TOMOYO Linux Cross Reference
Linux/tools/testing/selftests/net/mptcp/simult_flows.sh

   #!/bin/bash
   # SPDX-License-Identifier: GPL-2.0
   
   # Double quotes to prevent globbing and word splitting is recommended in new
   # code but we accept it, especially because there were too many before having
   # address all other issues detected by shellcheck.
   #shellcheck disable=SC2086
   
   . "$(dirname "${0}")/mptcp_lib.sh"
  
  ns1=""
  ns2=""
  ns3=""
  capture=false
  timeout_poll=30
  timeout_test=$((timeout_poll * 2 + 1))
  # a bit more space: because we have more to display
  MPTCP_LIB_TEST_FORMAT="%02u %-60s"
  ret=0
  bail=0
  slack=50
  large=""
  small=""
  sout=""
  cout=""
  capout=""
  size=0
  
  usage() {
          echo "Usage: $0 [ -b ] [ -c ] [ -d ] [ -i]"
          echo -e "\t-b: bail out after first error, otherwise runs al testcases"
          echo -e "\t-c: capture packets for each test using tcpdump (default: no capture)"
          echo -e "\t-d: debug this script"
          echo -e "\t-i: use 'ip mptcp' instead of 'pm_nl_ctl'"
  }
  
  # This function is used in the cleanup trap
  #shellcheck disable=SC2317
  cleanup()
  {
          rm -f "$cout" "$sout"
          rm -f "$large" "$small"
          rm -f "$capout"
  
          mptcp_lib_ns_exit "${ns1}" "${ns2}" "${ns3}"
  }
  
  mptcp_lib_check_mptcp
  mptcp_lib_check_tools ip tc
  
  #  "$ns1"              ns2                    ns3
  #     ns1eth1    ns2eth1   ns2eth3      ns3eth1
  #            netem
  #     ns1eth2    ns2eth2
  #            netem
  
  setup()
  {
          large=$(mktemp)
          small=$(mktemp)
          sout=$(mktemp)
          cout=$(mktemp)
          capout=$(mktemp)
          size=$((2 * 2048 * 4096))
  
          dd if=/dev/zero of=$small bs=4096 count=20 >/dev/null 2>&1
          dd if=/dev/zero of=$large bs=4096 count=$((size / 4096)) >/dev/null 2>&1
  
          trap cleanup EXIT
  
          mptcp_lib_ns_init ns1 ns2 ns3
  
          ip link add ns1eth1 netns "$ns1" type veth peer name ns2eth1 netns "$ns2"
          ip link add ns1eth2 netns "$ns1" type veth peer name ns2eth2 netns "$ns2"
          ip link add ns2eth3 netns "$ns2" type veth peer name ns3eth1 netns "$ns3"
  
          ip -net "$ns1" addr add 10.0.1.1/24 dev ns1eth1
          ip -net "$ns1" addr add dead:beef:1::1/64 dev ns1eth1 nodad
          ip -net "$ns1" link set ns1eth1 up mtu 1500
          ip -net "$ns1" route add default via 10.0.1.2
          ip -net "$ns1" route add default via dead:beef:1::2
  
          ip -net "$ns1" addr add 10.0.2.1/24 dev ns1eth2
          ip -net "$ns1" addr add dead:beef:2::1/64 dev ns1eth2 nodad
          ip -net "$ns1" link set ns1eth2 up mtu 1500
          ip -net "$ns1" route add default via 10.0.2.2 metric 101
          ip -net "$ns1" route add default via dead:beef:2::2 metric 101
  
          mptcp_lib_pm_nl_set_limits "${ns1}" 1 1
          mptcp_lib_pm_nl_add_endpoint "${ns1}" 10.0.2.1 dev ns1eth2 flags subflow
  
          ip -net "$ns2" addr add 10.0.1.2/24 dev ns2eth1
          ip -net "$ns2" addr add dead:beef:1::2/64 dev ns2eth1 nodad
          ip -net "$ns2" link set ns2eth1 up mtu 1500
  
          ip -net "$ns2" addr add 10.0.2.2/24 dev ns2eth2
          ip -net "$ns2" addr add dead:beef:2::2/64 dev ns2eth2 nodad
          ip -net "$ns2" link set ns2eth2 up mtu 1500
  
         ip -net "$ns2" addr add 10.0.3.2/24 dev ns2eth3
         ip -net "$ns2" addr add dead:beef:3::2/64 dev ns2eth3 nodad
         ip -net "$ns2" link set ns2eth3 up mtu 1500
         ip netns exec "$ns2" sysctl -q net.ipv4.ip_forward=1
         ip netns exec "$ns2" sysctl -q net.ipv6.conf.all.forwarding=1
 
         ip -net "$ns3" addr add 10.0.3.3/24 dev ns3eth1
         ip -net "$ns3" addr add dead:beef:3::3/64 dev ns3eth1 nodad
         ip -net "$ns3" link set ns3eth1 up mtu 1500
         ip -net "$ns3" route add default via 10.0.3.2
         ip -net "$ns3" route add default via dead:beef:3::2
 
         mptcp_lib_pm_nl_set_limits "${ns3}" 1 1
 
         # debug build can slow down measurably the test program
         # we use quite tight time limit on the run-time, to ensure
         # maximum B/W usage.
         # Use kmemleak/lockdep/kasan/prove_locking presence as a rough
         # estimate for this being a debug kernel and increase the
         # maximum run-time accordingly. Observed run times for CI builds
         # running selftests, including kbuild, were used to determine the
         # amount of time to add.
         grep -q ' kmemleak_init$\| lockdep_init$\| kasan_init$\| prove_locking$' /proc/kallsyms && slack=$((slack+550))
 }
 
 do_transfer()
 {
         local cin=$1
         local sin=$2
         local max_time=$3
         local port
         port=$((10000+MPTCP_LIB_TEST_COUNTER))
 
         :> "$cout"
         :> "$sout"
         :> "$capout"
 
         if $capture; then
                 local capuser
                 local rndh="${ns1:4}"
                 if [ -z $SUDO_USER ] ; then
                         capuser=""
                 else
                         capuser="-Z $SUDO_USER"
                 fi
 
                 local capfile="${rndh}-${port}"
                 local capopt="-i any -s 65535 -B 32768 ${capuser}"
 
                 ip netns exec ${ns3}  tcpdump ${capopt} -w "${capfile}-listener.pcap"  >> "${capout}" 2>&1 &
                 local cappid_listener=$!
 
                 ip netns exec ${ns1} tcpdump ${capopt} -w "${capfile}-connector.pcap" >> "${capout}" 2>&1 &
                 local cappid_connector=$!
 
                 sleep 1
         fi
 
         timeout ${timeout_test} \
                 ip netns exec ${ns3} \
                         ./mptcp_connect -jt ${timeout_poll} -l -p $port -T $max_time \
                                 0.0.0.0 < "$sin" > "$sout" &
         local spid=$!
 
         mptcp_lib_wait_local_port_listen "${ns3}" "${port}"
 
         timeout ${timeout_test} \
                 ip netns exec ${ns1} \
                         ./mptcp_connect -jt ${timeout_poll} -p $port -T $max_time \
                                 10.0.3.3 < "$cin" > "$cout" &
         local cpid=$!
 
         wait $cpid
         local retc=$?
         wait $spid
         local rets=$?
 
         if $capture; then
                 sleep 1
                 kill ${cappid_listener}
                 kill ${cappid_connector}
         fi
 
         cmp $sin $cout > /dev/null 2>&1
         local cmps=$?
         cmp $cin $sout > /dev/null 2>&1
         local cmpc=$?
 
         printf "%-16s" " max $max_time "
         if [ $retc -eq 0 ] && [ $rets -eq 0 ] && \
            [ $cmpc -eq 0 ] && [ $cmps -eq 0 ]; then
                 mptcp_lib_pr_ok
                 cat "$capout"
                 return 0
         fi
 
         mptcp_lib_pr_fail
         echo "client exit code $retc, server $rets" 1>&2
         echo -e "\nnetns ${ns3} socket stat for $port:" 1>&2
         ip netns exec ${ns3} ss -nita 1>&2 -o "sport = :$port"
         echo -e "\nnetns ${ns1} socket stat for $port:" 1>&2
         ip netns exec ${ns1} ss -nita 1>&2 -o "dport = :$port"
         ls -l $sin $cout
         ls -l $cin $sout
 
         cat "$capout"
         return 1
 }
 
 run_test()
 {
         local rate1=$1
         local rate2=$2
         local delay1=$3
         local delay2=$4
         local lret
         local dev
         shift 4
         local msg=$*
 
         [ $delay1 -gt 0 ] && delay1="delay ${delay1}ms" || delay1=""
         [ $delay2 -gt 0 ] && delay2="delay ${delay2}ms" || delay2=""
 
         for dev in ns1eth1 ns1eth2; do
                 tc -n $ns1 qdisc del dev $dev root >/dev/null 2>&1
         done
         for dev in ns2eth1 ns2eth2; do
                 tc -n $ns2 qdisc del dev $dev root >/dev/null 2>&1
         done
         tc -n $ns1 qdisc add dev ns1eth1 root netem rate ${rate1}mbit $delay1
         tc -n $ns1 qdisc add dev ns1eth2 root netem rate ${rate2}mbit $delay2
         tc -n $ns2 qdisc add dev ns2eth1 root netem rate ${rate1}mbit $delay1
         tc -n $ns2 qdisc add dev ns2eth2 root netem rate ${rate2}mbit $delay2
 
         # time is measured in ms, account for transfer size, aggregated link speed
         # and header overhead (10%)
         #              ms    byte -> bit   10%        mbit      -> kbit -> bit  10%
         local time=$((1000 * size  *  8  * 10 / ((rate1 + rate2) * 1000 * 1000 * 9) ))
 
         # mptcp_connect will do some sleeps to allow the mp_join handshake
         # completion (see mptcp_connect): 200ms on each side, add some slack
         time=$((time + 400 + slack))
 
         mptcp_lib_print_title "$msg"
         do_transfer $small $large $time
         lret=$?
         mptcp_lib_result_code "${lret}" "${msg}"
         if [ $lret -ne 0 ] && ! mptcp_lib_subtest_is_flaky; then
                 ret=$lret
                 [ $bail -eq 0 ] || exit $ret
         fi
 
         msg+=" - reverse direction"
         mptcp_lib_print_title "${msg}"
         do_transfer $large $small $time
         lret=$?
         mptcp_lib_result_code "${lret}" "${msg}"
         if [ $lret -ne 0 ] && ! mptcp_lib_subtest_is_flaky; then
                 ret=$lret
                 [ $bail -eq 0 ] || exit $ret
         fi
 }
 
 while getopts "bcdhi" option;do
         case "$option" in
         "h")
                 usage $0
                 exit ${KSFT_PASS}
                 ;;
         "b")
                 bail=1
                 ;;
         "c")
                 capture=true
                 ;;
         "d")
                 set -x
                 ;;
         "i")
                 mptcp_lib_set_ip_mptcp
                 ;;
         "?")
                 usage $0
                 exit ${KSFT_FAIL}
                 ;;
         esac
 done
 
 setup
 mptcp_lib_subtests_last_ts_reset
 run_test 10 10 0 0 "balanced bwidth"
 run_test 10 10 1 25 "balanced bwidth with unbalanced delay"
 
 # we still need some additional infrastructure to pass the following test-cases
 MPTCP_LIB_SUBTEST_FLAKY=1 run_test 10 3 0 0 "unbalanced bwidth"
 run_test 10 3 1 25 "unbalanced bwidth with unbalanced delay"
 run_test 10 3 25 1 "unbalanced bwidth with opposed, unbalanced delay"
 
 mptcp_lib_result_print_all_tap
 exit $ret

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