\chapter{\label{appendixminus1}Resources and code repositories} The following sections describe how to acquire the resources to reproduce the test results. All compilations were made on Ubuntu 16.04 with kernels \begin{itemize} \item 4.15.0-54-generic (Supporting Desktop), \item 4.4.0-143-generic (BMV2 test VM) \item 4.15.0-55-generic (Desktop with NetFPGA \end{itemize} \section{\label{chapterminus1:thesis}Master Thesis} The master thesis including all self developed source code is available by git via \begin{verbatim} git clone git@gitlab.ethz.ch:nicosc/master-thesis.git \end{verbatim} It can be browsed online on \url{https://gitlab.ethz.ch/nicosc/master-thesis}. % ---------------------------------------------------------------------- \section{\label{chapterminus1:thesis}Xilinx Toolchain} A prerequisite for building the NetFGPA source code is the installation of \begin{itemize} \item \verb=Xilinx_SDNet_2018.2_1005_9= \item \verb=Xilinx_Vivado_SDK_2018.2_0614_1954= \end{itemize} Both tools need to be installed to /opt/Xilinx/, as paths are hardcoded in various places. % ---------------------------------------------------------------------- \section{\label{chapterminus1:thesis}NetFGPA support scripts} To be able to compile P4 source code to the NetFPGA the collection of scripts, Makefiles and sample code of P4-NetFGPA is required. The repository \url{git@github.com:NetFPGA/P4-NetFPGA-live.git} needs to be cloned to ``projects'' subdirectory as ``P4-NetPFGA'' of the user that wants to compile the source code. Access to the repository is granted after applying for access as described on \url{https://github.com/NetFPGA/P4-NetFPGA-public/wiki}. After that the variable \verb=P4_PROJECT_NAME= in \texttt{~/projects/P4-NetFPGA/tools/settings.sh} needs to be modified to read \verb|export P4_PROJECT_NAME=minip4| instead of \verb|export P4_PROJECT_NAME=switch_calc|. Sample code for installation: \begin{verbatim} mkdir -p ~/projects git clone git@github.com:NetFPGA/P4-NetFPGA-live.git P4-NetFPGA sed -i 's/\(P4_PROJECT_NAME=\).*/\1minip4/' ~/projects/P4-NetFPGA/tools/settings.sh \end{verbatim} % ---------------------------------------------------------------------- \chapter{\label{appendix0}BMV2 environment and tests} All BMV2 based compilations were made with the following compiler: \begin{verbatim} p4@ubuntu:~$ p4c --version p4c 0.5 (SHA: 5ae30ee) \end{verbatim} The installation is based on the vagrant files that were provided in the ``Advanced Topics in Communication Networks Fall 2018'' course of ETHZ (\url{https://adv-net.ethz.ch/2018/}) and contains p4tools as well as all utilities that came with the vagrant installation. \section{\label{chapter0:bmv2-diff}Diff based checksumming} For running the diff based checksum code, the following steps are necessary: Compiling the p4 code and starting the switch: \begin{verbatim} cd ~/master-thesis/p4app sudo p4run --config nat64-diff.json \end{verbatim} Starting the controller which sets up the required table entries: \begin{verbatim} cd ~/master-thesis/p4app sudo python ./controller.py --mode range_router \end{verbatim} % ---------------------------------------------------------------------- \chapter{\label{appendixA}NetFPGA environment and tests} \section{\label{chapterA:netpfga-setup}NetFPGA Setup} Description of installation, commit of netpfga-live \section{\label{chapterA:section1}NetFPGA NAT64 Test cases} todo: add graphic of nsg <-> esprimo cabling \begin{verbatim} ip addr add 10.0.0.42/24 dev enp2s0f0 # Adding necessary ARP entries: for the virtual IPv4 address(es) ip neigh add 10.0.0.6 lladdr f8:f2:1e:09:62:d1 dev enp2s0f0 ip neigh add 10.0.0.42 lladdr f8:f2:1e:09:62:d1 dev enp2s0f0 \end{verbatim} For all test cases the following network settings on esprimo: \begin{verbatim} 12: enp2s0f0: mtu 1500 qdisc mq state UP group default qlen 1000 link/ether f8:f2:1e:09:62:d0 brd ff:ff:ff:ff:ff:ff inet 10.0.0.42/24 scope global enp2s0f0 valid_lft forever preferred_lft forever inet6 fe80::faf2:1eff:fe09:62d0/64 scope link valid_lft forever preferred_lft forever 13: enp2s0f1: mtu 1500 qdisc mq state UP group default qlen 1000 link/ether f8:f2:1e:09:62:d1 brd ff:ff:ff:ff:ff:ff inet6 2001:db8:42::42/64 scope global valid_lft forever preferred_lft forever inet6 fe80::faf2:1eff:fe09:62d1/64 scope link valid_lft forever preferred_lft forever \end{verbatim} \subsection{Test 1: IPv4 egress settings work} Scenario: simple egress port setting for the IPv4 addresses Step 1: getting correct values for table entries from python: \begin{verbatim} >>> int(ipaddress.IPv4Address(u"10.0.0.42")) 167772202 >>> int(ipaddress.IPv4Address(u"10.0.0.4")) 167772164 >>> \end{verbatim} Step 2: setting table netries \begin{verbatim} >> table_cam_add_entry realmain_v4_networks_0 realmain.set_egress_port 167772202 => 16 0 0 0 0 fields = [(u'hit', 1), (u'action_run', 3), (u'out_port', 8), (u'out_port', 8), (u'mac_addr', 48), (u'task', 16), (u'table_id', 16)] action_name = TopPipe.realmain.set_egress_port field_vals = [1, '16', '0', '0', '0', '0'] CAM_Init_ValidateContext() - done WROTE 0x44020250 = 0xa00002a WROTE 0x44020280 = 0x0000 WROTE 0x44020284 = 0x0000 WROTE 0x44020288 = 0x10000000 WROTE 0x4402028c = 0x0001 READ 0x44020244 = 0x0001 WROTE 0x44020240 = 0x0001 READ 0x44020244 = 0x0001 READ 0x44020244 = 0x0001 success >> table_cam_add_entry realmain_v4_networks_0 realmain.set_egress_port 167772164 => 16 0 0 0 0 fields = [(u'hit', 1), (u'action_run', 3), (u'out_port', 8), (u'out_port', 8), (u'mac_addr', 48), (u'task', 16), (u'table_id', 16)] action_name = TopPipe.realmain.set_egress_port field_vals = [1, '16', '0', '0', '0', '0'] CAM_Init_ValidateContext() - done WROTE 0x44020250 = 0xa000004 WROTE 0x44020280 = 0x0000 WROTE 0x44020284 = 0x0000 WROTE 0x44020288 = 0x10000000 WROTE 0x4402028c = 0x0001 READ 0x44020244 = 0x0001 WROTE 0x44020240 = 0x0001 READ 0x44020244 = 0x0001 READ 0x44020244 = 0x0001 success >> \end{verbatim} Step 3: setting arp entries \begin{verbatim} root@ESPRIMO-P956:~# ip neigh add 10.0.0.6 lladdr f8:f2:1e:09:62:d1 dev enp2s0f0 root@ESPRIMO-P956:~# ip neigh add 10.0.0.4 lladdr f8:f2:1e:09:62:d1 dev enp2s0f0 \end{verbatim} Step 3: generating test packets, expecting 4 packets to show up on enp2s0f0: %\tvb \begin{verbatim} nico@ESPRIMO-P956:~$ sudo tcpdump -ni enp2s0f0 tcpdump: verbose output suppressed, use -v or -vv for full protocol decode listening on enp2s0f0, link-type EN10MB (Ethernet), capture size 262144 bytes 10:49:28.200407 IP 10.0.0.42 > 10.0.0.4: ICMP echo request, id 4440, seq 1, length 64 10:49:28.200445 IP 10.0.0.42 > 10.0.0.4: ICMP echo request, id 4440, seq 1, length 64 10:49:29.222340 IP 10.0.0.42 > 10.0.0.4: ICMP echo request, id 4440, seq 2, length 64 10:49:29.222418 IP 10.0.0.42 > 10.0.0.4: ICMP echo request, id 4440, seq 2, length 64 \end{verbatim} %\tve Result: sucess \subsection{Test 2: IPv6 egress} Similar to the IPv4 setting before, just for IPv6. Step 1: getting IP address values \begin{verbatim} >>> int(ipaddress.IPv6Address(u"2001:db8:42::4")) 42540766411362381960998550477184434180L >>> int(ipaddress.IPv6Address(u"2001:db8:42::6")) 42540766411362381960998550477184434182L >>> int(ipaddress.IPv6Address(u"2001:db8:42::42")) 42540766411362381960998550477184434242L \end{verbatim} Step 2: setting table entries \begin{verbatim} >> table_cam_add_entry realmain_v6_networks_0 realmain.set_egress_port 42540766411362381960998550477184434182 => 64 0 0 0 0 fields = [(u'hit', 1), (u'action_run', 3), (u'out_port', 8), (u'out_port', 8), (u'mac_addr', 48), (u'task', 16), (u'table_id', 16)] action_name = TopPipe.realmain.set_egress_port field_vals = [1, '64', '0', '0', '0', '0'] CAM_Init_ValidateContext() - done WROTE 0x44020350 = 0x0006 WROTE 0x44020354 = 0x0000 WROTE 0x44020358 = 0x420000 WROTE 0x4402035c = 0x20010db8 WROTE 0x44020380 = 0x0000 WROTE 0x44020384 = 0x0000 WROTE 0x44020388 = 0x40000000 WROTE 0x4402038c = 0x0001 READ 0x44020344 = 0x0001 WROTE 0x44020340 = 0x0001 READ 0x44020344 = 0x0001 READ 0x44020344 = 0x0001 success >> table_cam_add_entry realmain_v6_networks_0 realmain.set_egress_port 42540766411362381960998550477184434242 => 64 0 0 0 0 fields = [(u'hit', 1), (u'action_run', 3), (u'out_port', 8), (u'out_port', 8), (u'mac_addr', 48), (u'task', 16), (u'table_id', 16)] action_name = TopPipe.realmain.set_egress_port field_vals = [1, '64', '0', '0', '0', '0'] CAM_Init_ValidateContext() - done WROTE 0x44020350 = 0x0042 WROTE 0x44020354 = 0x0000 WROTE 0x44020358 = 0x420000 WROTE 0x4402035c = 0x20010db8 WROTE 0x44020380 = 0x0000 WROTE 0x44020384 = 0x0000 WROTE 0x44020388 = 0x40000000 WROTE 0x4402038c = 0x0001 READ 0x44020344 = 0x0001 WROTE 0x44020340 = 0x0001 READ 0x44020344 = 0x0001 READ 0x44020344 = 0x0001 success >> \end{verbatim} Step 3: setting neighbor entries \begin{verbatim} nico@ESPRIMO-P956:~$ sudo ip -6 neigh add 2001:db8:42::6 lladdr f8:f2:1e:09:62:d0 dev enp2s0f1 nico@ESPRIMO-P956:~$ sudo ip -6 neigh add 2001:db8:42::4 lladdr f8:f2:1e:09:62:d0 dev enp2s0f1 \end{verbatim} Step 4: generating test packets \begin{verbatim} nico@ESPRIMO-P956:~$ ping6 -c2 2001:db8:42::6 PING 2001:db8:42::6(2001:db8:42::6) 56 data bytes nico@ESPRIMO-P956:~$ sudo tcpdump -ni enp2s0f1 tcpdump: verbose output suppressed, use -v or -vv for full protocol decode listening on enp2s0f1, link-type EN10MB (Ethernet), capture size 262144 bytes 11:30:17.287577 IP6 2001:db8:42::42 > 2001:db8:42::6: ICMP6, echo request, seq 1, length 64 11:30:17.287599 IP6 2001:db8:42::42 > 2001:db8:42::6: ICMP6, echo request, seq 1, length 64 11:30:18.310178 IP6 2001:db8:42::42 > 2001:db8:42::6: ICMP6, echo request, seq 2, length 64 11:30:18.310258 IP6 2001:db8:42::42 > 2001:db8:42::6: ICMP6, echo request, seq 2, length 64 \end{verbatim} Result: success, packet is seen twice. % ------------------------------------------------------------------------------ \subsection{Test 3: NAT64} Additionally to the preparations done in test 1 and 2, the following steps were taken: Step 1: getting IP address values via Python \begin{verbatim} >>> int(ipaddress.IPv6Address(u"2001:db8:42::2a")) 42540766411362381960998550477184434218L >>> int(ipaddress.IPv6Address(u"2001:db8:42::")) 42540766411362381960998550477184434176L >>> int(ipaddress.IPv4Address(u"10.0.0.0")) 167772160 >>> int(ipaddress.IPv4Address(u"10.0.0.66")) 167772226 \end{verbatim} Add table entry for 2001:db8:42:2a to be translated to 10.0.0.42: \begin{verbatim} >> table_cam_add_entry realmain_nat64_0 realmain.nat64_static 42540766411362381960998550477184434218 => 42540766411362381960998550477184434176 167772160 42540766411362381960998550477184434176 0 fields = [(u'hit', 1), (u'action_run', 3), (u'v6_src', 128), (u'v4_dst', 32), (u'nat64_prefix', 128), (u'table_id', 16)] action_name = TopPipe.realmain.nat64_static field_vals = [2, '42540766411362381960998550477184434176', '167772160', '42540766411362381960998550477184434176', '0'] CAM_Init_ValidateContext() - done WROTE 0x44020050 = 0x002a WROTE 0x44020054 = 0x0000 WROTE 0x44020058 = 0x420000 WROTE 0x4402005c = 0x20010db8 WROTE 0x44020080 = 0x0000 WROTE 0x44020084 = 0x0000 WROTE 0x44020088 = 0x0000 WROTE 0x4402008c = 0xdb80042 WROTE 0x44020090 = 0x2001 WROTE 0x44020094 = 0x0a00 WROTE 0x44020098 = 0x0000 WROTE 0x4402009c = 0x0000 WROTE 0x440200a0 = 0xdb80042 WROTE 0x440200a4 = 0x22001 READ 0x44020044 = 0x0001 WROTE 0x44020040 = 0x0001 READ 0x44020044 = 0x0001 READ 0x44020044 = 0x0001 success >> \end{verbatim} Add table entry for 2001:db8:42::a00:2a to be translated to 10.0.0.66: \begin{verbatim} \end{verbatim} Add table entry for 10.0.0.66 to be translated to 2001:db8:42:42: \begin{verbatim} >> table_cam_add_entry realmain_nat46_0 realmain.nat46_static 167772226 => 42540766411362381960998550477184434176 167772160 42540766411362381960998550477184434176 0 fields = [(u'hit', 1), (u'action_run', 3), (u'v6_src', 128), (u'v4_dst', 32), (u'nat64_prefix', 128), (u'table_id', 16)] action_name = TopPipe.realmain.nat46_static field_vals = [2, '42540766411362381960998550477184434176', '167772160', '42540766411362381960998550477184434176', '0'] CAM_Init_ValidateContext() - done WROTE 0x44020150 = 0xa000042 WROTE 0x44020180 = 0x0000 WROTE 0x44020184 = 0x0000 WROTE 0x44020188 = 0x0000 WROTE 0x4402018c = 0xdb80042 WROTE 0x44020190 = 0x2001 WROTE 0x44020194 = 0x0a00 WROTE 0x44020198 = 0x0000 WROTE 0x4402019c = 0x0000 WROTE 0x440201a0 = 0xdb80042 WROTE 0x440201a4 = 0x22001 READ 0x44020144 = 0x0001 WROTE 0x44020140 = 0x0001 READ 0x44020144 = 0x0001 READ 0x44020144 = 0x0001 success >> \end{verbatim} Step 3: setting neighbor entries \begin{verbatim} sudo ip neigh add 10.0.0.66 lladdr f8:f2:1e:09:62:d1 dev enp2s0f0 sudo ip -6 neigh add 2001:db8:42::2a lladdr f8:f2:1e:09:62:d0 dev enp2s0f1 sudo ip -6 neighbor add 2001:db8:42::a00:2a lladdr f8:f2:1e:09:62:d0 dev enp2s0f1 \end{verbatim} Step 4: ping test should translate, but fail with wrong checksum: \begin{verbatim} \end{verbatim} \begin{verbatim} \end{verbatim} \chapter{\label{appendixB}NetFPGA Logs} Majority of the log files are stored inside the source code directory stored at ``netpfga/logs''. It follows a selection of log files \section{\label{chapterB:netpfga-flasherror}NetFPGA Flash Errors} Sometimes flashing bitfiles to the NetFPGA will fail. A random amount of reboots (1 to 3) and a random amount of reflashing will fix this problem. Below can be found the log output from the flashing process. \begin{verbatim} nico@nsg-System:~/projects/P4-NetFPGA/contrib-projects/sume-sdnet-switch/projects/minip4/simple_sume_switch/bitfiles$ sudo bash -c ". $HOME/master-thesis/netpfga/bashinit && $(pwd -P)/program_switch.sh" ++ which vivado + xilinx_tool_path=/opt/Xilinx/Vivado/2018.2/bin/vivado + bitimage=minip4.bit + configWrites=config_writes.sh + '[' -z minip4.bit ']' + '[' -z config_writes.sh ']' + '[' /opt/Xilinx/Vivado/2018.2/bin/vivado == '' ']' + rmmod sume_riffa + xsct /home/nico/projects/P4-NetFPGA/contrib-projects/sume-sdnet-switch/tools/run_xsct.tcl -tclargs minip4.bit rlwrap: warning: your $TERM is 'screen' but rlwrap couldn't find it in the terminfo database. Expect some problems. RUN loading image file. minip4.bit 100% 19MB 1.7MB/s 00:11 fpga configuration failed. DONE PIN is not HIGH invoked from within "::tcf::eval -progress ::xsdb::print_progress {::tcf::cache_enter tcfchan#0 {tcf_cache_eval {process_tcf_actions_cache_client ::tcfclient#0::arg}}}" (procedure "::tcf::cache_eval_with_progress" line 2) invoked from within "::tcf::cache_eval_with_progress [dict get $arg chan] [list process_tcf_actions_cache_client $argvar] $progress" (procedure "process_tcf_actions" line 1) invoked from within "process_tcf_actions $arg ::xsdb::print_progress" (procedure "fpga" line 430) invoked from within "fpga -f $bitimage" (file "/home/nico/projects/P4-NetFPGA/contrib-projects/sume-sdnet-switch/tools/run_xsct.tcl" line 33) + bash /home/nico/projects/P4-NetFPGA/contrib-projects/sume-sdnet-switch/tools/pci_rescan_run.sh Check programming FPGA or Reboot machine ! + rmmod sume_riffa rmmod: ERROR: Module sume_riffa is not currently loaded + modprobe sume_riffa + ifconfig nf0 up nf0: ERROR while getting interface flags: No such device + ifconfig nf1 up nf1: ERROR while getting interface flags: No such device + ifconfig nf2 up nf2: ERROR while getting interface flags: No such device + ifconfig nf3 up nf3: ERROR while getting interface flags: No such device + bash config_writes.sh \end{verbatim} \section{\label{chapterB:netpfga-flashok}NetFPGA Flash Success} A successful flashing process also emits a couple of errors, however the message ``fpga configuration failed. DONE PIN is not HIGH'' and its succeeding lines are missing, as seen below. After that in all cases a reboot is required; the PCI rescan in no tested case showed the nf devices. \begin{verbatim} nico@nsg-System:~$ cd $NF_DESIGN_DIR/bitfiles/ nico@nsg-System:~/projects/P4-NetFPGA/contrib-projects/sume-sdnet-switch/projects/minip4/simple_sume_switch/bitfiles$ sudo bash -c ". $HOME/master-thesis/netpfga/bashinit && $(pwd -P)/program_switch.sh" ++ which vivado + xilinx_tool_path=/opt/Xilinx/Vivado/2018.2/bin/vivado + bitimage=minip4.bit + configWrites=config_writes.sh + '[' -z minip4.bit ']' + '[' -z config_writes.sh ']' + '[' /opt/Xilinx/Vivado/2018.2/bin/vivado == '' ']' + rmmod sume_riffa + xsct /home/nico/projects/P4-NetFPGA/contrib-projects/sume-sdnet-switch/tools/run_xsct.tcl -tclargs minip4.bit rlwrap: warning: your $TERM is 'xterm-256color' but rlwrap couldn't find it in the terminfo database. Expect some problems. RUN loading image file. minip4.bit attempting to launch hw_server ****** Xilinx hw_server v2018.2 **** Build date : Jun 14 2018-20:18:37 ** Copyright 1986-2018 Xilinx, Inc. All Rights Reserved. INFO: hw_server application started INFO: Use Ctrl-C to exit hw_server application INFO: To connect to this hw_server instance use url: TCP:127.0.0.1:3121 100% 19MB 1.7MB/s 00:11 + bash /home/nico/projects/P4-NetFPGA/contrib-projects/sume-sdnet-switch/tools/pci_rescan_run.sh Check programming FPGA or Reboot machine ! + rmmod sume_riffa rmmod: ERROR: Module sume_riffa is not currently loaded + modprobe sume_riffa + ifconfig nf0 up nf0: ERROR while getting interface flags: No such device + ifconfig nf1 up nf1: ERROR while getting interface flags: No such device + ifconfig nf2 up nf2: ERROR while getting interface flags: No such device + ifconfig nf3 up nf3: ERROR while getting interface flags: No such device + bash config_writes.sh nico@nsg-System:~/projects/P4-NetFPGA/contrib-projects/sume-sdnet-switch/projects/minip4/simple_sume_switch/bitfiles$ \end{verbatim} \section{\label{chapterB:netpfga-kernelmodule}NetFPGA Kernel module} After a successful flash, loading the kernel module will enable nf devices to appear in the operating system. \begin{verbatim} nico@nsg-System:~$ ip l 1: lo: mtu 65536 qdisc noqueue state UNKNOWN mode DEFAULT group default qlen 1000 link/loopback 00:00:00:00:00:00 brd 00:00:00:00:00:00 2: eth0: mtu 1500 qdisc pfifo_fast state UP mode DEFAULT group default qlen 1000 link/ether 74:d0:2b:98:38:f6 brd ff:ff:ff:ff:ff:ff 3: eth1: mtu 1500 qdisc noop state DOWN mode DEFAULT group default qlen 1000 link/ether f8:f2:1e:41:44:9c brd ff:ff:ff:ff:ff:ff 4: eth2: mtu 1500 qdisc noop state DOWN mode DEFAULT group default qlen 1000 link/ether f8:f2:1e:41:44:9d brd ff:ff:ff:ff:ff:ff 5: wg0: mtu 1420 qdisc noqueue state UNKNOWN mode DEFAULT group default qlen 1000 link/none nico@nsg-System:~$ ~/master-thesis/bin/build-load-drivers.sh + cd /home/nico/projects/P4-NetFPGA/lib/sw/std/driver/sume_riffa_v1_0_0 + sudo modprobe -r sume_riffa + make clean make -C /lib/modules/4.15.0-55-generic/build M=/home/nico/projects/P4-NetFPGA/lib/sw/std/driver/sume_riffa_v1_0_0 clean make[1]: Entering directory '/usr/src/linux-headers-4.15.0-55-generic' CLEAN /home/nico/projects/P4-NetFPGA/lib/sw/std/driver/sume_riffa_v1_0_0/.tmp_versions CLEAN /home/nico/projects/P4-NetFPGA/lib/sw/std/driver/sume_riffa_v1_0_0/Module.symvers make[1]: Leaving directory '/usr/src/linux-headers-4.15.0-55-generic' + make all make -C /lib/modules/4.15.0-55-generic/build M=/home/nico/projects/P4-NetFPGA/lib/sw/std/driver/sume_riffa_v1_0_0 modules make[1]: Entering directory '/usr/src/linux-headers-4.15.0-55-generic' CC [M] /home/nico/projects/P4-NetFPGA/lib/sw/std/driver/sume_riffa_v1_0_0/sume_riffa.o Building modules, stage 2. MODPOST 1 modules CC /home/nico/projects/P4-NetFPGA/lib/sw/std/driver/sume_riffa_v1_0_0/sume_riffa.mod.o LD [M] /home/nico/projects/P4-NetFPGA/lib/sw/std/driver/sume_riffa_v1_0_0/sume_riffa.ko make[1]: Leaving directory '/usr/src/linux-headers-4.15.0-55-generic' + sudo make install make -C /lib/modules/4.15.0-55-generic/build M=/home/nico/projects/P4-NetFPGA/lib/sw/std/driver/sume_riffa_v1_0_0 modules make[1]: Entering directory '/usr/src/linux-headers-4.15.0-55-generic' Building modules, stage 2. MODPOST 1 modules make[1]: Leaving directory '/usr/src/linux-headers-4.15.0-55-generic' install -o root -g root -m 0755 -d /lib/modules/4.15.0-55-generic/extra/sume_riffa/ install -o root -g root -m 0755 sume_riffa.ko /lib/modules/4.15.0-55-generic/extra/sume_riffa/ depmod -a 4.15.0-55-generic + sudo modprobe sume_riffa + grep sume_riffa + lsmod sume_riffa 28672 0 nico@nsg-System:~$ nico@nsg-System:~$ ip l 1: lo: mtu 65536 qdisc noqueue state UNKNOWN mode DEFAULT group default qlen 1000 link/loopback 00:00:00:00:00:00 brd 00:00:00:00:00:00 2: eth0: mtu 1500 qdisc pfifo_fast state UP mode DEFAULT group default qlen 1000 link/ether 74:d0:2b:98:38:f6 brd ff:ff:ff:ff:ff:ff 3: eth1: mtu 1500 qdisc noop state DOWN mode DEFAULT group default qlen 1000 link/ether f8:f2:1e:41:44:9c brd ff:ff:ff:ff:ff:ff 4: eth2: mtu 1500 qdisc noop state DOWN mode DEFAULT group default qlen 1000 link/ether f8:f2:1e:41:44:9d brd ff:ff:ff:ff:ff:ff 5: wg0: mtu 1420 qdisc noqueue state UNKNOWN mode DEFAULT group default qlen 1000 link/none 6: nf0: mtu 1500 qdisc noop state DOWN mode DEFAULT group default qlen 1000 link/ether 02:53:55:4d:45:00 brd ff:ff:ff:ff:ff:ff 7: nf1: mtu 1500 qdisc noop state DOWN mode DEFAULT group default qlen 1000 link/ether 02:53:55:4d:45:01 brd ff:ff:ff:ff:ff:ff 8: nf2: mtu 1500 qdisc noop state DOWN mode DEFAULT group default qlen 1000 link/ether 02:53:55:4d:45:02 brd ff:ff:ff:ff:ff:ff 9: nf3: mtu 1500 qdisc noop state DOWN mode DEFAULT group default qlen 1000 link/ether 02:53:55:4d:45:03 brd ff:ff:ff:ff:ff:ff nico@nsg-System:~$ \end{verbatim} \section{\label{chapterB:netpfga-nftraffic}NetFPGA misses packets on nf*} While the nf devices appear in the operating system, packets emitted by the netpfga cannot be sniffed on the nf interfaces directly. Instead one has to sniff packets on a physical network card that is connected to the specific output port. %Entries for the list of abbrevations: % %To generate the list of abbrevations, execute: %makeindex Thesis.nlo -s nomencl.ist -o Thesis.nls % %If you are using TeXniCenter, specify: %"%bm.nlo" -s nomencl.ist -o "%bm.nls" %as beeing the argument list for makeindex. %--------------------------------------------------------------------------------------------------------- %For old nomencl package uncomment this: %\printglossary %For new nomencl package uncomment this: \printnomenclature \abbrev{XCA}{\markup{X}tremely \markup{C}ool \markup{A}bbrevations}