49. ThunderX NICVF Poll Mode Driver
The ThunderX NICVF PMD (librte_pmd_thunderx_nicvf) provides poll mode driver support for the inbuilt NIC found in the Cavium ThunderX SoC family as well as their virtual functions (VF) in SR-IOV context.
More information can be found at Cavium, Inc Official Website.
49.1. Features
Features of the ThunderX PMD are:
- Multiple queues for TX and RX
- Receive Side Scaling (RSS)
- Packet type information
- Checksum offload
- Promiscuous mode
- Multicast mode
- Port hardware statistics
- Jumbo frames
- Link state information
- Setting up link state.
- Scattered and gather for TX and RX
- VLAN stripping
- SR-IOV VF
- NUMA support
- Multi queue set support (up to 96 queues (12 queue sets)) per port
- Skip data bytes
49.2. Supported ThunderX SoCs
- CN88xx
- CN81xx
- CN83xx
49.3. Prerequisites
- Follow the DPDK Getting Started Guide for Linux to setup the basic DPDK environment.
49.4. Pre-Installation Configuration
49.4.1. Config File Options
The following options can be modified in the config
file.
Please note that enabling debugging options may affect system performance.
CONFIG_RTE_LIBRTE_THUNDERX_NICVF_PMD
(defaulty
)Toggle compilation of the
librte_pmd_thunderx_nicvf
driver.CONFIG_RTE_LIBRTE_THUNDERX_NICVF_DEBUG_RX
(defaultn
)Toggle asserts of receive fast path.
CONFIG_RTE_LIBRTE_THUNDERX_NICVF_DEBUG_TX
(defaultn
)Toggle asserts of transmit fast path.
49.5. Driver compilation and testing
Refer to the document compiling and testing a PMD for a NIC for details.
To compile the ThunderX NICVF PMD for Linux arm64 gcc, use arm64-thunderx-linux-gcc as target.
49.6. Linux
49.6.1. SR-IOV: Prerequisites and sample Application Notes
Current ThunderX NIC PF/VF kernel modules maps each physical Ethernet port automatically to virtual function (VF) and presented them as PCIe-like SR-IOV device. This section provides instructions to configure SR-IOV with Linux OS.
Verify PF devices capabilities using
lspci
:lspci -vvv
Example output:
0002:01:00.0 Ethernet controller: Cavium Networks Device a01e (rev 01) ... Capabilities: [100 v1] Alternative Routing-ID Interpretation (ARI) ... Capabilities: [180 v1] Single Root I/O Virtualization (SR-IOV) ... Kernel driver in use: thunder-nic ...
Note
Unless
thunder-nic
driver is in use make sure your kernel config includesCONFIG_THUNDER_NIC_PF
setting.Verify VF devices capabilities and drivers using
lspci
:lspci -vvv
Example output:
0002:01:00.1 Ethernet controller: Cavium Networks Device 0011 (rev 01) ... Capabilities: [100 v1] Alternative Routing-ID Interpretation (ARI) ... Kernel driver in use: thunder-nicvf ... 0002:01:00.2 Ethernet controller: Cavium Networks Device 0011 (rev 01) ... Capabilities: [100 v1] Alternative Routing-ID Interpretation (ARI) ... Kernel driver in use: thunder-nicvf ...
Note
Unless
thunder-nicvf
driver is in use make sure your kernel config includesCONFIG_THUNDER_NIC_VF
setting.Pass VF device to VM context (PCIe Passthrough):
The VF devices may be passed through to the guest VM using qemu or virt-manager or virsh etc.
Example qemu guest launch command:
sudo qemu-system-aarch64 -name vm1 \ -machine virt,gic_version=3,accel=kvm,usb=off \ -cpu host -m 4096 \ -smp 4,sockets=1,cores=8,threads=1 \ -nographic -nodefaults \ -kernel <kernel image> \ -append "root=/dev/vda console=ttyAMA0 rw hugepagesz=512M hugepages=3" \ -device vfio-pci,host=0002:01:00.1 \ -drive file=<rootfs.ext3>,if=none,id=disk1,format=raw \ -device virtio-blk-device,scsi=off,drive=disk1,id=virtio-disk1,bootindex=1 \ -netdev tap,id=net0,ifname=tap0,script=/etc/qemu-ifup_thunder \ -device virtio-net-device,netdev=net0 \ -serial stdio \ -mem-path /dev/hugepages
Enable VFIO-NOIOMMU mode (optional):
echo 1 > /sys/module/vfio/parameters/enable_unsafe_noiommu_mode
Note
VFIO-NOIOMMU is required only when running in VM context and should not be enabled otherwise.
Running testpmd:
Follow instructions available in the document compiling and testing a PMD for a NIC to run testpmd.
Example output:
./arm64-thunderx-linux-gcc/app/testpmd -l 0-3 -n 4 -w 0002:01:00.2 \ -- -i --no-flush-rx \ --port-topology=loop ... PMD: rte_nicvf_pmd_init(): librte_pmd_thunderx nicvf version 1.0 ... EAL: probe driver: 177d:11 rte_nicvf_pmd EAL: using IOMMU type 1 (Type 1) EAL: PCI memory mapped at 0x3ffade50000 EAL: Trying to map BAR 4 that contains the MSI-X table. Trying offsets: 0x40000000000:0x0000, 0x10000:0x1f0000 EAL: PCI memory mapped at 0x3ffadc60000 PMD: nicvf_eth_dev_init(): nicvf: device (177d:11) 2:1:0:2 PMD: nicvf_eth_dev_init(): node=0 vf=1 mode=tns-bypass sqs=false loopback_supported=true PMD: nicvf_eth_dev_init(): Port 0 (177d:11) mac=a6:c6:d9:17:78:01 Interactive-mode selected Configuring Port 0 (socket 0) ... PMD: nicvf_dev_configure(): Configured ethdev port0 hwcap=0x0 Port 0: A6:C6:D9:17:78:01 Checking link statuses... Port 0 Link Up - speed 10000 Mbps - full-duplex Done testpmd>
49.6.2. Multiple Queue Set per DPDK port configuration
There are two types of VFs:
- Primary VF
- Secondary VF
Each port consists of a primary VF and n secondary VF(s). Each VF provides 8 Tx/Rx queues to a port. When a given port is configured to use more than 8 queues, it requires one (or more) secondary VF. Each secondary VF adds 8 additional queues to the queue set.
During PMD driver initialization, the primary VF’s are enumerated by checking the specific flag (see sqs message in DPDK boot log - sqs indicates secondary queue set). They are at the beginning of VF list (the remain ones are secondary VF’s).
The primary VFs are used as master queue sets. Secondary VFs provide additional queue sets for primary ones. If a port is configured for more then 8 queues than it will request for additional queues from secondary VFs.
Secondary VFs cannot be shared between primary VFs.
Primary VFs are present on the beginning of the ‘Network devices using kernel driver’ list, secondary VFs are on the remaining on the remaining part of the list.
Note
The VNIC driver in the multiqueue setup works differently than other drivers like ixgbe. We need to bind separately each specific queue set device with the
usertools/dpdk-devbind.py
utility.Note
Depending on the hardware used, the kernel driver sets a threshold
vf_id
. VFs that try to attached with an id below or equal to this boundary are considered primary VFs. VFs that try to attach with an id above this boundary are considered secondary VFs.
49.6.3. LBK HW Access
Loopback HW Unit (LBK) receives packets from NIC-RX and sends packets back to NIC-TX. The loopback block has N channels and contains data buffering that is shared across all channels. Four primary VFs are reserved as loopback ports.
49.6.4. Example device binding
If a system has three interfaces, a total of 18 VF devices will be created on a non-NUMA machine.
Note
NUMA systems have 12 VFs per port and non-NUMA 6 VFs per port.
# usertools/dpdk-devbind.py --status Network devices using DPDK-compatible driver ============================================ <none> Network devices using kernel driver =================================== 0000:01:10.0 'THUNDERX BGX (Common Ethernet Interface) a026' if= drv=thunder-BGX unused=vfio-pci 0000:01:10.1 'THUNDERX BGX (Common Ethernet Interface) a026' if= drv=thunder-BGX unused=vfio-pci 0001:01:00.0 'THUNDERX Network Interface Controller a01e' if= drv=thunder-nic unused=vfio-pci 0001:01:00.1 'Device a034' if=eth0 drv=thunder-nicvf unused=vfio-pci 0001:01:00.2 'Device a034' if=eth1 drv=thunder-nicvf unused=vfio-pci 0001:01:00.3 'Device a034' if=eth2 drv=thunder-nicvf unused=vfio-pci 0001:01:00.4 'Device a034' if=eth3 drv=thunder-nicvf unused=vfio-pci 0001:01:00.5 'Device a034' if=eth4 drv=thunder-nicvf unused=vfio-pci 0001:01:00.6 'Device a034' if=lbk0 drv=thunder-nicvf unused=vfio-pci 0001:01:00.7 'Device a034' if=lbk1 drv=thunder-nicvf unused=vfio-pci 0001:01:01.0 'Device a034' if=lbk2 drv=thunder-nicvf unused=vfio-pci 0001:01:01.1 'Device a034' if=lbk3 drv=thunder-nicvf unused=vfio-pci 0001:01:01.2 'Device a034' if= drv=thunder-nicvf unused=vfio-pci 0001:01:01.3 'Device a034' if= drv=thunder-nicvf unused=vfio-pci 0001:01:01.4 'Device a034' if= drv=thunder-nicvf unused=vfio-pci 0001:01:01.5 'Device a034' if= drv=thunder-nicvf unused=vfio-pci 0001:01:01.6 'Device a034' if= drv=thunder-nicvf unused=vfio-pci 0001:01:01.7 'Device a034' if= drv=thunder-nicvf unused=vfio-pci 0001:01:02.0 'Device a034' if= drv=thunder-nicvf unused=vfio-pci 0001:01:02.1 'Device a034' if= drv=thunder-nicvf unused=vfio-pci 0001:01:02.2 'Device a034' if= drv=thunder-nicvf unused=vfio-pci Other network devices ===================== 0002:00:03.0 'Device a01f' unused=vfio-pci,uio_pci_genericNote
Here total no of primary VFs = 5 (variable, depends on no of ethernet ports present) + 4 (fixed, loopback ports). Ethernet ports are indicated as if=eth0 while loopback ports as if=lbk0.
We want to bind two physical interfaces with 24 queues each device, we attach two primary VFs and four secondary VFs. In our example we choose two 10G interfaces eth1 (0002:01:00.2) and eth2 (0002:01:00.3). We will choose four secondary queue sets from the ending of the list (0001:01:01.2-0002:01:02.2).
Bind two primary VFs to the
vfio-pci
driver:usertools/dpdk-devbind.py -b vfio-pci 0002:01:00.2 usertools/dpdk-devbind.py -b vfio-pci 0002:01:00.3
Bind four primary VFs to the
vfio-pci
driver:usertools/dpdk-devbind.py -b vfio-pci 0002:01:01.7 usertools/dpdk-devbind.py -b vfio-pci 0002:01:02.0 usertools/dpdk-devbind.py -b vfio-pci 0002:01:02.1 usertools/dpdk-devbind.py -b vfio-pci 0002:01:02.2
The nicvf thunderx driver will make use of attached secondary VFs automatically during the interface configuration stage.
49.6.5. Thunder-nic VF’s
- Use sysfs to distinguish thunder-nic primary VFs and secondary VFs.
ls -l /sys/bus/pci/drivers/thunder-nic/ total 0 drwxr-xr-x 2 root root 0 Jan 22 11:19 ./ drwxr-xr-x 86 root root 0 Jan 22 11:07 ../ lrwxrwxrwx 1 root root 0 Jan 22 11:19 0001:01:00.0 -> '../../../../devices/platform/soc@0/849000000000.pci/pci0001:00/0001:00:10.0/0001:01:00.0'/
cat /sys/bus/pci/drivers/thunder-nic/0001\:01\:00.0/sriov_sqs_assignment 12 0 0001:01:00.1 vfio-pci +: 12 13 1 0001:01:00.2 thunder-nicvf -: 2 0001:01:00.3 thunder-nicvf -: 3 0001:01:00.4 thunder-nicvf -: 4 0001:01:00.5 thunder-nicvf -: 5 0001:01:00.6 thunder-nicvf -: 6 0001:01:00.7 thunder-nicvf -: 7 0001:01:01.0 thunder-nicvf -: 8 0001:01:01.1 thunder-nicvf -: 9 0001:01:01.2 thunder-nicvf -: 10 0001:01:01.3 thunder-nicvf -: 11 0001:01:01.4 thunder-nicvf -: 12 0001:01:01.5 vfio-pci: 0 13 0001:01:01.6 vfio-pci: 0 14 0001:01:01.7 thunder-nicvf: 255 15 0001:01:02.0 thunder-nicvf: 255 16 0001:01:02.1 thunder-nicvf: 255 17 0001:01:02.2 thunder-nicvf: 255 18 0001:01:02.3 thunder-nicvf: 255 19 0001:01:02.4 thunder-nicvf: 255 20 0001:01:02.5 thunder-nicvf: 255 21 0001:01:02.6 thunder-nicvf: 255 22 0001:01:02.7 thunder-nicvf: 255 23 0001:01:03.0 thunder-nicvf: 255 24 0001:01:03.1 thunder-nicvf: 255 25 0001:01:03.2 thunder-nicvf: 255 26 0001:01:03.3 thunder-nicvf: 255 27 0001:01:03.4 thunder-nicvf: 255 28 0001:01:03.5 thunder-nicvf: 255 29 0001:01:03.6 thunder-nicvf: 255 30 0001:01:03.7 thunder-nicvf: 255 31 0001:01:04.0 thunder-nicvf: 255
Every column that ends with ‘thunder-nicvf: number’ can be used as secondary VF. In printout above all entres after ‘14 0001:01:01.7 thunder-nicvf: 255’ can be used as secondary VF.
49.7. Debugging Options
- EAL command option to change log level
--log-level=pmd.net.thunderx.driver:info or --log-level=pmd.net.thunderx.driver,7
49.8. Module params
49.8.1. skip_data_bytes
This feature is used to create a hole between HEADROOM and actual data. Size of hole is specified in bytes as module param(“skip_data_bytes”) to pmd. This scheme is useful when application would like to insert vlan header without disturbing HEADROOM.
- Example:
-w 0002:01:00.2,skip_data_bytes=8
49.9. Limitations
49.9.1. CRC stripping
The ThunderX SoC family NICs strip the CRC for every packets coming into the host interface irrespective of the offload configuration.
49.9.2. Maximum packet length
The ThunderX SoC family NICs support a maximum of a 9K jumbo frame. The value
is fixed and cannot be changed. So, even when the rxmode.max_rx_pkt_len
member of struct rte_eth_conf
is set to a value lower than 9200, frames
up to 9200 bytes can still reach the host interface.
49.9.3. Maximum packet segments
The ThunderX SoC family NICs support up to 12 segments per packet when working
in scatter/gather mode. So, setting MTU will result with EINVAL
when the
frame size does not fit in the maximum number of segments.
49.9.4. skip_data_bytes
Maximum limit of skip_data_bytes is 128 bytes and number of bytes should be multiple of 8.