

tcp_listen(struct tcp_pcb *pcb)

{

  struct tcp_pcb_listen *lpcb;

  /* already listening? */

  if (pcb->state == LISTEN) {

    return pcb;

  }

  lpcb = memp_malloc(MEMP_TCP_PCB_LISTEN);

  if (lpcb == NULL) {

    return NULL;

  }

  lpcb->callback_arg = pcb->callback_arg;

  lpcb->local_port = pcb->local_port;

  lpcb->state = LISTEN;

  lpcb->so_options = pcb->so_options;

  lpcb->so_options |= SOF_ACCEPTCONN;

  lpcb->ttl = pcb->ttl;

  lpcb->tos = pcb->tos;

  ip_addr_set(&lpcb->local_ip, &pcb->local_ip);

  memp_free(MEMP_TCP_PCB, pcb);

#if LWIP_CALLBACK_API

  lpcb->accept = tcp_accept_null;

#endif /* LWIP_CALLBACK_API */

  TCP_REG(&tcp_listen_pcbs.listen_pcbs, lpcb);

  return (struct tcp_pcb *)lpcb;

}

/**

 * This function should be called by the application when it has

 * processed the data. The purpose is to advertise a larger window

 * when the data has been processed.

 *

 */

void

tcp_recved(struct tcp_pcb *pcb, u16_t len)

{

  if ((u32_t)pcb->rcv_wnd + len > TCP_WND) {

    pcb->rcv_wnd = TCP_WND;

  } else {

    pcb->rcv_wnd += len;

  }

  if (!(pcb->flags & TF_ACK_DELAY) &&

     !(pcb->flags & TF_ACK_NOW)) {

    /*

     * We send an ACK here (if one is not already pending, hence

     * the above tests) as tcp_recved() implies that the application

     * has processed some data, and so we can open the receiver's

     * window to allow more to be transmitted.  This could result in

     * two ACKs being sent for each received packet in some limited cases

     * (where the application is only receiving data, and is slow to

     * process it) but it is necessary to guarantee that the sender can

     * continue to transmit.

     */

    tcp_ack(pcb);

  }

  else if (pcb->flags & TF_ACK_DELAY && pcb->rcv_wnd >= TCP_WND/2) {

    /* If we can send a window update such that there is a full

     * segment available in the window, do so now.  This is sort of

     * nagle-like in its goals, and tries to hit a compromise between

     * sending acks each time the window is updated, and only sending

     * window updates when a timer expires.  The "threshold" used

     * above (currently TCP_WND/2) can be tuned to be more or less

     * aggressive  */

    tcp_ack_now(pcb);

  }

  LWIP_DEBUGF(TCP_DEBUG, ("tcp_recved: recveived %"U16_F" bytes, wnd %"U16_F" (%"U16_F").\n",

         len, pcb->rcv_wnd, TCP_WND - pcb->rcv_wnd));

}

/**

 * A nastly hack featuring 'goto' statements that allocates a

 * new TCP local port.

 */

static u16_t

tcp_new_port(void)

{

  struct tcp_pcb *pcb;

#ifndef TCP_LOCAL_PORT_RANGE_START

#define TCP_LOCAL_PORT_RANGE_START 4096

#define TCP_LOCAL_PORT_RANGE_END   0x7fff

#endif

  static u16_t port = TCP_LOCAL_PORT_RANGE_START;

 again:

  if (++port > TCP_LOCAL_PORT_RANGE_END) {

    port = TCP_LOCAL_PORT_RANGE_START;

  }

  for(pcb = tcp_active_pcbs; pcb != NULL; pcb = pcb->next) {

    if (pcb->local_port == port) {

      goto again;

    }

  }

  for(pcb = tcp_tw_pcbs; pcb != NULL; pcb = pcb->next) {

    if (pcb->local_port == port) {

      goto again;

    }

  }

  for(pcb = (struct tcp_pcb *)tcp_listen_pcbs.pcbs; pcb != NULL; pcb = pcb->next) {

    if (pcb->local_port == port) {

      goto again;

    }

  }

  return port;

}

/**

 * Connects to another host. The function given as the "connected"

 * argument will be called when the connection has been established.

 *

 */

err_t

tcp_connect(struct tcp_pcb *pcb, struct ip_addr *ipaddr, u16_t port,

      err_t (* connected)(void *arg, struct tcp_pcb *tpcb, err_t err))

{

  u32_t optdata;

  err_t ret;

  u32_t iss;

  LWIP_DEBUGF(TCP_DEBUG, ("tcp_connect to port %"U16_F"\n", port));

  if (ipaddr != NULL) {

    pcb->remote_ip = *ipaddr;

  } else {

    return ERR_VAL;

  }

  pcb->remote_port = port;

  if (pcb->local_port == 0) {

    pcb->local_port = tcp_new_port();

  }

  iss = tcp_next_iss();

  pcb->rcv_nxt = 0;

  pcb->snd_nxt = iss;

  pcb->lastack = iss - 1;

  pcb->snd_lbb = iss - 1;

  pcb->rcv_wnd = TCP_WND;

  pcb->snd_wnd = TCP_WND;

  pcb->mss = TCP_MSS;

  pcb->cwnd = 1;

  pcb->ssthresh = pcb->mss * 10;

  pcb->state = SYN_SENT;

#if LWIP_CALLBACK_API  

  pcb->connected = connected;

#endif /* LWIP_CALLBACK_API */  

  TCP_REG(&tcp_active_pcbs, pcb);

  /* Build an MSS option */

  optdata = htonl(((u32_t)2 << 24) |

      ((u32_t)4 << 16) |

      (((u32_t)pcb->mss / 256) << 8) |

      (pcb->mss & 255));

  ret = tcp_enqueue(pcb, NULL, 0, TCP_SYN, 0, (u8_t *)&optdata, 4);

  if (ret == ERR_OK) {

    tcp_output(pcb);

  }

  return ret;

}

/**

 * Called every 500 ms and implements the retransmission timer and the timer that

 * removes PCBs that have been in TIME-WAIT for enough time. It also increments

 * various timers such as the inactivity timer in each PCB.

 */

void

tcp_slowtmr(void)

{

  struct tcp_pcb *pcb, *pcb2, *prev;

  u32_t eff_wnd;

  u8_t pcb_remove;      /* flag if a PCB should be removed */

  err_t err;

  err = ERR_OK;

  ++tcp_ticks;

  /* Steps through all of the active PCBs. */

  prev = NULL;

  pcb = tcp_active_pcbs;

  if (pcb == NULL) {

    LWIP_DEBUGF(TCP_DEBUG, ("tcp_slowtmr: no active pcbs\n"));

  }

  while (pcb != NULL) {

    LWIP_DEBUGF(TCP_DEBUG, ("tcp_slowtmr: processing active pcb\n"));

    LWIP_ASSERT("tcp_slowtmr: active pcb->state != CLOSED\n", pcb->state != CLOSED);

    LWIP_ASSERT("tcp_slowtmr: active pcb->state != LISTEN\n", pcb->state != LISTEN);

    LWIP_ASSERT("tcp_slowtmr: active pcb->state != TIME-WAIT\n", pcb->state != TIME_WAIT);

    pcb_remove = 0;

    if (pcb->state == SYN_SENT && pcb->nrtx == TCP_SYNMAXRTX) {

      ++pcb_remove;

      LWIP_DEBUGF(TCP_DEBUG, ("tcp_slowtmr: max SYN retries reached\n"));

    }

    else if (pcb->nrtx == TCP_MAXRTX) {

      ++pcb_remove;

      LWIP_DEBUGF(TCP_DEBUG, ("tcp_slowtmr: max DATA retries reached\n"));

    } else {

      ++pcb->rtime;

      if (pcb->unacked != NULL && pcb->rtime >= pcb->rto) {

        /* Time for a retransmission. */

        LWIP_DEBUGF(TCP_RTO_DEBUG, ("tcp_slowtmr: rtime %"U16_F" pcb->rto %"U16_F"\n",

          pcb->rtime, pcb->rto));

        /* Double retransmission time-out unless we are trying to

         * connect to somebody (i.e., we are in SYN_SENT). */

        if (pcb->state != SYN_SENT) {

          pcb->rto = ((pcb->sa >> 3) + pcb->sv) << tcp_backoff[pcb->nrtx];

        }

        /* Reduce congestion window and ssthresh. */

        eff_wnd = LWIP_MIN(pcb->cwnd, pcb->snd_wnd);

        pcb->ssthresh = eff_wnd >> 1;

        if (pcb->ssthresh < pcb->mss) {

          pcb->ssthresh = pcb->mss * 2;

        }

        pcb->cwnd = pcb->mss;

        LWIP_DEBUGF(TCP_CWND_DEBUG, ("tcp_slowtmr: cwnd %"U16_F" ssthresh %"U16_F"\n",

                                pcb->cwnd, pcb->ssthresh));

        /* The following needs to be called AFTER cwnd is set to one mss - STJ */

        tcp_rexmit_rto(pcb);

     }

    }

    /* Check if this PCB has stayed too long in FIN-WAIT-2 */

    if (pcb->state == FIN_WAIT_2) {

      if ((u32_t)(tcp_ticks - pcb->tmr) >

        TCP_FIN_WAIT_TIMEOUT / TCP_SLOW_INTERVAL) {

        ++pcb_remove;

        LWIP_DEBUGF(TCP_DEBUG, ("tcp_slowtmr: removing pcb stuck in FIN-WAIT-2\n"));

      }

    }

   /* Check if KEEPALIVE should be sent */

   if((pcb->so_options & SOF_KEEPALIVE) && ((pcb->state == ESTABLISHED) || (pcb->state == CLOSE_WAIT))) {

      if((u32_t)(tcp_ticks - pcb->tmr) > (pcb->keepalive + TCP_MAXIDLE) / TCP_SLOW_INTERVAL)  {

         LWIP_DEBUGF(TCP_DEBUG, ("tcp_slowtmr: KEEPALIVE timeout. Aborting connection to %"U16_F".%"U16_F".%"U16_F".%"U16_F".\n",

                                 ip4_addr1(&pcb->remote_ip), ip4_addr2(&pcb->remote_ip),

                                 ip4_addr3(&pcb->remote_ip), ip4_addr4(&pcb->remote_ip)));

         tcp_abort(pcb);

      }

      else if((u32_t)(tcp_ticks - pcb->tmr) > (pcb->keepalive + pcb->keep_cnt * TCP_KEEPINTVL) / TCP_SLOW_INTERVAL) {

         tcp_keepalive(pcb);

         pcb->keep_cnt++;

      }

   }

    /* If this PCB has queued out of sequence data, but has been

       inactive for too long, will drop the data (it will eventually

       be retransmitted). */

#if TCP_QUEUE_OOSEQ    

    if (pcb->ooseq != NULL &&

       (u32_t)tcp_ticks - pcb->tmr >=

       pcb->rto * TCP_OOSEQ_TIMEOUT) {

      tcp_segs_free(pcb->ooseq);

      pcb->ooseq = NULL;

      LWIP_DEBUGF(TCP_CWND_DEBUG, ("tcp_slowtmr: dropping OOSEQ queued data\n"));

    }

#endif /* TCP_QUEUE_OOSEQ */

    /* Check if this PCB has stayed too long in SYN-RCVD */

    if (pcb->state == SYN_RCVD) {

      if ((u32_t)(tcp_ticks - pcb->tmr) >

        TCP_SYN_RCVD_TIMEOUT / TCP_SLOW_INTERVAL) {

        ++pcb_remove;

        LWIP_DEBUGF(TCP_DEBUG, ("tcp_slowtmr: removing pcb stuck in SYN-RCVD\n"));

      }

    }

    /* Check if this PCB has stayed too long in LAST-ACK */

    if (pcb->state == LAST_ACK) {

      if ((u32_t)(tcp_ticks - pcb->tmr) > 2 * TCP_MSL / TCP_SLOW_INTERVAL) {

        ++pcb_remove;

        LWIP_DEBUGF(TCP_DEBUG, ("tcp_slowtmr: removing pcb stuck in LAST-ACK\n"));

      }

    }

    /* If the PCB should be removed, do it. */

    if (pcb_remove) {

      tcp_pcb_purge(pcb);

      /* Remove PCB from tcp_active_pcbs list. */

      if (prev != NULL) {

  LWIP_ASSERT("tcp_slowtmr: middle tcp != tcp_active_pcbs", pcb != tcp_active_pcbs);

        prev->next = pcb->next;

      } else {

        /* This PCB was the first. */

        LWIP_ASSERT("tcp_slowtmr: first pcb == tcp_active_pcbs", tcp_active_pcbs == pcb);

        tcp_active_pcbs = pcb->next;

      }

      TCP_EVENT_ERR(pcb->errf, pcb->callback_arg, ERR_ABRT);

      pcb2 = pcb->next;

      memp_free(MEMP_TCP_PCB, pcb);

      pcb = pcb2;

    } else {

      /* We check if we should poll the connection. */

      ++pcb->polltmr;

      if (pcb->polltmr >= pcb->pollinterval) {

        pcb->polltmr = 0;

        LWIP_DEBUGF(TCP_DEBUG, ("tcp_slowtmr: polling application\n"));

        TCP_EVENT_POLL(pcb, err);

        if (err == ERR_OK) {

          tcp_output(pcb);

        }

      }

      prev = pcb;

      pcb = pcb->next;

    }

  }

  /* Steps through all of the TIME-WAIT PCBs. */

  prev = NULL;

  pcb = tcp_tw_pcbs;

  while (pcb != NULL) {

    LWIP_ASSERT("tcp_slowtmr: TIME-WAIT pcb->state == TIME-WAIT", pcb->state == TIME_WAIT);

    pcb_remove = 0;

    /* Check if this PCB has stayed long enough in TIME-WAIT */

    if ((u32_t)(tcp_ticks - pcb->tmr) > 2 * TCP_MSL / TCP_SLOW_INTERVAL) {

      ++pcb_remove;

    }

    /* If the PCB should be removed, do it. */

    if (pcb_remove) {

      tcp_pcb_purge(pcb);

      /* Remove PCB from tcp_tw_pcbs list. */

      if (prev != NULL) {

  LWIP_ASSERT("tcp_slowtmr: middle tcp != tcp_tw_pcbs", pcb != tcp_tw_pcbs);

        prev->next = pcb->next;

      } else {

        /* This PCB was the first. */

        LWIP_ASSERT("tcp_slowtmr: first pcb == tcp_tw_pcbs", tcp_tw_pcbs == pcb);

        tcp_tw_pcbs = pcb->next;

      }

      pcb2 = pcb->next;

      memp_free(MEMP_TCP_PCB, pcb);

      pcb = pcb2;

    } else {

      prev = pcb;

      pcb = pcb->next;

    }

  }

}

/**

 * Is called every TCP_FAST_INTERVAL (250 ms) and sends delayed ACKs.

 */

void

tcp_fasttmr(void)

{

  struct tcp_pcb *pcb;

  /* send delayed ACKs */

  for(pcb = tcp_active_pcbs; pcb != NULL; pcb = pcb->next) {

    if (pcb->flags & TF_ACK_DELAY) {

      LWIP_DEBUGF(TCP_DEBUG, ("tcp_fasttmr: delayed ACK\n"));

      tcp_ack_now(pcb);

      pcb->flags &= ~(TF_ACK_DELAY | TF_ACK_NOW);

    }

  }

}

/**

 * Deallocates a list of TCP segments (tcp_seg structures).

 *

 */

u8_t

tcp_segs_free(struct tcp_seg *seg)

{

  u8_t count = 0;

  struct tcp_seg *next;

  while (seg != NULL) {

    next = seg->next;

    count += tcp_seg_free(seg);

    seg = next;

  }

  return count;

}

/**

 * Frees a TCP segment.

 *

 */