Provided by: iperf_2.1.9+dfsg-1_amd64 bug

NAME

       iperf  -  perform  network traffic tests using network sockets. Metrics include throughput
       and latency or link capacity and responsiveness.

SYNOPSIS

       iperf -s [options]

       iperf -c server [options]

       iperf -u -s [options]

       iperf -u -c server [options]

DESCRIPTION

       iperf 2 is a testing tool  which  performs  network  traffic  measurements  using  network
       sockets.  The  performance  metrics  supported  include  throughput  and  latency (or link
       capacity and responsiveness.) Latency measurements include both one way  delay  (OWD)  and
       round  trip  times  (RTTs.)  Iperf  can  use  both  TCP and UDP sockets (or protocols.) It
       supports unidirectional, full duplex (same socket) and bidirectional traffic, and supports
       multiple,  simultaneous  traffic  streams.  It supports multicast traffic including source
       specific multicast (SSM) joins. Its multi-threaded design  allows  for  peak  performance.
       Metrics  displayed  help  to  characterize  host  to host network performance. Setting the
       enhanced (-e) option provides all available metrics. Note: the metrics are at  the  socket
       level  reads  and  writes.  They  do  not include the overhead associated with lower level
       protocol layer headers.

       The user must establish both a server (to receive traffic) and a client (to  generate  and
       send traffic) for a test to occur.  The client and server typically are on different hosts
       or computers but need not be.

GENERAL OPTIONS

       -b, --bandwidth
              set the target bandwidth and optional standard deviation per <mean>,[<stdev>]  (See
              NOTES for suffixes)

       -e, --enhanced
              Display  enhanced  output  in  reports  otherwise  use  legacy  report  (ver 2.0.5)
              formatting (see NOTES)

       -f, --format [abkmgBKMG]
              format to report: adaptive, bits,  Bytes,  Kbits,  Mbits,  Gbits,  KBytes,  MBytes,
              GBytes (see NOTES for more)

       -h, --help
              print a help synopsis

           --hide-ips
              obscure  ip  addresses  in  output  (useful when wanting to publish results and not
              display the full ip addresses. v4 only)

       -i, --interval < t | f >
              sample or display interval reports every t seconds  (default)  or  every  frame  or
              burst,  i.e.  if f is used then the interval will be each frame or burst. The frame
              interval reporting is experimental.  Also suggest  a  compile  with  fast-sampling,
              i.e. ./configure --enable-fastsampling

       -l, --len n[kmKM]
              set  read/write  buffer  size  (TCP)  or  length  (UDP) to n (TCP default 128K, UDP
              default 1470)

           --l2checks
              perform layer 2 length checks  on  received  UDP  packets  (requires  systems  that
              support packet sockets, e.g. Linux)

       -m, --print_mss
              print TCP maximum segment size

           --NUM_REPORT_STRUCTS <count>
              Override  the default shared memory size between the traffic thread(s) and reporter
              thread in order to mitigate mutex lock  contentions.  The  default  value  of  5000
              should  be  sufficient  for  1Gb/s  networks. Increase this upon seeing the Warning
              message of reporter thread too slow.  If  the  Warning  message  isn't  seen,  then
              increasing  this  won't  have  any  significant  effect  (other  than  to  use some
              additional memory.)

       -o, --output filename
              output the report or error message to this specified file

           --permit-key [=<value>]
              Set a key value that must match for the server to accept traffic on  a  connection.
              If  the  option  is  given  without  a  value  on  the  server  a key value will be
              autogenerated and displayed in its initial settings report. The lifetime of the key
              is  set  using  --permit-key-timeout  and  defaults to twenty seconds. The value is
              required on clients. The value will also be used as part  of  the  transfer  id  in
              reports. The option set on the client but not the server will also cause the server
              to reject the client's traffic. TCP only, no UDP support.

       -p, --port m[-n]
              set client or server port(s) to send or listen on per m (default  5001)  w/optional
              port range per m-n (e.g. -p 6002-6008) (see NOTES)

           --sum-dstip
              sum  traffic  threads  based  upon the destination IP address (default is source ip
              address)

           --sum-only
              set the output to sum reports only. Useful for -P at large values

       -t, --time n
              time in seconds to listen for new traffic  connections,  receive  traffic  or  send
              traffic

       -u, --udp
              use UDP rather than TCP

           --utc
              use  coordinated  universal  time  (UTC)  when outputting time (otherwise use local
              time)

       -w, --window n[kmKM]
              TCP window size (socket buffer size)

       -z, --realtime
              Request real-time scheduler, if supported.

       -B, --bind host[:port][%dev]
              bind to host, ip address or multicast address, optional port or device (see NOTES)

       -C, --compatibility
              for use with older versions does not sent extra msgs

       -M, --mss n
              set TCP maximum segment size using TCP_MAXSEG

       -N, --nodelay
              set TCP no delay, disabling Nagle's Algorithm

       -v, --version
              print version information and quit

       -x, --reportexclude [CDMSV]
              exclude C(connection) D(data) M(multicast) S(settings) V(server) reports

       -y, --reportstyle C|c
              if set to C or c report results as CSV (comma separated values)

       -Z, --tcp-congestion
              Set the default congestion-control  algorithm  to  be  used  for  new  connections.
              Platforms   must  support  setsockopt's  TCP_CONGESTION.  (Notes:  See  sysctl  and
              tcp_allowed_congestion_control for available options. May require root privileges.)

SERVER SPECIFIC OPTIONS

       -1, --singleclient
              set the server to process only one client at a time

       -b, --bandwidth n[kmgKMG]
              set target read rate to n bits/sec. TCP only for the server.

       -s, --server
              run in server mode

           --histograms[=binwidth[u],bincount,[lowerci],[upperci]]
              enable latency histograms for udp packets (-u), for tcp writes (with --trip-times),
              or  for  either  udp  or  tcp  with --isochronous clients, or for --bounceback. The
              binning  can  be  modified.  Bin  widths  (default  1  millisecond,  append  u  for
              microseconds,  m  for  milliseconds)  bincount  is total bins (default 1000), ci is
              confidence interval between 0-100% (default lower 5%, upper 95%, 3 stdev 99.7%)

           --jitter-histograms[=<binwidth>]
              enable jitter histograms for udp packets (-u). Optional  value  is  the  bin  width
              where units are microseconds and defaults to 100 usecs

           --permit-key [=<value>]
              Set  a  key  value  that  must match for the server to accept traffic from a client
              (also set with --permit-key.) The server will auto-generate a globally  unique  key
              when  the  option  is  given  without  a value. This value will be displayed in the
              server's  initial  settings  report.  The  lifetime  of  the  key  is   set   using
              --permit-key-timeout and defaults to twenty seconds. TCP only, no UDP support.

           --permit-key-timeout <value>
              Set the lifetime of the permit key in seconds. Defaults to 20 seconds if not set. A
              value of zero will disable the timer.

           --tap-dev <dev>
              Set the receive interface to the TAP device as specified.

           --tcp-rx-window-clamp n[kmKM]
              Set the socket option of TCP_WINDOW_CLAMP, units is bytes.

       -t, --time n
              time in seconds to listen  for  new  traffic  connections  and/or  receive  traffic
              (defaults to infinite)

           --tos-override <val>
              set  the  socket's  IP_TOS  value  for reverse or full duplex traffic. Supported in
              versions 2.1.5 or greater. Previous versions won't set IP_TOS on  reverse  traffic.
              See NOTES for values.

       -B, --bind ip | ip%device
              bind src ip addr and optional src device for receiving

       -D, --daemon
              run  the  server  as  a daemon. On Windows this will run the specified command-line
              under the IPerfService, installing the service if necessary. Note  the  service  is
              not  configured  to auto-start or restart - if you need a self-starting service you
              will need to create an init script or use Windows "sc" commands.

       -H, --ssm-host host
              Set the source host (ip addr) per SSM multicast, i.e. the S of the S,G

       -R, --remove
              remove the IPerfService (Windows only).

       -U, --single_udp
              run in single threaded UDP mode

       -V, --ipv6_domain
              Enable IPv6 reception by setting the domain and socket to AF_INET6 (Can receive  on
              both IPv4 and IPv6)

CLIENT SPECIFIC OPTIONS

       -b, --bandwidth n[kmgKMG][,n[kmgKMG]] | n[kmgKMG]pps
              set  target bandwidth to n bits/sec (default 1 Mbit/sec) or n packets per sec. This
              may be used with TCP  or  UDP.  Optionally,  for  variable  loads,  use  format  of
              mean,standard deviation

           --bounceback[=n]
              run  a  TCP bounceback or rps test with optional number writes in a burst per value
              of n. The default is ten writes every period and the default period is  one  second
              (Note: set size with -l or --len which defaults to 100 bytes)

           --bounceback-hold n
              request  the  server to insert a delay of n milliseconds between its read and write
              (default is no delay)

           --bounceback-period[=n]
              request the client schedule its send(s) every n seconds (default is one second, use
              zero value for immediate or continuous back to back)

           --bounceback-no-quickack
              request  the  server  not  set  the  TCP_QUICKACK  socket option (disabling TCP ACK
              delays) during a bounceback test (see NOTES)

           --bounceback-txdelay n
              request the client to delay n seconds between the start of the working load and the
              bounceback traffic (default is no delay)

           --burst-period n
              Set the burst period in seconds. Defaults to one second. (Note: assumed use case is
              low duty cycle traffic bursts)

           --burst-size n
              Set the burst size in bytes. Defaults to 1M if no value  is  given.   -c,  --client
              host  | host%device run in client mode, connecting to host  where the optional %dev
              will SO_BINDTODEVICE that output interface (requires root and see NOTES)

           --connect-only[=n]
              only perform a TCP connect (or 3WHS) without any data transfer, useful  to  measure
              TCP  connect()  times.  Optional  value  of n is the total number of connects to do
              (zero is run forever.) Note that -i will rate limit  the  connects  where  -P  will
              create bursts and -t will end the client and hence end its connect attempts.

           --connect-retries[= n]
              number  of  times  to  retry a TCP connect at the application level.  See operating
              system information on the details of TCP connect related settings.

       -d, --dualtest
              Do a bidirectional test simultaneous test using two unidirectional sockets

           --fq-rate n[kmgKMG]
              Set a rate to be used with fair-queuing based socket-level pacing, in bytes or bits
              per  second.  Only  available on platforms supporting the SO_MAX_PACING_RATE socket
              option. (Note: Here  the  suffixes  indicate  bytes/sec  or  bits/sec  per  use  of
              uppercase or lowercase, respectively)

           --full-duplex
              run  a full duplex test, i.e. traffic in both transmit and receive directions using
              the same socket

           --histograms[=binwidth[u],bincount,[lowerci],[upperci]]
              enable select()/write() histograms with --tcp-write-times  or  --bounceback  (these
              options  are  mutually exclusive.) The binning can be modified. Bin widths (default
              100 microseconds, append u for microseconds, m for milliseconds) bincount is  total
              bins  (default  10000), ci is confidence interval between 0-100% (default lower 5%,
              upper 95%, 3 stdev 99.7%)

           --incr-dstip
              increment the destination ip address when using the parallel  (-P)  or  port  range
              option

           --incr-dstport
              increment the destination port when using the parallel (-P) or port range option

           --incr-srcip
              increment the source ip address when using the parallel (-P) or port range option

           --incr-srcport
              increment  the source ip address when using the parallel (-P) or port range option,
              requires -B to set the src port

           --ipg n
              set the inter-packet  gap  to  n  (units  of  seconds)  for  packets  or  within  a
              frame/burst when --isochronous is set

           --isochronous[=fps:mean,stdev]
              send  isochronous traffic with frequency frames per second and load defined by mean
              and standard deviation using a  log  normal  distribution,  defaults  to  60:20m,0.
              (Note:  Here  the  suffixes  indicate bytes/sec or bits/sec per use of uppercase or
              lowercase, respectively. Also the p suffix is supported to set the  burst  size  in
              packets, e.g. isochronous=2:25p will send two 25 packet bursts every second, or one
              25 packet burst every 0.5 seconds.)

           --local-only[=1|0]
              Set 1 to limit traffic to the local network only (through the use of  SO_DONTROUTE)
              set to zero otherwise with optional override of compile time default (see configure
              --default-localonly)

           --near-congestion[=n]
              Enable TCP write rate limiting per the sampled RTT. The delay is applied after  the
              -l  number of bytes have completed. The optional value is the multiplier to the RTT
              and defines the time delay. This value defaults to 0.5 if it  is  not  set.  Values
              less than 1 are supported but the value cannot be negative. This is an experimental
              feature. It is not likely stable on live networks. Suggested use is over controlled
              test networks.

           --no-connect-sync
              By default, parallel traffic threads (per -P greater than 1) will synchronize after
              their TCP connects and prior to each sending traffic, i.e. all  the  threads  first
              complete (or error) the TCP 3WHS before any traffic thread will start sending. This
              option disables that synchronization such  that  each  traffic  thread  will  start
              sending immediately after completing its successful connect.

           --no-udp-fin
              Don't  perform the UDP final server to client exchange which means there won't be a
              final server report displayed on the client. All packets per the test will be  from
              the  client  to  the  server  and no packets should be sent in the other direction.
              It's highly suggested that -t be set on the server if this option  is  being  used.
              This  is  because  there will be only one trigger ending packet sent from client to
              server and if it's lost then the server will continue to run. (Requires ver  2.0.14
              or better)

       -n, --num n[kmKM]
              number of bytes to transmit (instead of -t)

           --permit-key [=<value>]
              Set  a key value that must match the server's value (also set with --permit-key) in
              order for the server to accept traffic from the client. TCP only, no UDP support.

       -r, --tradeoff
              Do a bidirectional test individually - client-to-server,  followed  by  a  reversed
              test, server-to-client

           --tcp-quickack
              Set TCP_QUICKACK on the socket

           --tcp-write-prefetch n[kmKM]
              Set  TCP_NOTSENT_LOWAT on the socket and use event based writes per select() on the
              socket.

           --tcp-write-times
              Measure the socket write times

       -t, --time n|0
              time in seconds to transmit traffic, use zero for infinite (default is 10 secs)

           --trip-times
              enable the measurement of end to end write to read  latencies  (client  and  server
              clocks must be synchronized.) See notes about tcp-write-prefetch being enabled.

           --txdelay-time
              time in seconds to hold back or delay after the TCP connect and prior to the socket
              writes. For UDP it's the delay between the traffic thread starting  and  the  first
              write.

           --txstart-time n.n
              set  the  txstart-time to n.n using unix or epoch time format (supports microsecond
              resolution, e.g 1536014418.123456) An example to delay  one  second  using  command
              substitution is iperf -c 192.168.1.10 --txstart-time $(expr $(date +%s) + 1).$(date
              +%N)

       -B, --bind ip | ip:port | ipv6 -V | [ipv6]:port -V
              bind src ip addr and optional port as the source of traffic (see NOTES)

       -F, --fileinput name
              input the data to be transmitted from a file

       -I, --stdin
              input the data to be transmitted from stdin

       -L, --listenport n
              port to receive bidirectional tests back on

       -P, --parallel n
              number of parallel client threads to run

       -R, --reverse
              reverse the traffic flow (useful for testing through firewalls, see NOTES)

       -S, --tos <val>
              set the socket's IP_TOS value. Versions 2.1.5 or  greater  will  reflect  this  tos
              setting  back  with --reverse or --full-duplex option. (Previous versions won't set
              tos on the reverse traffic.) Note: use server side --tos-override to override.  See
              NOTES for values.

       -T, --ttl n
              time-to-live, for multicast (default 1)

           --working-load[=up|down|bidir][,n]
              request a concurrent working load, currently TCP stream(s), defaults to full duplex
              (or bidir) unless the up or down option is provided.  The  number  of  TCP  streams
              defaults  to  1 and can be changed via the n value, e.g. --working-load=down,4 will
              use four TCP streams from server to the client as the working load. The IP ToS will
              be BE (0x0) for working load traffic.

       -V, --ipv6_domain
              Set the domain to IPv6 (send packets over IPv6)

       -X, --peerdetect
              run peer version detection prior to traffic.

       -Z, --linux-congestion algo
              set TCP congestion control algorithm (Linux only)

EXAMPLES

       TCP tests (client)

       iperf -c <host> -e -i 1
       ------------------------------------------------------------
       Client connecting to <host>, TCP port 5001 with pid 5149
       Write buffer size:  128 KByte
       TCP window size:  340 KByte (default)
       ------------------------------------------------------------
       [  3] local 45.56.85.133 port 49960 connected with 45.33.58.123 port 5001 (ct=3.23 ms)
       [   ID]   Interval          Transfer      Bandwidth         Write/Err   Rtry      Cwnd/RTT
       NetPwr
       [  3] 0.00-1.00 sec   126 MBytes   1.05  Gbits/sec   1006/0           0        56K/626  us
       210636.47
       [   3]  1.00-2.00  sec    138  MBytes  1.15 Gbits/sec  1100/0        299      483K/3884 us
       37121.32
       [  3] 2.00-3.00 sec   137 MBytes  1.15  Gbits/sec   1093/0          24       657K/5087  us
       28162.31
       [   3]  3.00-4.00  sec    126  MBytes  1.06 Gbits/sec  1010/0        284      294K/2528 us
       52366.58
       [  3] 4.00-5.00 sec   117 MBytes    980  Mbits/sec   935/0         373       487K/2025  us
       60519.66
       [   3]  5.00-6.00  sec    144  MBytes  1.20 Gbits/sec  1149/0          2      644K/3570 us
       42185.36
       [  3] 6.00-7.00 sec   126 MBytes  1.06  Gbits/sec   1011/0         112       582K/5281  us
       25092.56
       [   3]  7.00-8.00  sec    110  MBytes    922 Mbits/sec  879/0         56      279K/1957 us
       58871.89
       [  3] 8.00-9.00 sec   127 MBytes  1.06  Gbits/sec   1014/0          46       483K/3372  us
       39414.89
       [   3]  9.00-10.00  sec    132 MBytes  1.11 Gbits/sec  1054/0          0      654K/3380 us
       40872.75
       [  3] 0.00-10.00 sec  1.25 GBytes  1.07 Gbits/sec  10251/0        1196        -1K/3170  us
       42382.03

       where (per -e,)
              ct= TCP connect time (or three way handshake time 3WHS)
              Write/Err  Total  number  of  successful  socket  writes. Total number of non-fatal
              socket write errors
              Rtry Total number of TCP retries
              Cwnd/RTT (*nix only) TCP congestion window and round trip time  (sampled  where  NA
              indicates no value)
              NetPwr (*nix only) Network power defined as (throughput / RTT)

       iperf -c host.doamin.com -i 1 --bounceback --permit-key=mytest --hide-ips
       ------------------------------------------------------------
       Client connecting to (**hidden**), TCP port 5001
       Bursting:  100 Byte writes 10 times every 1.00 second(s)
       Bounce-back test (size= 100 Byte) (server hold req=0 usecs)
       TCP window size: 16.0 KByte (default)
       ------------------------------------------------------------
       [mytest(1)]   local   *.*.*.96   port   38044  connected  with  *.*.*.123  port  5001  (bb
       len/hold=100/0) (icwnd/mss/irtt=14/1448/10605)
       [ ID] Interval        Transfer    Bandwidth         BB cnt=avg/min/max/stdev          Rtry
       Cwnd/RTT    RPS
       [mytest(1)]  0.00-1.00 sec  1.95 KBytes  16.0 Kbits/sec    10=11.949/9.662/19.597/3.127 ms
       0   14K/10930 us    83 rps
       [mytest(1)] 1.00-2.00 sec  1.95 KBytes  16.0 Kbits/sec    10=10.004/9.651/10.322/0.232  ms
       0   14K/10244 us    99 rps
       [mytest(1)]  2.00-3.00 sec  1.95 KBytes  16.0 Kbits/sec    10=10.582/9.720/14.831/1.573 ms
       0   14K/10352 us    94 rps
       [mytest(1)] 3.00-4.00 sec  1.95 KBytes  16.0 Kbits/sec    10=11.303/9.940/15.114/2.026  ms
       0   14K/10832 us    88 rps
       [mytest(1)]  4.00-5.00 sec  1.95 KBytes  16.0 Kbits/sec    10=11.148/9.671/14.803/1.837 ms
       0   14K/10858 us    89 rps
       [mytest(1)] 5.00-6.00 sec  1.95 KBytes  16.0 Kbits/sec    10=10.207/9.695/10.729/0.356  ms
       0   14K/10390 us    97 rps
       [mytest(1)]  6.00-7.00 sec  1.95 KBytes  16.0 Kbits/sec    10=10.871/9.770/14.387/1.547 ms
       0   14K/10660 us    91 rps
       [mytest(1)] 7.00-8.00 sec  1.95 KBytes  16.0 Kbits/sec    10=11.224/9.760/14.993/1.837  ms
       0   14K/11027 us    89 rps
       [mytest(1)]  8.00-9.00 sec  1.95 KBytes  16.0 Kbits/sec    10=10.719/9.887/14.553/1.455 ms
       0   14K/10620 us    93 rps
       [mytest(1)] 9.00-10.00 sec  1.95 KBytes  16.0 Kbits/sec    10=10.775/9.689/14.746/1.562 ms
       0   14K/10596 us    92 rps
       [mytest(1)]  0.00-10.02  sec  19.5 KBytes  16.0 Kbits/sec    100=10.878/9.651/19.597/1.743
       ms    0   14K/11676 us    91 rps
       [  1] 0.00-10.02 sec BB8(f)-PDF: bin(w=100us): cnt(100)=97:  5,98:  8,99:  10,100:  8,101:
       12,102:  10,103:  6,104:  7,105:  2,106:  2,107: 3,108: 3,109: 2,110: 1,114: 1,115: 1,118:
       1,120: 2,121: 1,124: 1,125: 1,128: 1,140: 1,143: 1,144: 1,146: 2,148: 1,149: 2,150: 1,151:
       1,152: 1,196: 1 (5.00/95.00/99.7%=97/149/196,Outliers=0,obl/obu=0/0)

       where  BB  cnt=avg/min/max/stdev Count of bouncebacks, average time, minimum time, maximum
              time, standard deviation units of ms
              Rtry Total number of TCP retries
              Cwnd/RTT (*nix only) TCP congestion window and round trip time  (sampled  where  NA
              indicates no value)
              RPS Responses per second

       TCP tests (server)

       iperf -s -e -i 1 -l 8K
       ------------------------------------------------------------
       Server listening on TCP port 5001 with pid 13430
       Read buffer size: 8.00 KByte
       TCP window size: 85.3 KByte (default)
       ------------------------------------------------------------
       [  4] local 45.33.58.123 port 5001 connected with 45.56.85.133 port 49960
       [ ID] Interval        Transfer    Bandwidth       Reads   Dist(bin=1.0K)
       [       4]      0.00-1.00      sec       124     MBytes      1.04     Gbits/sec      22249
       798:2637:2061:767:2165:1563:589:11669
       [      4]     1.00-2.00     sec       136     MBytes       1.14      Gbits/sec       24780
       946:3227:2227:790:2427:1888:641:12634
       [       4]      2.00-3.00      sec       137     MBytes      1.15     Gbits/sec      24484
       1047:2686:2218:810:2195:1819:728:12981
       [      4]     3.00-4.00     sec       126     MBytes       1.06      Gbits/sec       20812
       863:1353:1546:614:1712:1298:547:12879
       [       4]      4.00-5.00      sec       117     MBytes       984     Mbits/sec      20266
       769:1886:1828:589:1866:1350:476:11502
       [      4]     5.00-6.00     sec       143     MBytes       1.20      Gbits/sec       24603
       1066:1925:2139:822:2237:1827:744:13843
       [       4]      6.00-7.00      sec       126     MBytes      1.06     Gbits/sec      22635
       834:2464:2249:724:2269:1646:608:11841
       [      4]     7.00-8.00     sec       110     MBytes        921      Mbits/sec       21107
       842:2437:2747:592:2871:1903:496:9219
       [       4]      8.00-9.00      sec       126     MBytes      1.06     Gbits/sec      22804
       1038:1784:2639:656:2738:1927:573:11449
       [      4]     9.00-10.00     sec       133     MBytes      1.11      Gbits/sec       23091
       1088:1654:2105:710:2333:1928:723:12550
       [       4]     0.00-10.02     sec      1.25     GBytes      1.07     Gbits/sec      227306
       9316:22088:21792:7096:22893:17193:6138:120790

       where (per -e,)
              Reads Total number of socket reads
              Dist(bin=size) Eight bin histogram of the socket reads  returned  byte  count.  Bin
              width  is set per size. Bins are separated by a colon. In the example, the bins are
              0-1K, 1K-2K, .., 7K-8K.

       TCP tests (server with --trip-times on client) iperf -s -i 1 -w 4M
       ------------------------------------------------------------
       Server listening on TCP port 5001
       TCP window size: 8.00 MByte (WARNING: requested 4.00 MByte)
       ------------------------------------------------------------
       [  4] local 192.168.1.4%eth0 port 5001 connected with 192.168.1.7 port 44798  (trip-times)
       (MSS=1448) (peer 2.0.14-alpha)
       [  ID] Interval        Transfer    Bandwidth    Burst Latency avg/min/max/stdev (cnt/size)
       inP NetPwr  Reads=Dist
       [   4]  0.00-1.00  sec   19.0  MBytes    159  Mbits/sec   52.314/10.238/117.155/19.779  ms
       (151/131717) 1.05 MByte 380.19  781=306:253:129:48:18:15:8:4
       [    4]  1.00-2.00  sec   20.0  MBytes    168  Mbits/sec   53.863/21.264/79.252/12.277  ms
       (160/131080) 1.08 MByte 389.38  771=294:236:126:60:18:24:10:3
       [   4]  2.00-3.00  sec   18.2  MBytes    153  Mbits/sec   58.718/22.000/137.944/20.397  ms
       (146/130964) 1.06 MByte 325.64  732=299:231:98:52:18:19:10:5
       [   4]  3.00-4.00  sec   19.7  MBytes    165  Mbits/sec   50.448/  8.921/82.728/14.627  ms
       (158/130588)  997 KByte 409.00  780=300:255:121:58:15:18:7:6
       [   4]  4.00-5.00  sec   18.8  MBytes    158  Mbits/sec   53.826/11.169/115.316/15.541  ms
       (150/131420) 1.02 MByte 366.24  761=302:226:134:52:22:17:7:1
       [    4]  5.00-6.00  sec   19.5  MBytes    164  Mbits/sec   50.943/11.922/76.134/14.053  ms
       (156/131276) 1.03 MByte 402.00  759=273:246:149:45:16:18:4:8
       [   4]  6.00-7.00  sec   18.5  MBytes    155  Mbits/sec   57.643/10.039/127.850/18.950  ms
       (148/130926) 1.05 MByte 336.16  710=262:228:133:37:16:20:8:6
       [    4]  7.00-8.00  sec   19.6  MBytes    165  Mbits/sec   52.498/12.900/77.045/12.979  ms
       (157/131003) 1.00 MByte 391.78  742=288:200:135:68:16:23:4:8
       [  4]  8.00-9.00  sec   18.0  MBytes    151  Mbits/sec   58.370/  8.026/150.243/21.445  ms
       (144/131255) 1.06 MByte 323.81  716=268:241:108:51:20:17:8:3
       [   4]  9.00-10.00  sec   18.4  MBytes    154  Mbits/sec   56.112/12.419/79.790/13.668  ms
       (147/131194) 1.05 MByte 343.70  822=330:303:120:26:16:14:9:4
       [  4]  10.00-10.06  sec   1.03  MBytes    146  Mbits/sec   69.880/45.175/78.754/10.823  ms
       (9/119632) 1.74 MByte 260.40  62=26:30:5:1:0:0:0:0
       [   4]  0.00-10.06  sec    191  MBytes    159  Mbits/sec   54.183/ 8.026/150.243/16.781 ms
       (1526/131072) 1.03 MByte 366.98  7636=2948:2449:1258:498:175:185:75:48

       where (per -e,)
              Burst    Latency    One    way    TCP    write()    to    read()     latency     in
              mean/minimum/maximum/standard  deviation  format  (Note:  requires the client's and
              server's system clocks to  be  synchronized  to  a  common  reference,  e.g.  using
              precision time protocol PTP. A GPS disciplined OCXO is a recommended reference.)
              cnt Number of completed bursts received and used for the burst latency calculations
              size Average burst size in bytes (computed average and estimate only)
              inP  inP,  short  for in progress, is the average number of bytes in progress or in
              flight. This is taken from the application level write to  read  perspective.  Note
              this  is  a  mean  value.  The parenthesis value is the standard deviation from the
              mean.  (Requires --trip-times on client. See Little's law in NOTES.)
              NetPwr Network power defined as (throughput / one way latency)

       TCP tests (with one way delay sync check -X and --trip-times on the client)

       iperf -c 192.168.1.4 -X -e --trip-times -i 1 -t 2
       ------------------------------------------------------------
       Client connecting to 192.168.1.4, TCP port 5001 with pid 16762 (1 flows)
       Write buffer size: 131072 Byte
       TCP window size: 85.0 KByte (default)
       ------------------------------------------------------------
       [ 1] Clock sync check (ms): RTT/Half=(3.361/1.680) OWD-send/ack/asym=(2.246/1.115/1.131)
       [  1] local 192.168.1.1%ap0 port 47466 connected with  192.168.1.4  port  5001  (MSS=1448)
       (trip-times) (sock=3) (peer 2.1.4-master)
       [   ID]   Interval          Transfer      Bandwidth         Write/Err   Rtry      Cwnd/RTT
       NetPwr
       [  1] 0.00-1.00 sec  9.50 MBytes  79.7 Mbits/sec  77/0          0     2309K/113914 us  87
       [  1] 1.00-2.00 sec  7.12 MBytes  59.8 Mbits/sec  57/0          0     2492K/126113 us  59
       [  1] 2.00-2.42 sec   128 KBytes  2.47 Mbits/sec  2/0          0     2492K/126113 us  2
       [  1] 0.00-2.42 sec  16.8 MBytes  58.0 Mbits/sec  136/0          0     2492K/126113 us  57

       UDP tests (client)

       iperf -c <host> -e -i 1 -u -b 10m
       ------------------------------------------------------------
       Client connecting to <host>, UDP port 5001 with pid 5169
       Sending 1470 byte datagrams, IPG target: 1176.00 us (kalman adjust)
       UDP buffer size:  208 KByte (default)
       ------------------------------------------------------------
       [  3] local 45.56.85.133 port 32943 connected with 45.33.58.123 port 5001
       [ ID] Interval        Transfer     Bandwidth      Write/Err  PPS
       [  3] 0.00-1.00 sec  1.19 MBytes  10.0 Mbits/sec  852/0      851 pps
       [  3] 1.00-2.00 sec  1.19 MBytes  10.0 Mbits/sec  850/0      850 pps
       [  3] 2.00-3.00 sec  1.19 MBytes  10.0 Mbits/sec  850/0      850 pps
       [  3] 3.00-4.00 sec  1.19 MBytes  10.0 Mbits/sec  851/0      850 pps
       [  3] 4.00-5.00 sec  1.19 MBytes  10.0 Mbits/sec  850/0      850 pps
       [  3] 5.00-6.00 sec  1.19 MBytes  10.0 Mbits/sec  850/0      850 pps
       [  3] 6.00-7.00 sec  1.19 MBytes  10.0 Mbits/sec  851/0      850 pps
       [  3] 7.00-8.00 sec  1.19 MBytes  10.0 Mbits/sec  850/0      850 pps
       [  3] 8.00-9.00 sec  1.19 MBytes  10.0 Mbits/sec  851/0      850 pps
       [  3] 0.00-10.00 sec  11.9 MBytes  10.0 Mbits/sec  8504/0      850 pps
       [  3] Sent 8504 datagrams
       [  3] Server Report:
       [  3] 0.00-10.00 sec  11.9 MBytes  10.0 Mbits/sec    0.047  ms     0/  8504  (0%)   0.537/
       0.392/23.657/ 0.497 ms  850 pps  2329.37

       where (per -e,)
              Write/Err  Total  number  of  successful  socket  writes. Total number of non-fatal
              socket write errors
              PPS Transmit packet rate in packets per second

       UDP tests (server) iperf -s -i 1 -w 4M -u
       ------------------------------------------------------------
       Server listening on UDP port 5001
       Receiving 1470 byte datagrams
       UDP buffer size: 8.00 MByte (WARNING: requested 4.00 MByte)
       ------------------------------------------------------------
       [   3]  local  192.168.1.4  port  5001  connected  with  192.168.1.1  port  60027   (WARN:
       winsize=8.00 MByte req=4.00 MByte) (trip-times) (0.0) (peer 2.0.14-alpha)
       [   ID]   Interval          Transfer      Bandwidth         Jitter    Lost/Total   Latency
       avg/min/max/stdev PPS  inP NetPwr
       [  3] 0.00-1.00 sec  44.5 MBytes   373 Mbits/sec    0.071  ms  52198/83938  (62%)  75.185/
       2.367/85.189/14.430 ms 31854 pps 3.64 MByte 620.58
       [    3]  1.00-2.00  sec   44.8  MBytes    376  Mbits/sec    0.015  ms  59549/143701  (41%)
       79.609/75.603/85.757/ 1.454 ms 31954 pps 3.56 MByte 590.04
       [   3]  2.00-3.00  sec   44.5  MBytes    373  Mbits/sec    0.017  ms  59494/202975   (29%)
       80.006/75.951/88.198/ 1.638 ms 31733 pps 3.56 MByte 583.07
       [    3]  3.00-4.00  sec   44.5  MBytes    373  Mbits/sec    0.019  ms  59586/262562  (23%)
       79.939/75.667/83.857/ 1.145 ms 31767 pps 3.56 MByte 583.57
       [   3]  4.00-5.00  sec   44.5  MBytes    373  Mbits/sec    0.081  ms  59612/322196   (19%)
       79.882/75.400/86.618/ 1.666 ms 31755 pps 3.55 MByte 584.40
       [    3]  5.00-6.00  sec   44.7  MBytes    375  Mbits/sec    0.064  ms  59571/381918  (16%)
       79.767/75.571/85.339/ 1.556 ms 31879 pps 3.56 MByte 588.02
       [   3]  6.00-7.00  sec   44.6  MBytes    374  Mbits/sec    0.041  ms  58990/440820   (13%)
       79.722/75.662/85.938/ 1.087 ms 31820 pps 3.58 MByte 586.73
       [    3]  7.00-8.00  sec   44.7  MBytes    375  Mbits/sec    0.027  ms  59679/500548  (12%)
       79.745/75.704/84.731/ 1.094 ms 31869 pps 3.55 MByte 587.46
       [   3]  8.00-9.00  sec   44.3  MBytes    371  Mbits/sec    0.078  ms  59230/559499   (11%)
       80.346/75.514/94.293/ 2.858 ms 31590 pps 3.58 MByte 577.97
       [   3]  9.00-10.00  sec   44.4  MBytes    373  Mbits/sec    0.073  ms  58782/618394 (9.5%)
       79.125/75.511/93.638/ 1.643 ms 31702 pps 3.55 MByte 588.99
       [   3]  10.00-10.08  sec   3.53  MBytes    367  Mbits/sec    0.129  ms  6026/595236   (1%)
       94.967/80.709/99.685/ 3.560 ms 31107 pps 3.58 MByte 483.12
       [   3]  0.00-10.08 sec   449 MBytes   374 Mbits/sec   0.129 ms 592717/913046 (65%) 79.453/
       2.367/99.685/ 5.200 ms 31776 pps (null) 587.91

       where (per -e,)
              Latency End to end latency in mean/minimum/maximum/standard deviation format (Note:
              requires  the  client's  and  server's system clocks to be synchronized to a common
              reference, e.g. using precision time protocol PTP. A  GPS  disciplined  OCXO  is  a
              recommended reference.)
              PPS Received packet rate in packets per second
              inP  inP,  short  for in progress, is the average number of bytes in progress or in
              flight. This is taken from an application  write  to  read  perspective.  (Requires
              --trip-times on client. See Little's law in NOTES.)
              NetPwr Network power defined as (throughput / latency)

       Isochronous UDP tests (client)

       iperf -c 192.168.100.33 -u -e -i 1 --isochronous=60:100m,10m --realtime
       ------------------------------------------------------------
       Client connecting to 192.168.100.33, UDP port 5001 with pid 14971
       UDP    isochronous:    60    frames/sec    mean=    100    Mbit/s,   stddev=10.0   Mbit/s,
       Period/IPG=16.67/0.005 ms
       UDP buffer size:  208 KByte (default)
       ------------------------------------------------------------
       [  3] local 192.168.100.76 port 42928 connected with 192.168.100.33 port 5001
       [ ID] Interval        Transfer     Bandwidth      Write/Err  PPS  frames:tx/missed/slips
       [  3] 0.00-1.00 sec  12.0 MBytes   101 Mbits/sec  8615/0     8493 pps   62/0/0
       [  3] 1.00-2.00 sec  12.0 MBytes   100 Mbits/sec  8556/0     8557 pps   60/0/0
       [  3] 2.00-3.00 sec  12.0 MBytes   101 Mbits/sec  8586/0     8586 pps   60/0/0
       [  3] 3.00-4.00 sec  12.1 MBytes   102 Mbits/sec  8687/0     8687 pps   60/0/0
       [  3] 4.00-5.00 sec  11.8 MBytes  99.2 Mbits/sec  8468/0     8468 pps   60/0/0
       [  3] 5.00-6.00 sec  11.9 MBytes  99.8 Mbits/sec  8519/0     8520 pps   60/0/0
       [  3] 6.00-7.00 sec  12.1 MBytes   102 Mbits/sec  8694/0     8694 pps   60/0/0
       [  3] 7.00-8.00 sec  12.1 MBytes   102 Mbits/sec  8692/0     8692 pps   60/0/0
       [  3] 8.00-9.00 sec  11.9 MBytes   100 Mbits/sec  8537/0     8537 pps   60/0/0
       [  3] 9.00-10.00 sec  11.8 MBytes  99.0 Mbits/sec  8450/0     8450 pps   60/0/0
       [  3] 0.00-10.01 sec   120 MBytes   100 Mbits/sec  85867/0     8574 pps  602/0/0
       [  3] Sent 85867 datagrams
       [  3] Server Report:
       [  3] 0.00-9.98 sec   120 MBytes   101 Mbits/sec   0.009  ms   196/85867  (0.23%)   0.665/
       0.083/ 1.318/ 0.174 ms 8605 pps  18903.85

       where (per -e,)
              frames:tx/missed/slips  Total  number of isochronous frames or bursts. Total number
              of frame ids not sent. Total number of frame slips

       Isochronous UDP tests (server)

       iperf -s -e -u --udp-histogram=100u,2000 --realtime
       ------------------------------------------------------------
       Server listening on UDP port 5001 with pid 5175
       Receiving 1470 byte datagrams
       UDP buffer size:  208 KByte (default)
       ------------------------------------------------------------
       [  3] local 192.168.100.33 port 5001 connected with 192.168.100.76 port 42928 isoch  (peer
       2.0.13-alpha)
       [   ID]   Interval          Transfer      Bandwidth         Jitter    Lost/Total   Latency
       avg/min/max/stdev PPS  NetPwr  Frames/Lost
       [  3] 0.00-9.98 sec   120 MBytes   101 Mbits/sec   0.010  ms   196/85867  (0.23%)   0.665/
       0.083/ 1.318/ 0.284 ms 8585 pps  18903.85  601/1
       [   3]  0.00-9.98  sec  T8(f)-PDF: bin(w=100us): cnt(85671)= 1:2,2:844,3: 10034,4: 8493,5:
       8967,6:  8733,7:  8823,8:   9023,9:   8901,10:   8816,11:   7730,12:   4563,13:   741,14:1
       (5.00/95.00%=3/12,Outliers=0,obl/obu=0/0)
       [  3] 0.00-9.98 sec F8(f)-PDF: bin(w=100us): cnt(598)= 15:2,16:1,17: 27,18: 68,19: 125,20:
       136,21: 103,22: 83,23: 22,24: 23,25: 5,26: 3 (5.00/95.00%=17/24,Outliers=0,obl/obu=0/0)

       where, Frames/lost Total number of frames (or bursts) received.  Total  number  of  bursts
              lost or error-ed
              T8-PDF(f) Latency histogram for packets
              F8-PDF(f) Latency histogram for frames

ENVIRONMENT

       Note:  The  environment  variable  option  settings haven't been maintained well.  See the
              source code if these are of interest.

NOTES

       Numeric options: Some numeric options support format characters per '<value>c' (e.g.  10M)
       where the c format characters are k,m,g,K,M,G.  Lowercase format characters are 10^3 based
       and uppercase are 2^n based, e.g. 1k = 1000, 1K = 1024, 1m = 1,000,000 and 1M = 1,048,576

       Rate limiting: The -b option supports read and write  rate  limiting  at  the  application
       level.   The  -b  option  on  the  client also supports variable offered loads through the
       <mean>,<standard deviation> format, e.g.   -b  100m,10m.  The  distribution  used  is  log
       normal.  Similar  for  the isochronous option. The -b on the server rate limits the reads.
       Socket based pacing is also supported using the --fq-rate long option. This will work with
       the --reverse and --full-duplex options as well.

       IP  tos: Specifies the type-of-service or DSCP class for connections.  Accepted values are
       af11, af12, af13, af21, af22, af23, af31, af32, af33, af41, af42,  af43,  cs0,  cs1,  cs2,
       cs3,  cs4,  cs5,  cs6,  cs7,  ef,  le,  nqb,  nqb2,  ac_be, ac_bk, ac_vi, ac_vo, lowdelay,
       throughput, reliability, a numeric value, or none to use  the  operating  system  default.
       The  ac_xx  values  are  the four access categories defined in WMM for Wi-Fi, and they are
       aliases for DSCP values that will be mapped to the corresponding ACs under the  assumption
       that the device uses the DSCP-to-UP mapping table specified in IETF RFC 8325.

       --trip-times  The  --trip-times option enables many one way delay (OWD) metrics. Also note
       that using --trip-times on a TCP client will cause --tcp-write-prefetch to  be  set  to  a
       small value if tcp-write-prefetch hasn't hasn't also been set. This is done to reduce send
       side  bloat   latency   (which   is   unrelated   to   network   induced   latency.)   Set
       --tcp-write-prefetch  to  zero  to disable this (which will disable TCP_NOTSENT_LOWAT) and
       will allow for send side bloat.

       Synchronized clocks: The --trip-times option indicates  that  the  client's  and  server's
       clocks  are  synchronized to a common reference.  Network Time Protocol (NTP) or Precision
       Time Protocol (PTP) are commonly used for this.  The  reference  clock(s)  error  and  the
       synchronization protocols will affect the accuracy of any end to end latency measurements.

       Histograms  and  non-parametric  statistics: The --histograms option provides the raw data
       where nothing is averaged. This is useful for non-parametric distributions, e.g.  latency.
       The  standard  output  does  use  the  central  limit theorem to produce average, minimum,
       maximum and variation. This loses information when the  underlining  distribution  is  not
       Gaussian.  Histograms are supported so this information is made available.

       Histogram  output  interpretation:  Below  is  an  example bounceback histogram and how to
       interpret it

       [  1] 0.00-5.10 sec BB8-PDF:
       bin(w=100us): cnt(50)=35: 1,37: 1,39: 1,40: 3,41: 4,42:  1,43:  1,52:  1,57:  1,65:  1,68:
       1,69:  1,70: 1,72: 2,74: 1,75: 5,78: 1,79: 2,80: 4,81: 3,82: 1,83: 1,88: 2,90: 2,92: 1,94:
       1,117:        1,126:        1,369:        1,1000:        1,1922:         1,3710:         1
       (5.00/95.00/99.7%=39/1000/3710,Outliers=4,obl/obu=0/0)

       where, [ 1] The traffic thread number
              0.00-5.10 sec The time interval of the histogram
              BB8-PDF BB8 is the histogram name and the PDF indicates a histogram raw output
              bin(w=100us)  provides  the  bin  width.  The  bin  width  of this histogram is 100
              microseconds
              cnt(50) provides the total number of samples in the histogram. There are 50 samples
              in this histogram
              35:1  provides  the  bin no then the number of samples in that bin. Bin 35 with bin
              width 100us is 3.4 ms - 3.5 ms and there was one sample that landed there
              5.00/95.00/99.7%=39/1000/3710  provides  the  bin  confidence  intervals  (per  the
              integrated cumulative distribution function.) 5% landed in 3.9 ms or better (recall
              bin number multiplies by bin width.) 95% landed in 10 ms  or  better.  99.7%  or  3
              standards of deviation landed in 37.1 ms or better
              Outliers=4  provides the outlier count, similar to 3IQR (3 times the inter quartile
              range) but uses 10% and 90% for inner & outer fence post, then  3  times  that  for
              outlier detection.
              obl/obu=0/0  out  of  bounds  lower  and out of bands upper, provides the number of
              samples that could not be binned because the value landed outside of  all  possible
              bins

       Binding  is  done  at  the  logical level of port and ip address (or layer 3) using the -B
       option and a colon as the separator between port and the ip addr. Binding  at  the  device
       (or  layer 2) level requires the percent (%) as the delimiter (for both the client and the
       server.)  An example for src port and ip address is -B 192.168.1.1:6001. To bind  the  src
       port  only and let the operating system choose the source ip address use 0.0.0.0, e.g.  -B
       0.0.0.0:6001. On the client, the -B option affects the bind(2) system call, and  will  set
       the  source  ip  address  and the source port, e.g. iperf -c <host> -B 192.168.100.2:6002.
       This controls the packet's source values but not routing.  These can be confusing in  that
       a route or device lookup may not be that of the device with the configured source IP.  So,
       for example, if the IP address of eth0 is used for  -B  and  the  routing  table  for  the
       destination  IP  address resolves the output interface to be eth1, then the host will send
       the packet out device eth1 while using the source IP address of eth0 in  the  packet.   To
       affect  the physical output interface (e.g. dual homed systems) either use -c <host>%<dev>
       (requires root) which bypasses this host route table lookup, or configure  policy  routing
       per  each  -B  source  address  and  set  the output interface appropriately in the policy
       routes. On the server or receive, only packets destined to -B IP address will be received.
       It's  also  useful for multicast. For example, iperf -s -B 224.0.0.1%eth0 will only accept
       ip multicast packets with dest ip 224.0.0.1 that are received on the eth0 interface, while
       iperf  -s  -B  224.0.0.1  will receive those packets on any interface, Finally, the device
       specifier is required for v6 link-local, e.g. -c [v6addr]%<dev> -V, to select  the  output
       interface.

       Reverse,   full-duplex,   dualtest   (-d)  and  tradeoff  (-r):  The  --reverse  (-R)  and
       --full-duplex options can be confusing when compared to the older  options  of  --dualtest
       (-d)  and  --tradeoff (-r). The newer options of --reverse and --full-duplex only open one
       socket and read and write to the same socket descriptor,  i.e.  use  the  socket  in  full
       duplex mode.  The older -d and -r open second sockets in the opposite direction and do not
       use a socket in full duplex mode. Note that full duplex applies to the socket and  not  to
       the  network  devices  and that full duplex sockets are supported by the operating systems
       regardless if an underlying network supports full duplex transmission and reception.  It's
       suggested  to  use  --reverse  if  you  want  to  test  through  a  NAT firewall (or -R on
       non-windows systems). This applies role reversal of the test after opening the full duplex
       socket.   (Note: Firewall piercing may be required to use -d and -r if a NAT gateway is in
       the path.)

       Also, the --reverse -b <rate> setting behaves differently for TCP and UDP. For TCP it will
       rate limit the read side, i.e. the iperf client (role reversed to act as a server) reading
       from the full duplex socket.  This will in turn  flow  control  the  reverse  traffic  per
       standard TCP congestion control. The --reverse -b <rate> will be applied on transmit (i.e.
       the server role reversed to act as a client) for UDP since there is no flow  control  with
       UDP.  There  is  no  option  to directly rate limit the writes with TCP testing when using
       --reverse.

       Bounceback The bounceback test allows one to measure  network  responsiveness  (which,  in
       this  test, is an inverse of latency.)  The units are responses per second or rps. Latency
       is merely delay in units of time. Latency metrics require one to know the delay of  what's
       being  measured.  For bounceback it's a client write to a server read followed by a server
       write and then the client read. The original write is bounce backed. Iperf 2 sets  up  the
       socket  with  TCP_NODELAY  and possibly TCP_QUICKACK (unless disabled). The client sends a
       small write (which defaults to 100 bytes unless -l is set) and issues a read  waiting  for
       the  "bounceback"  from the server. The server waits for a read and then optionally delays
       before sending the payload back. This repeats until the traffic ends. Results are shown in
       units of rps and time delays.

       The  TCP_QUICKACK  socket  option  will  be  enabled  during  bounceback  tests  when  the
       bounceback-hold is set to a non-zero value. The  socket  option  is  applied  after  every
       read()  on the server and before the hold delay call. It's also applied on the client. Use
       --bounceback-no-quickack to have TCP run in default mode per the  socket  (which  is  most
       likely TCP_QUICKACK being off.)

       TCP  Connect times: The TCP connect time (or three way handshake) can be seen on the iperf
       client when the -e (--enhanced) option is set. Look for the ct=<value>  in  the  connected
       message,  e.g.in  '[  3] local 192.168.1.4 port 48736 connected with 192.168.1.1 port 5001
       (ct=1.84 ms)' shows the 3WHS took 1.84 milliseconds.

       Port-range Port ranges are supported using the hyphen notation, e.g. 6001-6009. This  will
       cause  multiple  threads,  one  per port, on either the listener/server or the client. The
       user needs to take care that the ports in the port range are available and not already  in
       use  per  the  operating  system. The -P is supported on the client and will apply to each
       destination port within the port range.  Finally, this can be used for  a  workaround  for
       Windows  UDP  and  -P  >  1 as Windows doesn't dispatch UDP per a server's connect and the
       quintuple.

       Packet per second (pps) calculation The packets  per  second  calculation  is  done  as  a
       derivative,  i.e.  number  of packets divided by time. The time is taken from the previous
       last packet to the current last packet. It is not  the  sample  interval  time.  The  last
       packet  can land at different times within an interval.  This means that pps does not have
       to match rx bytes divided by the sample interval.  Also, with --trip-times set, the packet
       time on receive is set by the sender's write time so pps indicates the end to end pps with
       --trip-times. The RX pps calculation is receive side only when -e is set and  --trip-times
       is not set.

       Little's  Law  in  queuing theory is a theorem that determines the average number of items
       (L) in a stationary queuing system based on the average waiting time (W) of an item within
       a system and the average number of items arriving at the system per unit of time (lambda).
       Mathematically, it's L = lambda * W. As used here, the units are bytes. The  arrival  rate
       is taken from the writes.

       Network  power:  The  network  power  (NetPwr)  metric is experimental. It's a convenience
       function defined as throughput/delay.  For TCP transmits, the delay  is  the  sampled  RTT
       times.   For  TCP  receives, the delay is the write to read latency.  For UDP the delay is
       the end/end latency.  Don't confuse this with  the  physics  definition  of  power  (delta
       energy/delta time) but more of a measure of a desirable property divided by an undesirable
       property. Also note, one must use -i interval with TCP to get this as that's what sets the
       RTT sampling rate. The metric is scaled to assist with human readability.

       Multicast:  Iperf  2 supports multicast with a couple of caveats. First, multicast streams
       cannot take advantage of the -P option. The server will serialize multicast streams. Also,
       it's  highly  encouraged  to use a -t on a server that will be used for multicast clients.
       That is because the single end of traffic packet sent from client to server may  get  lost
       and there are no redundant end of traffic packets.  Setting -t on the server will kill the
       server thread in the event this packet is indeed lost.

       TCP_QUICKACK: The TCP_QUICKACK socket option will be applied after  every  read()  on  the
       server such that TCP acks are sent immediately, rather than possibly delayed.

       Fast  Sampling:  Use  ./configure  --enable-fastsampling  and  then compile from source to
       enable  four  digit  (e.g.  1.0000)  precision  in   reports'   timestamps.   Useful   for
       sub-millisecond sampling.

DIAGNOSTICS

       Use  ./configure --enable-thread-debug and then compile from source to enable both asserts
       and advanced debugging of the tool itself.

BUGS

       See https://sourceforge.net/p/iperf2/tickets/

AUTHORS

       Iperf2, based from iperf (originally written by Mark Gates and  Alex  Warshavsky),  has  a
       goal  of  maintenance  with  some  feature  enhancement.   Other  contributions  from Ajay
       Tirumala, Jim Ferguson, Jon Dugan <jdugan at x1024 dot net>, Feng Qin, Kevin  Gibbs,  John
       Estabrook  <jestabro  at  ncsa.uiuc.edu>, Andrew Gallatin <gallatin at gmail.com>, Stephen
       Hemminger <shemminger at linux-foundation.org>, Tim Auckland <tim.auckland at  gmail.com>,
       Robert J. McMahon <rjmcmahon at rjmcmahon.com>

SEE ALSO

       accept(2),bind(2),close(2),connect(2),fcntl(2),getpeername(2),getsockname(2),getsockopt(2),listen(2),read(2),recv(2),select(2),send(2),setsockopt(2),shutdown(2),write(2),ip(7),socket(7),tcp(7),udp(7)

       Source code at http://sourceforge.net/projects/iperf2/

       "Unix Network Programming, Volume 1: The Sockets Networking API (3rd Edition) 3rd Edition"
       by W. Richard Stevens (Author), Bill Fenner (Author), Andrew M. Rudoff (Author)