Diff for /embedaddon/iperf/src/iperf_udp.c between versions 1.1 and 1.1.1.3

version 1.1, 2016/10/18 13:28:18 version 1.1.1.3, 2023/09/27 11:14:54
Line 1 Line 1
 /*  /*
 * iperf, Copyright (c) 2014, 2016, The Regents of the University of * iperf, Copyright (c) 2014-2022, The Regents of the University of
  * California, through Lawrence Berkeley National Laboratory (subject   * California, through Lawrence Berkeley National Laboratory (subject
  * to receipt of any required approvals from the U.S. Dept. of   * to receipt of any required approvals from the U.S. Dept. of
  * Energy).  All rights reserved.   * Energy).  All rights reserved.
Line 30 Line 30
 #include <errno.h>  #include <errno.h>
 #include <unistd.h>  #include <unistd.h>
 #include <assert.h>  #include <assert.h>
   #include <arpa/inet.h>
 #include <sys/socket.h>  #include <sys/socket.h>
 #include <sys/types.h>  #include <sys/types.h>
 #include <netinet/in.h>  #include <netinet/in.h>
Line 45 Line 46
 #include "iperf_udp.h"  #include "iperf_udp.h"
 #include "timer.h"  #include "timer.h"
 #include "net.h"  #include "net.h"
   #include "cjson.h"
 #include "portable_endian.h"  #include "portable_endian.h"
   
   #if defined(HAVE_INTTYPES_H)
   # include <inttypes.h>
   #else
   # ifndef PRIu64
   #  if sizeof(long) == 8
   #   define PRIu64               "lu"
   #  else
   #   define PRIu64               "llu"
   #  endif
   # endif
   #endif
   
 /* iperf_udp_recv  /* iperf_udp_recv
  *   *
  * receives the data for UDP   * receives the data for UDP
Line 58  iperf_udp_recv(struct iperf_stream *sp) Line 72  iperf_udp_recv(struct iperf_stream *sp)
     uint64_t  pcount;      uint64_t  pcount;
     int       r;      int       r;
     int       size = sp->settings->blksize;      int       size = sp->settings->blksize;
       int       first_packet = 0;
     double    transit = 0, d = 0;      double    transit = 0, d = 0;
    struct timeval sent_time, arrival_time;    struct iperf_time sent_time, arrival_time, temp_time;
   
     r = Nread(sp->socket, sp->buffer, size, Pudp);      r = Nread(sp->socket, sp->buffer, size, Pudp);
   
Line 71  iperf_udp_recv(struct iperf_stream *sp) Line 86  iperf_udp_recv(struct iperf_stream *sp)
     if (r <= 0)      if (r <= 0)
         return r;          return r;
   
    sp->result->bytes_received += r;    /* Only count bytes received while we're in the correct state. */
    sp->result->bytes_received_this_interval += r;    if (sp->test->state == TEST_RUNNING) {
   
    if (sp->test->udp_counters_64bit) {        /*
        memcpy(&sec, sp->buffer, sizeof(sec));         * For jitter computation below, it's important to know if this
        memcpy(&usec, sp->buffer+4, sizeof(usec));         * packet is the first packet received.
        memcpy(&pcount, sp->buffer+8, sizeof(pcount));         */
        sec = ntohl(sec);        if (sp->result->bytes_received == 0) {
        usec = ntohl(usec);            first_packet = 1;
        pcount = be64toh(pcount);        }
        sent_time.tv_sec = sec; 
        sent_time.tv_usec = usec; 
    } 
    else { 
        uint32_t pc; 
        memcpy(&sec, sp->buffer, sizeof(sec)); 
        memcpy(&usec, sp->buffer+4, sizeof(usec)); 
        memcpy(&pc, sp->buffer+8, sizeof(pc)); 
        sec = ntohl(sec); 
        usec = ntohl(usec); 
        pcount = ntohl(pc); 
        sent_time.tv_sec = sec; 
        sent_time.tv_usec = usec; 
    } 
   
    /* Out of order packets */        sp->result->bytes_received += r;
    if (pcount >= sp->packet_count + 1) {        sp->result->bytes_received_this_interval += r;
        if (pcount > sp->packet_count + 1) { 
            sp->cnt_error += (pcount - 1) - sp->packet_count; 
        } 
        sp->packet_count = pcount; 
    } else { 
        sp->outoforder_packets++; 
        iperf_err(sp->test, "OUT OF ORDER - incoming packet = %zu and received packet = %d AND SP = %d", pcount, sp->packet_count, sp->socket); 
    } 
   
    /* jitter measurement */        /* Dig the various counters out of the incoming UDP packet */
    gettimeofday(&arrival_time, NULL);        if (sp->test->udp_counters_64bit) {
             memcpy(&sec, sp->buffer, sizeof(sec));
             memcpy(&usec, sp->buffer+4, sizeof(usec));
             memcpy(&pcount, sp->buffer+8, sizeof(pcount));
             sec = ntohl(sec);
             usec = ntohl(usec);
             pcount = be64toh(pcount);
             sent_time.secs = sec;
             sent_time.usecs = usec;
         }
         else {
             uint32_t pc;
             memcpy(&sec, sp->buffer, sizeof(sec));
             memcpy(&usec, sp->buffer+4, sizeof(usec));
             memcpy(&pc, sp->buffer+8, sizeof(pc));
             sec = ntohl(sec);
             usec = ntohl(usec);
             pcount = ntohl(pc);
             sent_time.secs = sec;
             sent_time.usecs = usec;
         }
   
    transit = timeval_diff(&sent_time, &arrival_time);        if (sp->test->debug_level >= DEBUG_LEVEL_DEBUG)
    d = transit - sp->prev_transit;            fprintf(stderr, "pcount %" PRIu64 " packet_count %" PRIu64 "\n", pcount, sp->packet_count);
    if (d < 0) 
        d = -d; 
    sp->prev_transit = transit; 
    // XXX: This is NOT the way to calculate jitter 
    //      J = |(R1 - S1) - (R0 - S0)| [/ number of packets, for average] 
    sp->jitter += (d - sp->jitter) / 16.0; 
   
    if (sp->test->debug) {        /*
        fprintf(stderr, "packet_count %d\n", sp->packet_count);         * Try to handle out of order packets.  The way we do this
          * uses a constant amount of storage but might not be
          * correct in all cases.  In particular we seem to have the
          * assumption that packets can't be duplicated in the network,
          * because duplicate packets will possibly cause some problems here.
          *
          * First figure out if the sequence numbers are going forward.
          * Note that pcount is the sequence number read from the packet,
          * and sp->packet_count is the highest sequence number seen so
          * far (so we're expecting to see the packet with sequence number
          * sp->packet_count + 1 arrive next).
          */
         if (pcount >= sp->packet_count + 1) {
 
             /* Forward, but is there a gap in sequence numbers? */
             if (pcount > sp->packet_count + 1) {
                 /* There's a gap so count that as a loss. */
                 sp->cnt_error += (pcount - 1) - sp->packet_count;
             }
             /* Update the highest sequence number seen so far. */
             sp->packet_count = pcount;
         } else {
 
             /*
              * Sequence number went backward (or was stationary?!?).
              * This counts as an out-of-order packet.
              */
             sp->outoforder_packets++;
 
             /*
              * If we have lost packets, then the fact that we are now
              * seeing an out-of-order packet offsets a prior sequence
              * number gap that was counted as a loss.  So we can take
              * away a loss.
              */
             if (sp->cnt_error > 0)
                 sp->cnt_error--;
 
             /* Log the out-of-order packet */
             if (sp->test->debug)
                 fprintf(stderr, "OUT OF ORDER - incoming packet sequence %" PRIu64 " but expected sequence %" PRIu64 " on stream %d", pcount, sp->packet_count + 1, sp->socket);
         }
 
         /*
          * jitter measurement
          *
          * This computation is based on RFC 1889 (specifically
          * sections 6.3.1 and A.8).
          *
          * Note that synchronized clocks are not required since
          * the source packet delta times are known.  Also this
          * computation does not require knowing the round-trip
          * time.
          */
         iperf_time_now(&arrival_time);
 
         iperf_time_diff(&arrival_time, &sent_time, &temp_time);
         transit = iperf_time_in_secs(&temp_time);
 
         /* Hack to handle the first packet by initializing prev_transit. */
         if (first_packet)
             sp->prev_transit = transit;
 
         d = transit - sp->prev_transit;
         if (d < 0)
             d = -d;
         sp->prev_transit = transit;
         sp->jitter += (d - sp->jitter) / 16.0;
     }      }
       else {
           if (sp->test->debug)
               printf("Late receive, state = %d\n", sp->test->state);
       }
   
     return r;      return r;
 }  }
Line 136  iperf_udp_send(struct iperf_stream *sp) Line 214  iperf_udp_send(struct iperf_stream *sp)
 {  {
     int r;      int r;
     int       size = sp->settings->blksize;      int       size = sp->settings->blksize;
    struct timeval before;    struct iperf_time before;
   
    gettimeofday(&before, 0);    iperf_time_now(&before);
   
     ++sp->packet_count;      ++sp->packet_count;
   
Line 147  iperf_udp_send(struct iperf_stream *sp) Line 225  iperf_udp_send(struct iperf_stream *sp)
         uint32_t  sec, usec;          uint32_t  sec, usec;
         uint64_t  pcount;          uint64_t  pcount;
   
        sec = htonl(before.tv_sec);        sec = htonl(before.secs);
        usec = htonl(before.tv_usec);        usec = htonl(before.usecs);
         pcount = htobe64(sp->packet_count);          pcount = htobe64(sp->packet_count);
        
         memcpy(sp->buffer, &sec, sizeof(sec));          memcpy(sp->buffer, &sec, sizeof(sec));
         memcpy(sp->buffer+4, &usec, sizeof(usec));          memcpy(sp->buffer+4, &usec, sizeof(usec));
         memcpy(sp->buffer+8, &pcount, sizeof(pcount));          memcpy(sp->buffer+8, &pcount, sizeof(pcount));
        
     }      }
     else {      else {
   
         uint32_t  sec, usec, pcount;          uint32_t  sec, usec, pcount;
   
        sec = htonl(before.tv_sec);        sec = htonl(before.secs);
        usec = htonl(before.tv_usec);        usec = htonl(before.usecs);
         pcount = htonl(sp->packet_count);          pcount = htonl(sp->packet_count);
        
         memcpy(sp->buffer, &sec, sizeof(sec));          memcpy(sp->buffer, &sec, sizeof(sec));
         memcpy(sp->buffer+4, &usec, sizeof(usec));          memcpy(sp->buffer+4, &usec, sizeof(usec));
         memcpy(sp->buffer+8, &pcount, sizeof(pcount));          memcpy(sp->buffer+8, &pcount, sizeof(pcount));
        
     }      }
   
     r = Nwrite(sp->socket, sp->buffer, size, Pudp);      r = Nwrite(sp->socket, sp->buffer, size, Pudp);
   
    if (r < 0)    if (r <= 0) {
        return r;        --sp->packet_count;     /* Don't count messages that no data was sent from them.
                                  * Allows "resending" a massage with the same numbering */
         if (r < 0) {
             if (r == NET_SOFTERROR && sp->test->debug_level >= DEBUG_LEVEL_INFO)
                 printf("UDP send failed on NET_SOFTERROR. errno=%s\n", strerror(errno));
             return r;
         }
     }
   
     sp->result->bytes_sent += r;      sp->result->bytes_sent += r;
     sp->result->bytes_sent_this_interval += r;      sp->result->bytes_sent_this_interval += r;
   
       if (sp->test->debug_level >=  DEBUG_LEVEL_DEBUG)
           printf("sent %d bytes of %d, total %" PRIu64 "\n", r, sp->settings->blksize, sp->result->bytes_sent);
   
     return r;      return r;
 }  }
   
Line 194  iperf_udp_send(struct iperf_stream *sp) Line 282  iperf_udp_send(struct iperf_stream *sp)
  */   */
   
 /*  /*
    * Set and verify socket buffer sizes.
    * Return 0 if no error, -1 if an error, +1 if socket buffers are
    * potentially too small to hold a message.
    */
   int
   iperf_udp_buffercheck(struct iperf_test *test, int s)
   {
       int rc = 0;
       int sndbuf_actual, rcvbuf_actual;
   
       /*
        * Set socket buffer size if requested.  Do this for both sending and
        * receiving so that we can cover both normal and --reverse operation.
        */
       int opt;
       socklen_t optlen;
   
       if ((opt = test->settings->socket_bufsize)) {
           if (setsockopt(s, SOL_SOCKET, SO_RCVBUF, &opt, sizeof(opt)) < 0) {
               i_errno = IESETBUF;
               return -1;
           }
           if (setsockopt(s, SOL_SOCKET, SO_SNDBUF, &opt, sizeof(opt)) < 0) {
               i_errno = IESETBUF;
               return -1;
           }
       }
   
       /* Read back and verify the sender socket buffer size */
       optlen = sizeof(sndbuf_actual);
       if (getsockopt(s, SOL_SOCKET, SO_SNDBUF, &sndbuf_actual, &optlen) < 0) {
           i_errno = IESETBUF;
           return -1;
       }
       if (test->debug) {
           printf("SNDBUF is %u, expecting %u\n", sndbuf_actual, test->settings->socket_bufsize);
       }
       if (test->settings->socket_bufsize && test->settings->socket_bufsize > sndbuf_actual) {
           i_errno = IESETBUF2;
           return -1;
       }
       if (test->settings->blksize > sndbuf_actual) {
           char str[WARN_STR_LEN];
           snprintf(str, sizeof(str),
                    "Block size %d > sending socket buffer size %d",
                    test->settings->blksize, sndbuf_actual);
           warning(str);
           rc = 1;
       }
   
       /* Read back and verify the receiver socket buffer size */
       optlen = sizeof(rcvbuf_actual);
       if (getsockopt(s, SOL_SOCKET, SO_RCVBUF, &rcvbuf_actual, &optlen) < 0) {
           i_errno = IESETBUF;
           return -1;
       }
       if (test->debug) {
           printf("RCVBUF is %u, expecting %u\n", rcvbuf_actual, test->settings->socket_bufsize);
       }
       if (test->settings->socket_bufsize && test->settings->socket_bufsize > rcvbuf_actual) {
           i_errno = IESETBUF2;
           return -1;
       }
       if (test->settings->blksize > rcvbuf_actual) {
           char str[WARN_STR_LEN];
           snprintf(str, sizeof(str),
                    "Block size %d > receiving socket buffer size %d",
                    test->settings->blksize, rcvbuf_actual);
           warning(str);
           rc = 1;
       }
   
       if (test->json_output) {
       cJSON *sock_bufsize_item = cJSON_GetObjectItem(test->json_start, "sock_bufsize");
       if (sock_bufsize_item == NULL) {
       cJSON_AddNumberToObject(test->json_start, "sock_bufsize", test->settings->socket_bufsize);
       }
   
       cJSON *sndbuf_actual_item = cJSON_GetObjectItem(test->json_start, "sndbuf_actual");
       if (sndbuf_actual_item == NULL) {
           cJSON_AddNumberToObject(test->json_start, "sndbuf_actual", sndbuf_actual);
       }
           
       cJSON *rcvbuf_actual_item = cJSON_GetObjectItem(test->json_start, "rcvbuf_actual");
       if (rcvbuf_actual_item == NULL) {
           cJSON_AddNumberToObject(test->json_start, "rcvbuf_actual", rcvbuf_actual);
       }
       }
   
       return rc;
   }
   
   /*
  * iperf_udp_accept   * iperf_udp_accept
  *   *
  * Accepts a new UDP "connection"   * Accepts a new UDP "connection"
Line 202  int Line 383  int
 iperf_udp_accept(struct iperf_test *test)  iperf_udp_accept(struct iperf_test *test)
 {  {
     struct sockaddr_storage sa_peer;      struct sockaddr_storage sa_peer;
    int       buf;    unsigned int buf;
     socklen_t len;      socklen_t len;
     int       sz, s;      int       sz, s;
       int       rc;
   
     /*      /*
      * Get the current outstanding socket.  This socket will be used to handle       * Get the current outstanding socket.  This socket will be used to handle
Line 228  iperf_udp_accept(struct iperf_test *test) Line 410  iperf_udp_accept(struct iperf_test *test)
         return -1;          return -1;
     }      }
   
       /* Check and set socket buffer sizes */
       rc = iperf_udp_buffercheck(test, s);
       if (rc < 0)
           /* error */
           return rc;
     /*      /*
     * Set socket buffer size if requested.  Do this for both sending and     * If the socket buffer was too small, but it was the default
     * receiving so that we can cover both normal and --reverse operation.     * size, then try explicitly setting it to something larger.
      */       */
    int opt;    if (rc > 0) {
    if ((opt = test->settings->socket_bufsize)) {        if (test->settings->socket_bufsize == 0) {
        if (setsockopt(s, SOL_SOCKET, SO_RCVBUF, &opt, sizeof(opt)) < 0) {            char str[WARN_STR_LEN];
            i_errno = IESETBUF;            int bufsize = test->settings->blksize + UDP_BUFFER_EXTRA;
            return -1;            snprintf(str, sizeof(str), "Increasing socket buffer size to %d",
        }                     bufsize);
        if (setsockopt(s, SOL_SOCKET, SO_SNDBUF, &opt, sizeof(opt)) < 0) {            warning(str);
            i_errno = IESETBUF;            test->settings->socket_bufsize = bufsize;
            return -1;            rc = iperf_udp_buffercheck(test, s);
        }            if (rc < 0)
                 return rc;
         }
     }      }
   
 #if defined(HAVE_SO_MAX_PACING_RATE)  #if defined(HAVE_SO_MAX_PACING_RATE)
    /* If socket pacing is available and not disabled, try it. */    /* If socket pacing is specified, try it. */
    if (! test->no_fq_socket_pacing) {    if (test->settings->fqrate) {
         /* Convert bits per second to bytes per second */          /* Convert bits per second to bytes per second */
        unsigned int rate = test->settings->rate / 8;        unsigned int fqrate = test->settings->fqrate / 8;
        if (rate > 0) {        if (fqrate > 0) {
             if (test->debug) {              if (test->debug) {
                printf("Setting fair-queue socket pacing to %u\n", rate);                printf("Setting fair-queue socket pacing to %u\n", fqrate);
             }              }
            if (setsockopt(s, SOL_SOCKET, SO_MAX_PACING_RATE, &rate, sizeof(rate)) < 0) {            if (setsockopt(s, SOL_SOCKET, SO_MAX_PACING_RATE, &fqrate, sizeof(fqrate)) < 0) {
                warning("Unable to set socket pacing, using application pacing instead");                warning("Unable to set socket pacing");
                test->no_fq_socket_pacing = 1; 
             }              }
         }          }
     }      }
 #endif /* HAVE_SO_MAX_PACING_RATE */  #endif /* HAVE_SO_MAX_PACING_RATE */
       {
           unsigned int rate = test->settings->rate / 8;
           if (rate > 0) {
               if (test->debug) {
                   printf("Setting application pacing to %u\n", rate);
               }
           }
       }
   
     /*      /*
      * Create a new "listening" socket to replace the one we were using before.       * Create a new "listening" socket to replace the one we were using before.
      */       */
    test->prot_listener = netannounce(test->settings->domain, Pudp, test->bind_address, test->server_port);    test->prot_listener = netannounce(test->settings->domain, Pudp, test->bind_address, test->bind_dev, test->server_port);
     if (test->prot_listener < 0) {      if (test->prot_listener < 0) {
         i_errno = IESTREAMLISTEN;          i_errno = IESTREAMLISTEN;
         return -1;          return -1;
Line 274  iperf_udp_accept(struct iperf_test *test) Line 470  iperf_udp_accept(struct iperf_test *test)
     test->max_fd = (test->max_fd < test->prot_listener) ? test->prot_listener : test->max_fd;      test->max_fd = (test->max_fd < test->prot_listener) ? test->prot_listener : test->max_fd;
   
     /* Let the client know we're ready "accept" another UDP "stream" */      /* Let the client know we're ready "accept" another UDP "stream" */
    buf = 987654321;              /* any content will work here */    buf = UDP_CONNECT_REPLY;
     if (write(s, &buf, sizeof(buf)) < 0) {      if (write(s, &buf, sizeof(buf)) < 0) {
         i_errno = IESTREAMWRITE;          i_errno = IESTREAMWRITE;
         return -1;          return -1;
Line 296  iperf_udp_listen(struct iperf_test *test) Line 492  iperf_udp_listen(struct iperf_test *test)
 {  {
     int s;      int s;
   
    if ((s = netannounce(test->settings->domain, Pudp, test->bind_address, test->server_port)) < 0) {    if ((s = netannounce(test->settings->domain, Pudp, test->bind_address, test->bind_dev, test->server_port)) < 0) {
         i_errno = IESTREAMLISTEN;          i_errno = IESTREAMLISTEN;
         return -1;          return -1;
     }      }
Line 316  iperf_udp_listen(struct iperf_test *test) Line 512  iperf_udp_listen(struct iperf_test *test)
 int  int
 iperf_udp_connect(struct iperf_test *test)  iperf_udp_connect(struct iperf_test *test)
 {  {
    int s, buf, sz;    int s, sz;
     unsigned int buf;
 #ifdef SO_RCVTIMEO  #ifdef SO_RCVTIMEO
     struct timeval tv;      struct timeval tv;
 #endif  #endif
       int rc;
       int i, max_len_wait_for_reply;
   
     /* Create and bind our local socket. */      /* Create and bind our local socket. */
    if ((s = netdial(test->settings->domain, Pudp, test->bind_address, test->bind_port, test->server_hostname, test->server_port)) < 0) {    if ((s = netdial(test->settings->domain, Pudp, test->bind_address, test->bind_dev, test->bind_port, test->server_hostname, test->server_port, -1)) < 0) {
         i_errno = IESTREAMCONNECT;          i_errno = IESTREAMCONNECT;
         return -1;          return -1;
     }      }
   
       /* Check and set socket buffer sizes */
       rc = iperf_udp_buffercheck(test, s);
       if (rc < 0)
           /* error */
           return rc;
     /*      /*
     * Set socket buffer size if requested.  Do this for both sending and     * If the socket buffer was too small, but it was the default
     * receiving so that we can cover both normal and --reverse operation.     * size, then try explicitly setting it to something larger.
      */       */
    int opt;    if (rc > 0) {
    if ((opt = test->settings->socket_bufsize)) {        if (test->settings->socket_bufsize == 0) {
        if (setsockopt(s, SOL_SOCKET, SO_RCVBUF, &opt, sizeof(opt)) < 0) {            char str[WARN_STR_LEN];
            i_errno = IESETBUF;            int bufsize = test->settings->blksize + UDP_BUFFER_EXTRA;
            return -1;            snprintf(str, sizeof(str), "Increasing socket buffer size to %d",
        }                     bufsize);
        if (setsockopt(s, SOL_SOCKET, SO_SNDBUF, &opt, sizeof(opt)) < 0) {            warning(str);
            i_errno = IESETBUF;            test->settings->socket_bufsize = bufsize;
            return -1;            rc = iperf_udp_buffercheck(test, s);
        }            if (rc < 0)
                 return rc;
         }
     }      }
   
 #if defined(HAVE_SO_MAX_PACING_RATE)  #if defined(HAVE_SO_MAX_PACING_RATE)
     /* If socket pacing is available and not disabled, try it. */      /* If socket pacing is available and not disabled, try it. */
    if (! test->no_fq_socket_pacing) {    if (test->settings->fqrate) {
         /* Convert bits per second to bytes per second */          /* Convert bits per second to bytes per second */
        unsigned int rate = test->settings->rate / 8;        unsigned int fqrate = test->settings->fqrate / 8;
        if (rate > 0) {        if (fqrate > 0) {
             if (test->debug) {              if (test->debug) {
                printf("Setting fair-queue socket pacing to %u\n", rate);                printf("Setting fair-queue socket pacing to %u\n", fqrate);
             }              }
            if (setsockopt(s, SOL_SOCKET, SO_MAX_PACING_RATE, &rate, sizeof(rate)) < 0) {            if (setsockopt(s, SOL_SOCKET, SO_MAX_PACING_RATE, &fqrate, sizeof(fqrate)) < 0) {
                warning("Unable to set socket pacing, using application pacing instead");                warning("Unable to set socket pacing");
                test->no_fq_socket_pacing = 1; 
             }              }
         }          }
     }      }
 #endif /* HAVE_SO_MAX_PACING_RATE */  #endif /* HAVE_SO_MAX_PACING_RATE */
       {
           unsigned int rate = test->settings->rate / 8;
           if (rate > 0) {
               if (test->debug) {
                   printf("Setting application pacing to %u\n", rate);
               }
           }
       }
   
       /* Set common socket options */
       iperf_common_sockopts(test, s);
   
 #ifdef SO_RCVTIMEO  #ifdef SO_RCVTIMEO
     /* 30 sec timeout for a case when there is a network problem. */      /* 30 sec timeout for a case when there is a network problem. */
     tv.tv_sec = 30;      tv.tv_sec = 30;
Line 371  iperf_udp_connect(struct iperf_test *test) Line 587  iperf_udp_connect(struct iperf_test *test)
      * Write a datagram to the UDP stream to let the server know we're here.       * Write a datagram to the UDP stream to let the server know we're here.
      * The server learns our address by obtaining its peer's address.       * The server learns our address by obtaining its peer's address.
      */       */
    buf = 123456789;              /* this can be pretty much anything */    buf = UDP_CONNECT_MSG;
     if (test->debug) {
         printf("Sending Connect message to Socket %d\n", s);
     }
     if (write(s, &buf, sizeof(buf)) < 0) {      if (write(s, &buf, sizeof(buf)) < 0) {
        // XXX: Should this be changed to IESTREAMCONNECT?         // XXX: Should this be changed to IESTREAMCONNECT?
         i_errno = IESTREAMWRITE;          i_errno = IESTREAMWRITE;
         return -1;          return -1;
     }      }
   
     /*      /*
     * Wait until the server replies back to us.     * Wait until the server replies back to us with the "accept" response.
      */       */
    if ((sz = recv(s, &buf, sizeof(buf), 0)) < 0) {    i = 0;
     max_len_wait_for_reply = sizeof(buf);
     if (test->reverse) /* In reverse mode allow few packets to have the "accept" response - to handle out of order packets */
         max_len_wait_for_reply += MAX_REVERSE_OUT_OF_ORDER_PACKETS * test->settings->blksize;
     do {
         if ((sz = recv(s, &buf, sizeof(buf), 0)) < 0) {
             i_errno = IESTREAMREAD;
             return -1;
         }
         if (test->debug) {
             printf("Connect received for Socket %d, sz=%d, buf=%x, i=%d, max_len_wait_for_reply=%d\n", s, sz, buf, i, max_len_wait_for_reply);
         }
         i += sz;
     } while (buf != UDP_CONNECT_REPLY && buf != LEGACY_UDP_CONNECT_REPLY && i < max_len_wait_for_reply);
 
     if (buf != UDP_CONNECT_REPLY  && buf != LEGACY_UDP_CONNECT_REPLY) {
         i_errno = IESTREAMREAD;          i_errno = IESTREAMREAD;
         return -1;          return -1;
     }      }

Removed from v.1.1  
changed lines
  Added in v.1.1.1.3


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