Quickstart Guide¶
Introduction¶
Welcome to the Dataplane Stack reference solution quickstart guide. This guide provides instructions on how to fetch source code, build the source code and run sample applications.
By following the steps in this quickstart guide to the end, you will set up two user space programs for high-throughput packet forwarding. The programs accept packets from NIC port 0 and forward them out on the same NIC port based on their destination IP address.
Users and Essential Skills¶
The reference solutions are targeted for a networking software development or performance analysis engineer who has in-depth networking knowledge, but does not know about Arm necessarily.
Mastering knowledge on certain user space open source networking projects, e.g., DPDK, VPP, ODP, will help gain deeper understanding of this guide and the reference solutions more easily.
Setup¶
The sample applications described in this guide require the following setup.
+------------------+ +-------------------+
| | | |
| Traffic | +----| DUT |
| Generator | Ethernet Connection | N | |
| |<----------------------->| I | |
| | (Port 0)| C | |
| | +----| |
+------------------+ +-------------------+
As shown, the Device Under Test (DUT) should have at least one NIC connected to the traffic generator on port 0. The user can use any traffic generator. The DUT is also used to download the solution repository and build the code. Cross compilation is not supported currently.
Tested Platforms¶
The sample applications are tested on the following platforms.
DUT¶
Ampere Altra (Neoverse-N1)
Ubuntu 20.04.3 LTS (Focal Fossa)
Preparing the DUT¶
Requirements¶
The DUT needs to have a minimum hardware configuration as below.
Processor: Minimum 1 GHz and 4 CPU cores
Hard Drive: Minimum 32 GB
Memory (RAM): Minimum 8 GB
Network Interface Controller: Minimum 10G port connecting to Traffic Generator
Connection to internet to download the source code and dependent packages
This documentation assumes the user has installed Ubuntu 20.04 (Focal) on the DUT.
Admin (root) privileges are required to run the software and set up the DUT.
Access to the internet is mandatory for downloading solution source code and installing all dependent packages and libraries.
Scripts are provided to install the dependent packages and libraries.
Mellanox OFED driver is installed and NIC firmware is updated.
gcc 9.4.0 or newer version is required to compile the software.
The provided scripts must be run in a bash shell.
- The following utilities must be available on the DUT:
git
curl
python
python3
To configure Git, run:
git config --global user.email "[email protected]"
git config --global user.name "Your Name"
Follow the instructions provided in
git-repo to install the
repo tool manually.
Download Source Code¶
Create a new folder that will be the workspace, henceforth referred to as
<nw_ds_workspace> in these instructions:
mkdir <nw_ds_workspace>
cd <nw_ds_workspace>
export NW_DS_RELEASE=refs/tags/NW-DS-2022.06.30
Note
Sometimes new features and additional bug fixes are made available in
the git repositories, but are not tagged yet as part of a release.
To pick up these latest changes, remove the
-b <release tag> option from the repo init command below.
However, please be aware that such untagged changes may not be formally
verified and should be considered unstable until they are tagged in an
official release.
To clone the repository, run the following commands:
repo init \
-u https://git.gitlab.arm.com/arm-reference-solutions/arm-reference-solutions-manifest.git \
-b ${NW_DS_RELEASE} \
-m dataplane-stack.xml
repo sync
Setup¶
This solution includes a setup.sh bash script responsible for the setup
process.
The setup script:
Installs and upgrades the required packages
Configures platform level parameters required to run the applications
The affected packages and parameters can be found in setup.sh.
To set up the DUT:
cd <nw_ds_workspace>/dataplane-stack
sudo ./setup.sh
Build¶
This solution uses Makefile to build all the components.
The Makefile:
Builds DPDK and the L3fwd sample application
Builds VPP
To build Dataplane Stack, run the following on DUT:
cd <nw_ds_workspace>/dataplane-stack
make all
Note
The compilation might take some time to complete.
Reboot¶
After setting up DUT and building the software, reboot the DUT. This ensures the setup changes are reflected before running the sample applications.
Get NIC Information¶
Identify the interface and PCIe address of the NIC port attached to the traffic generator.
sudo ethtool --identify <interface name> will help identify which NIC port is associated with a given interface name.
sudo lshw -c net -businfo will identify the PCIe address for the interface.
For example, if enP1p1s0f0 is attached to the traffic generator, then running lshw -c net -businfo will show
the PCIe address as 0001:01:00.0:
$ sudo lshw -c net -businfo
Bus info Device Class Description
====================================================
pci@0000:07:00.0 eth0 network RTL8111/8168/8411 PCI Express Gigabit Ethernet Controller
pci@0001:01:00.0 enP1p1s0f0 network MT27800 Family [ConnectX-5]
pci@0001:01:00.1 enP1p1s0f1 network MT27800 Family [ConnectX-5]
DPDK L3fwd¶
Bind NIC to Proper Linux Driver¶
For NICs that support bifurcated drivers, like Mellanox NICs, please skip this step.
For other NICs to be used by DPDK, the NIC needs to be bound to the appropriate driver.
In practice, vfio-pci driver is sufficient. Before using vfio-pci, be sure to load
the kernel module with modprobe vfio-pci.
For more information, review DPDK’s Linux Drivers Guide.
To bind the NIC to the appropriate driver, run:
cd <nw_ds_workspace>/dataplane-stack
sudo modprobe vfio-pci # ensure kernel module is loaded
sudo components/dpdk/usertools/dpdk-devbind.py -b vfio-pci <pcie_address>
For example, to bind PCIe address 0000:06:00.1 to vfio-pci:
sudo modprobe vfio-pci # ensure kernel module is loaded
sudo components/dpdk/usertools/dpdk-devbind.py -b vfio-pci 0000:06:00.1
Run¶
To run DPDK L3fwd application:
cd <nw_ds_workspace>/dataplane-stack
sudo components/dpdk/build/examples/dpdk-l3fwd -n 4 -l 2 -a <pcie_address> -- -P -p 0x1 --config='(0,0,2)'
For example, to run dpdk-l3fwd using 0001:01:00.0:
cd <nw_ds_workspace>/dataplane-stack
sudo components/dpdk/build/examples/dpdk-l3fwd -n 4 -l 2 -a 0001:01:00.0 -- -P -p 0x1 --config='(0,0,2)'
Test¶
For example, the typical output contains:
Initializing port 0 ... Creating queues: nb_rxq=1 nb_txq=1...
Address:98:03:9B:71:24:2E, Destination:02:00:00:00:00:00, Allocated mbuf pool on socket 0
LPM: Adding route 198.18.0.0 / 24 (0) [0001:01:00.0]
LPM: Adding route 2001:200:: / 64 (0) [0001:01:00.0]
txq=2,0,0
These logs show port 0 has MAC address 98:03:9B:71:24:2E with PCIe address
0001:01:00.0 on the DUT. 1 IPv4 route matching the subnet
198.18.0.0/24 is added.
Configure the traffic generator to send packets to the NIC port,
using the MAC and IP address displayed in the logs. In this example,
use a destination MAC address of 98:03:9B:71:24:2E and a destination
IP of 198.18.0.21. Then, dpdk-l3fwd will forward those packets out on port 0.
Stop¶
Stop the dpdk-l3fwd process with Control-C or kill. Next, if the NIC had been bound to a different Linux driver, rebind it to its original driver.
Find the original driver by running dpdk-devbind.py -s, and notice the unused= part of the PCIe address.
For example, sample output from dpdk-devbind.py -s may look like:
cd <nw_ds_workspace>/dataplane-stack
sudo components/dpdk/usertools/dpdk-devbind.py -s
Network devices using DPDK-compatible driver
============================================
0000:07:00.0 'Ethernet Controller XL710 for 40GbE QSFP+ 1583' drv=vfio-pci unused=i40e
...
In this example, bind 0000:07:00.0 to the i40e Linux driver using the following command
cd <nw_ds_workspace>/dataplane-stack
sudo components/dpdk/usertools/dpdk-devbind.py -b i40e 0000:07:00.0
VPP L3fwd¶
Note
Currently, the instructions provided in this section work with Mellanox NICs only.
Run¶
To run VPP:
cd <nw_ds_workspace>/dataplane-stack
sudo ./components/vpp/build-root/install-vpp-native/vpp/bin/vpp unix {interactive}
Note
It is possible that VPP may throw warnings and errors during initialization. These can be ignored safely.
Configure VPP with L3 interface and routes in VPP command prompt,
note the interface name enP1p1s0f0 below is obtained from above lshw command:
vpp# create interface rdma host-if enP1p1s0f0 name eth0
vpp# set interface mac address eth0 00:11:22:33:44:55
vpp# set interface ip address eth0 1.1.1.2/24
vpp# set interface state eth0 up
vpp# ip route add 198.18.0.0/24 via 1.1.1.1
vpp# set ip neighbor eth0 1.1.1.1 02:00:00:00:00:00
Test¶
After running the above command, configure the traffic generator to send packets to port 0
with a destination MAC address of 00:11:22:33:44:55 and an IP in the subnet 198.18.0.0/24.
vpp will forward those packets out on port 0.