VPP/Build, install, and test images
This page explains how to build, install, and smoke-test a VPP package.
These procedures assume that you have a working development environment available. If you are not sure, see Pulling, Building, Hacking, and Pushing VPP Code.
Contents
- 1 Running Vagrant
- 1.1 cd to the vagrant directory
- 1.2 Adding network interfaces to Vagrant
- 1.3 Build the VM with Vagrant
- 1.4 Access the shell
- 1.5 Build A VPP Package
- 1.5.1 Step 1: Navigate to the build-root directory
- 1.5.2 Step 2: (Optional) Update the tree and clean up the build directories
- 1.5.3 Step 3: Build Debian or RPM Packages
- 1.5.4 Step 1A: Navigate to the top level directory.
- 1.5.5 Step 2A: (Optional) Clean up build directories and execute fresh release build.
- 1.5.6 Step 3A: Build Debian or RPM Packages
- 1.6 Install A VPP Package
- 1.7 (Debian / Ubuntu)
- 1.8 (Centos)
- 1.9 Test The VPP Package
- 2 Build, Install, and Test VPP without using Packages
Running Vagrant
For more information about using Vagrant on a command-line interface (CLI), see: https://docs.vagrantup.com/v2/cli/index.html
cd to the vagrant directory
In the command-line interface, navigate to the directory that has the pre-configured Vagrantfile. (In the following sample command, <install_dir> is the directory where you unzipped or cloned the VPP software.)
cd <install_dir>/build-root/vagrant/
NOTE: The .../build-root directory contains the files that make up most of the build system. It contains all of the generic targets, including: xxx-build, xxx-rebuild, xxx-install, xxx-clean, xxx-wipe, xxx-configure, and xxx-find-source.
Adding network interfaces to Vagrant
By default, Virtual Machine will have access to only private networks, specifically local0 and pg interfaces. But they won't be useful for tutorial. To make Gigabit*(public network) interfaces appear, find comment in the Vagrant file.
# Define some physical ports for your VMs to be used by DPDK
Set nics to the number of Gigabit interfaces needed and config.vm.network to "private_network".
Code should look like following :
nics = 1 if ENV.key?('VPP_VAGRANT_NICS') nics = ENV['VPP_VAGRANT_NICS'].to_i(10) end for i in 1..nics config.vm.network "private_network", type: "dhcp" end
Build the VM with Vagrant
By default this will build an Ubuntu 14.0.4 VM.
If you wish instead to build a Centos7 VM instead:
(export VPP_VAGRANT_DISTRO=centos7;vagrant up)
If you wish to use VMWareFusion as your provider, use:
(export VAGRANT_DEFAULT_PROVIDER=vmware_fusion;vagrant up)
Note: If you use vmware please see Vagrant VMWare Provider
When you first start Vagrant, it is normal for it to run for several minutes, building the VM, building VPP, and then a README will be displayed telling you how to run VPP.
Use the Vagrant up command to cause Vagrant to start. Vagrant uses the Vagrantfile in the current working directory.
vagrant up
Access the shell
Use the Vagrant SSH command to access the running Vagrant machine and give you access to a shell.
vagrant ssh
If you wish to forward X-windows server requests, use this variation:
vagrant ssh -- -X
Build A VPP Package
The following steps explain how to build a package. Steps 1 through 3 show how to build from the build-root directory.
For an alternative method, use the top level make command. Steps 1A through 3A show this method.
After connecting vagrant through ssh
cd /vpp/build-root
Step 2: (Optional) Update the tree and clean up the build directories
You can execute a git pull command to obtain the latest updates from the repository. It's also a good idea to execute a "make distclean" command after you do this. Execute the bootstrap script to make sure that build paths and build tools are in a clean state.
git pull make distclean ./bootstrap.sh
Step 3: Build Debian or RPM Packages
Execute the make command to start the build process. You can review the makefile (located in the build-root directory) to examine the build parameters.
To build a Debian package:
make V=0 PLATFORM=vpp TAG=vpp install-deb
To build an RPM package:
make V=0 PLATFORM=vpp TAG=vpp install-rpm
On Ubuntu 15.10 I needed to execute the line above using 'sudo' as the dh_install failed with errors.
After connecting vagrant through ssh
cd /vpp
For list of commands, execute
make
Step 2A: (Optional) Clean up build directories and execute fresh release build.
You can execute a git pull command to obtain the latest updates from the repository. It's also a good idea to execute a "make distclean" command after you do this. Execute the bootstrap script to make sure that build paths and build tools are in a clean state.
git pull make wipe-release make install-dep make build-release
Step 3A: Build Debian or RPM Packages
Execute the make command to start the build process. You can review the makefile (located in the build-root directory) to examine the build parameters.
To build a Debian package:
make pkg-deb
To build an RPM package:
make pkg-rpm
Install A VPP Package
After you have successfully built the VPP packages, you need to install them in order to run.
Step 1: Install the packages
Install the packages. You can install packages with standard package installation tools (dpkg -i on debian/ubuntu, rpm on RedHat/CentOS).
NOTE: You will need root privileges.
To install the package(s) on a Debian operating system:
- Login with root privileges
- Type the dpkg installation command:
sudo dpkg -i /vpp/build-root/*.deb
To install the package(s) using Redhat Package Manager (RPM):
- Login with root privileges
- Type the RPM installation command:
sudo rpm -i /vpp/build-root/*.rpm
NOTE: On Ubuntu/Debian and RedHat/CentOS systems, the vpp engine consists of multiple installation packages:
- vpp - main VPP process
- vpp-lib - dynamically linked libraries
- vpp-dev - development support files and examples
- vpp-dpdk-dkms - DKMS based DPDK kernel module package (only on Debian/Ubuntu)
Step 2: Examine the startup configuration
After successful installation, vpp installs a startup config file named startup.conf in the /etc/vpp directory. You can modify that file if appropriate.
Here is a sample:
unix { nodaemon log /var/log/vpp/vpp.log cli-listen localhost:5002 full-coredump } api-trace { on } dpdk { socket-mem 1024 }
Note: In VPP 18.04, the default log file location was moved from '/tmp/vpp.log' to '/var/log/vpp/vpp.log' . The VPP code is indifferent to the file location. However, if SELinux is enabled, then the new location is required for the file to be properly labelled. Check your local startup.conf file for the log file location on your system.
Step 3: Start vpp
To start the data plane:
- Login with root privileges
- Type the start vpp command:
(Debian / Ubuntu)
sudo start vpp
On Ubuntu 15.10 you need to have Upstart installed as they switched to systemd. Use 'sudo apt-get install upstart-sysv' then reboot.
(Centos)
sudo service vpp start
- Wait for a few seconds
- Check the interface list.
It's a good idea to check the interface list to see which interfaces vpp has been discovered.
To show the interface list, execute the show command:
sudo vppctl show interface # The interface set varies depending on the system configuration. Name Idx State Counter Count GigabitEthernet2/2/0 5 down GigabitEthernet2/3/0 6 down GigabitEthernet2/4/0 7 down GigabitEthernet2/5/0 8 down GigabitEthernet2/6/0 9 down GigabitEthernet2/7/0 10 down local0 0 down pg/stream-0 1 down pg/stream-1 2 down pg/stream-2 3 down pg/stream-3 4 down
Step 4: Change blacklist behavior
If vpp seems not to have discovered an interface that you expected to see, it's likely that the data-plane blacklisted it. The VPP process blacklists interfaces whose corresponding Linux interfaces are up.
You can change this blacklist behavior. For example, if you want vpp to take over an interface eth1 which has been blacklisted, execute the following commands.
To remove eth1 from the running VPP blacklist:
sudo ifconfig # Save eth1 IP sudo ifconfig eth1 down sudo ip addr flush dev ethX sudo stop vpp sudo start vpp
Test The VPP Package
It's a good idea to perform a few basic smoke-tests. In other words, it's a good idea to perform some basic tasks to make sure that vpp is running as expected.
Step 1: Configure and enable an interface
Use the set int command to configure an interface. For this test, configure an ipv4 address on an interface, and enable the interface. Use the sudo command in combination with the vpp engine's vppctl command to execute the command with root privilege:
Replace X.X.X.X with saved IP.
sudo vppctl set int ip address GigabitEthernet2/2/0 X.X.X.X/24 sudo vppctl set int state GigabitEthernet2/2/0 up
You can also use the vppctl command in combination with native Linux commands such as grep:
sudo vppctl show int | grep State
Use the ip probe command to probe an adjacent system, by sending an ipv4 icmp echo-request:
sudo vppctl ip probe 192.168.1.2 GigabitEthernet2/2/0 Resolved 192.168.1.2
Use the sh ip command to check the ARP and ipv4 FIB tables:
sudo vppctl sh ip arp Time FIB IP4 Stat Ethernet Interface 2782.7392 0 192.168.1.2 00:50:56:b7:05:bb GigabitEthernet2/2/0
sudo vppctl sh ip fib Table 0, fib_index 0, flow hash: src dst sport dport proto Destination Packets Bytes Adjacency 192.168.1.0/24 0 0 weight 1, index 5 arp GigabitEthernet2/2/0 192.168.1.1/24 192.168.1.1/32 0 0 weight 1, index 4 local 192.168.1.1/24 192.168.1.2/32 0 0 weight 1, index 3 GigabitEthernet2/2/0 IP4: 00:50:56:b7:05:bc -> 00:50:56:b7:05:bb
Step 2: Check the error counters
After pinging the vpp engine from 192.168.1.2, use the show error command to check the error counters.
In this case, all of the counters represent normal events:
sudo vppctl show error Count Node Reason 1 ip4-arp ARP requests sent 9810 ip4-icmp-input echo replies sent 2 arp-input ARP replies receive
Step 3: Reset the statistics
Use the clear run command to reset the per-node runtime statistics:
sudo vppctl clear run
Step 4: Check for new statistics
Send a small number of ipv4 icmp echo replies from the adjacent Linux system. Note that the vpp data plane is capable of answering several MPPS worth of ipv4 icmp echo replies; as the vector size increases, the clocks/pkt statistics will improve drastically.
Use the show run command to see the new statistics.
sudo vppctl show run Time 18.1, average vectors/node 1.00, last 128 main loops 0.00 per node 0.00 vector rates in 2.2068e-1, out 2.2068e-1, drop 0.0000e0, punt 0.0000e0 Name State Calls Vectors Suspends Clocks Vectors/Call GigabitEthernet2/2/0-output active 4 4 0 1.71e3 1.00 GigabitEthernet2/2/0-tx active 4 4 0 7.49e3 1.00 api-rx-from-ring any wait 0 0 1 9.90e3 0.00 cnat-db-scanner any wait 0 0 1813 1.17e3 0.00 dpdk-input polling 60666120 4 0 4.04e9 0.00 dpdk-process any wait 0 0 4 1.29e7 0.00 ethernet-input active 4 4 0 5.51e3 1.00 gmon-process time wait 0 0 3 5.59e3 0.00 ip4-icmp-echo-request active 4 4 0 1.85e3 1.00 ip4-icmp-input active 4 4 0 1.51e3 1.00 ip4-input active 4 4 0 3.49e3 1.00 ip4-local active 4 4 0 3.23e3 1.00 ip4-lookup active 4 4 0 4.49e3 1.00 ip4-rewrite-local active 4 4 0 3.72e3 1.00 ip6-icmp-neighbor-discovery-ev any wait 0 0 18 6.74e3 0.00 unix-cli-127.0.0.1:48387 active 0 0 9 7.15e4 0.00 unix-epoll-input polling 60666120 0 0 5.15e2 0.00 vpe-oam-process any wait 0 0 9 6.45e3 0.00
Step 5: Start a packet trace
Use the trace add command to start a packet-tracer capture:
sudo vppctl trace add dpdk-input 10
Step 6: Verify test packets
Ping 192.168.1.1 from 192.168.1.2, AKA send ipv4 icmp echo request packets. If the ping succeeds, you should be all set.
Use the show trace command to display the packet trace.
To show trace information:
sudo vppctl show trace
The packet trace will look something like this:
------------------- Start of thread 0 vpp_main ------------------- Packet 1 01:10:14:046893: dpdk-input GigabitEthernet2/2/0 rx queue 0 buffer 0x631e: current data 0, length 102, free-list 0, totlen-nifb 0, trace 0x0 PKT MBUF: port 0, nb_segs 1, pkt_len 102 buf_len 2304, data_len 102, ol_flags 0x0, packet_type 0x0 IP4: 00:50:56:b7:05:bb -> 00:50:56:b7:05:bc ICMP: 192.168.1.2 -> 192.168.1.1 tos 0x00, ttl 64, length 84, checksum 0x7c1f fragment id 0x3b36, flags DONT_FRAGMENT ICMP echo_request checksum 0x7cd1 01:10:14:046989: ethernet-input IP4: 00:50:56:b7:05:bb -> 00:50:56:b7:05:bc 01:10:14:047010: ip4-input ICMP: 192.168.1.2 -> 192.168.1.1 tos 0x00, ttl 64, length 84, checksum 0x7c1f fragment id 0x3b36, flags DONT_FRAGMENT ICMP echo_request checksum 0x7cd1 01:10:14:047013: ip4-local fib: 0 adjacency: local 192.168.1.1/24 flow hash: 0x00000000 01:10:14:047017: ip4-icmp-input ICMP: 192.168.1.2 -> 192.168.1.1 tos 0x00, ttl 64, length 84, checksum 0x7c1f fragment id 0x3b36, flags DONT_FRAGMENT ICMP echo_request checksum 0x7cd1 01:10:14:047019: ip4-icmp-echo-request ICMP: 192.168.1.2 -> 192.168.1.1 tos 0x00, ttl 64, length 84, checksum 0x7c1f fragment id 0x3b36, flags DONT_FRAGMENT ICMP echo_request checksum 0x7cd1 01:10:14:047019: ip4-rewrite-local fib: 0 adjacency: GigabitEthernet2/2/0 IP4: 00:50:56:b7:05:bc -> 00:50:56:b7:05:bb flow hash: 0x00000000 IP4: 00:50:56:b7:05:bc -> 00:50:56:b7:05:bb ICMP: 192.168.1.1 -> 192.168.1.2 tos 0x00, ttl 64, length 84, checksum 0x6383 fragment id 0x53d2, flags DONT_FRAGMENT ICMP echo_reply checksum 0x84d1 01:10:14:047021: GigabitEthernet2/2/0-output GigabitEthernet2/2/0 IP4: 00:50:56:b7:05:bc -> 00:50:56:b7:05:bb ICMP: 192.168.1.1 -> 192.168.1.2 tos 0x00, ttl 64, length 84, checksum 0x6383 fragment id 0x53d2, flags DONT_FRAGMENT ICMP echo_reply checksum 0x84d1 01:10:14:047022: GigabitEthernet2/2/0-tx GigabitEthernet2/2/0 tx queue 0 buffer 0x631e: current data 0, length 102, free-list 0, totlen-nifb 0, trace 0x0 IP4: 00:50:56:b7:05:bc -> 00:50:56:b7:05:bb ICMP: 192.168.1.1 -> 192.168.1.2 tos 0x00, ttl 64, length 84, checksum 0x6383 fragment id 0x53d2, flags DONT_FRAGMENT ICMP echo_reply checksum 0x84d1 Packet 2 01:10:15:044487: dpdk-input GigabitEthernet2/2/0 rx queue 0 buffer 0x6345: current data 0, length 102, free-list 0, totlen-nifb 0, trace 0x1 PKT MBUF: port 0, nb_segs 1, pkt_len 102 buf_len 2304, data_len 102, ol_flags 0x0, packet_type 0x0 IP4: 00:50:56:b7:05:bb -> 00:50:56:b7:05:bc ICMP: 192.168.1.2 -> 192.168.1.1 tos 0x00, ttl 64, length 84, checksum 0x7bc7 fragment id 0x3b8e, flags DONT_FRAGMENT ICMP echo_request checksum 0x64d4 01:10:15:044496: ethernet-input IP4: 00:50:56:b7:05:bb -> 00:50:56:b7:05:bc 01:10:15:044500: ip4-input ICMP: 192.168.1.2 -> 192.168.1.1 tos 0x00, ttl 64, length 84, checksum 0x7bc7 fragment id 0x3b8e, flags DONT_FRAGMENT ICMP echo_request checksum 0x64d4 01:10:15:044504: ip4-local fib: 0 adjacency: local 192.168.1.1/24 flow hash: 0x00000000 01:10:15:044506: ip4-icmp-input ICMP: 192.168.1.2 -> 192.168.1.1 tos 0x00, ttl 64, length 84, checksum 0x7bc7 fragment id 0x3b8e, flags DONT_FRAGMENT ICMP echo_request checksum 0x64d4 01:10:15:044507: ip4-icmp-echo-request ICMP: 192.168.1.2 -> 192.168.1.1 tos 0x00, ttl 64, length 84, checksum 0x7bc7 fragment id 0x3b8e, flags DONT_FRAGMENT ICMP echo_request checksum 0x64d4 01:10:15:044507: ip4-rewrite-local fib: 0 adjacency: GigabitEthernet2/2/0 IP4: 00:50:56:b7:05:bc -> 00:50:56:b7:05:bb flow hash: 0x00000000 IP4: 00:50:56:b7:05:bc -> 00:50:56:b7:05:bb ICMP: 192.168.1.1 -> 192.168.1.2 tos 0x00, ttl 64, length 84, checksum 0x82be fragment id 0x3497, flags DONT_FRAGMENT ICMP echo_reply checksum 0x6cd4 01:10:15:044509: GigabitEthernet2/2/0-output GigabitEthernet2/2/0 IP4: 00:50:56:b7:05:bc -> 00:50:56:b7:05:bb ICMP: 192.168.1.1 -> 192.168.1.2 tos 0x00, ttl 64, length 84, checksum 0x82be fragment id 0x3497, flags DONT_FRAGMENT ICMP echo_reply checksum 0x6cd4 01:10:15:044510: GigabitEthernet2/2/0-tx GigabitEthernet2/2/0 tx queue 0 buffer 0x6345: current data 0, length 102, free-list 0, totlen-nifb 0, trace 0x1 IP4: 00:50:56:b7:05:bc -> 00:50:56:b7:05:bb ICMP: 192.168.1.1 -> 192.168.1.2 tos 0x00, ttl 64, length 84, checksum 0x82be fragment id 0x3497, flags DONT_FRAGMENT ICMP echo_reply checksum 0x6cd4
If you see packet information from ICMP: 192.168.1.2, then you know that vpp is successfully processing packets.
Update
If debian packages should be updated. See all VPP packages installed.
dpkg -l | grep vpp
You should get something like
# ii vpp 1.0.0-190~g9f50b0b-dirty amd64 Vector Packet Processing--executables # ii vpp-dbg 1.0.0-190~g9f50b0b-dirty amd64 Vector Packet Processing--debug symbols # ii vpp-dev 1.0.0-190~g9f50b0b-dirty amd64 Vector Packet Processing--development support # ii vpp-dpdk-dev 1.0.0-190~g9f50b0b-dirty amd64 Vector Packet Processing--development support # ii vpp-dpdk-dkms 1.0.0-190~g9f50b0b-dirty amd64 DPDK 2.1 igb_uio_driver # ii vpp-lib 1.0.0-190~g9f50b0b-dirty amd64 Vector Packet Processing--runtime libraries
Remove all of them
sudo dpkg --purge vpp vpp-dbg vpp-dev vpp-dpdk-dev vpp-dpdk-dkms vpp-lib
Build, Install, and Test VPP without using Packages
The following steps explain how to build, install, and test the code without building and installing packages. This is useful for doing development. Assume that <top> is the top directory of the tree that you cloned (e.g., git clone https://gerrit.fd.io/r/vpp) and should be spelled out appropriately.
cd <top>
For list of commands, execute
make
Step 2: Clean up build directories and execute fresh release build.
You can execute a git pull command to obtain the latest updates from the repository. It's also possible, though typically not necessary, to execute a "make wipe-release" command after you do this. Execute the bootstrap script during the initial build sequence to make sure that build paths and build tools are in a clean state; this is a no-op on subsequent builds.
git pull make wipe-release # rarely required make install-dep # extremely rarely required after the initial build sequence make bootstrap # only for first time build make build-release
You can substitute "make wipe" and "make "build" for "make wipe-release" and "make build-release" respectively, to build debug versions. If that is done, references to "install-vpp-native" below should be changed to "install-vpp_debug-native".
Step 3: Copy and Examine the startup configuration
I am recommending that configuration files be kept under /etc, and that we do a one time copy of the default versions from our source tree. This way, we can modify configuration without worrying that our modifications are overwritten. Thus, copying the configuration files is a one time operation:
cd <top>/src/vpp/conf sudo mkdir -p /etc/vpp sudo cp startup.conf /etc/vpp/ sudo cp 80-vpp.conf /etc/sysctl.d
Here is a sample of startup.conf:
unix { nodaemon log /var/log/vpp/vpp.log cli-listen localhost:5002 full-coredump } api-trace { on } dpdk { socket-mem 1024 } # Alternate syntax to choose plugin path plugin_path <top>/build-root/install-vpp-native/vpp/lib64/vpp_plugins
Note in particular that the plugin_path must be set for this inline development mode.
You need to reboot after copying 80-vpp.conf to /etc/sysctl.d/ to pickup that configuration. Alternatively, you could accomplish the same thing using the sysctl command. I believe that a minimum of 3.5 to 4 GB system memory is required, but I do not know the precise number. You can probably figure it out if you read 80-vpp.conf correctly.
Step 4: Start vpp
To start the data plane I use this script that I save in ~/vpp.sh and then I run "source ~/vpp.sh":
T=~/vpp/build-root/install-vpp-native/vpp sudo /bin/rm -f /dev/shm/db /dev/shm/global_vm /dev/shm/vpe-api || return sudo /sbin/modprobe uio_pci_generic || return sudo $T/bin/vpp -c /etc/vpp/startup.conf
Next, we need some preparation to use the vppctl command. It calls the vpp_api_test command; both commands are in directory $T/bin. Because vpp_api_test is called with sudo access, the sudo secure_path must be set correctly. Using the command
sudoedit /etc/sudoers
modify the definition of secure_path to read
Defaults secure_path = /sbin:/bin:/usr/sbin:/usr/bin:<top>/build-root/install-vpp-native/vpp/bin