Network Flow Processor (NFP) Kernel Drivers

Copyright:

© 2019, Netronome Systems, Inc.

Copyright:

© 2022, Corigine, Inc.

Contents

Overview

This driver supports Netronome and Corigine's line of Network Flow Processor devices, including the NFP3800, NFP4000, NFP5000, and NFP6000 models, which are also incorporated in the companies' family of Agilio SmartNICs. The SR-IOV physical and virtual functions for these devices are supported by the driver.

Acquiring Firmware

The NFP3800, NFP4000 and NFP6000 devices require application specific firmware to function. Application firmware can be located either on the host file system or in the device flash (if supported by management firmware).

Firmware files on the host filesystem contain card type (AMDA-* string), media config etc. They should be placed in /lib/firmware/netronome directory to load firmware from the host file system.

Firmware for basic NIC operation is available in the upstream linux-firmware.git repository.

A more comprehensive list of firmware can be downloaded from the Corigine Support site.

Firmware in NVRAM

Recent versions of management firmware supports loading application firmware from flash when the host driver gets probed. The firmware loading policy configuration may be used to configure this feature appropriately.

Devlink or ethtool can be used to update the application firmware on the device flash by providing the appropriate nic_AMDA*.nffw file to the respective command. Users need to take care to write the correct firmware image for the card and media configuration to flash.

Available storage space in flash depends on the card being used.

Dealing with multiple projects

NFP hardware is fully programmable therefore there can be different firmware images targeting different applications.

When using application firmware from host, we recommend placing actual firmware files in application-named subdirectories in /lib/firmware/netronome and linking the desired files, e.g.:

$ tree /lib/firmware/netronome/
/lib/firmware/netronome/
├── bpf
│   ├── nic_AMDA0081-0001_1x40.nffw
│   └── nic_AMDA0081-0001_4x10.nffw
├── flower
│   ├── nic_AMDA0081-0001_1x40.nffw
│   └── nic_AMDA0081-0001_4x10.nffw
├── nic
│   ├── nic_AMDA0081-0001_1x40.nffw
│   └── nic_AMDA0081-0001_4x10.nffw
├── nic_AMDA0081-0001_1x40.nffw -> bpf/nic_AMDA0081-0001_1x40.nffw
└── nic_AMDA0081-0001_4x10.nffw -> bpf/nic_AMDA0081-0001_4x10.nffw

3 directories, 8 files

You may need to use hard instead of symbolic links on distributions which use old mkinitrd command instead of dracut (e.g. Ubuntu).

After changing firmware files you may need to regenerate the initramfs image. Initramfs contains drivers and firmware files your system may need to boot. Refer to the documentation of your distribution to find out how to update initramfs. Good indication of stale initramfs is system loading wrong driver or firmware on boot, but when driver is later reloaded manually everything works correctly.

Selecting firmware per device

Most commonly all cards on the system use the same type of firmware. If you want to load a specific firmware image for a specific card, you can use either the PCI bus address or serial number. The driver will print which files it's looking for when it recognizes a NFP device:

nfp: Looking for firmware file in order of priority:
nfp:  netronome/serial-00-12-34-aa-bb-cc-10-ff.nffw: not found
nfp:  netronome/pci-0000:02:00.0.nffw: not found
nfp:  netronome/nic_AMDA0081-0001_1x40.nffw: found, loading...

In this case if file (or link) called serial-00-12-34-aa-bb-5d-10-ff.nffw or pci-0000:02:00.0.nffw is present in /lib/firmware/netronome this firmware file will take precedence over nic_AMDA* files.

Note that serial-* and pci-* files are not automatically included in initramfs, you will have to refer to documentation of appropriate tools to find out how to include them.

Running firmware version

The version of the loaded firmware for a particular <netdev> interface, (e.g. enp4s0), or an interface's port <netdev port> (e.g. enp4s0np0) can be displayed with the ethtool command:

$ ethtool -i <netdev>

Firmware loading policy

Firmware loading policy is controlled via three HWinfo parameters stored as key value pairs in the device flash:

app_fw_from_flash

Defines which firmware should take precedence, 'Disk' (0), 'Flash' (1) or the 'Preferred' (2) firmware. When 'Preferred' is selected, the management firmware makes the decision over which firmware will be loaded by comparing versions of the flash firmware and the host supplied firmware. This variable is configurable using the 'fw_load_policy' devlink parameter.

abi_drv_reset

Defines if the driver should reset the firmware when the driver is probed, either 'Disk' (0) if firmware was found on disk, 'Always' (1) reset or 'Never' (2) reset. Note that the device is always reset on driver unload if firmware was loaded when the driver was probed. This variable is configurable using the 'reset_dev_on_drv_probe' devlink parameter.

abi_drv_load_ifc

Defines a list of PF devices allowed to load FW on the device. This variable is not currently user configurable.

Configure Device

This section explains how to use Agilio SmartNICs running basic NIC firmware.

Configure interface Maximum Transmission Unit (MTU)

The MTU of interfaces can temporarily be set using the iproute2, ip link or ifconfig tools. Note that this change will not persist. Setting this via Network Manager, or another appropriate OS configuration tool, is recommended as changes to the MTU using Network Manager can be made to persist.

Set interface MTU to 9000 bytes:

$ ip link set dev <netdev port> mtu 9000

It is the responsibility of the user or the orchestration layer to set appropriate MTU values when handling jumbo frames or utilizing tunnels. For example, if packets sent from a VM are to be encapsulated on the card and egress a physical port, then the MTU of the VF should be set to lower than that of the physical port to account for the extra bytes added by the additional header. If a setup is expected to see fallback traffic between the SmartNIC and the kernel then the user should also ensure that the PF MTU is appropriately set to avoid unexpected drops on this path.

Configure Forward Error Correction (FEC) modes

Agilio SmartNICs support FEC mode configuration, e.g. Auto, Firecode Base-R, ReedSolomon and Off modes. Each physical port's FEC mode can be set independently using ethtool. The supported FEC modes for an interface can be viewed using:

$ ethtool <netdev>

The currently configured FEC mode can be viewed using:

$ ethtool --show-fec <netdev>

To force the FEC mode for a particular port, auto-negotiation must be disabled (see the Auto-negotiation section). An example of how to set the FEC mode to Reed-Solomon is:

$ ethtool --set-fec <netdev> encoding rs

Auto-negotiation

To change auto-negotiation settings, the link must first be put down. After the link is down, auto-negotiation can be enabled or disabled using:

ethtool -s <netdev> autoneg <on|off>

Statistics

Following device statistics are available through the ethtool -S interface:

NFP device statistics

Name

ID

Meaning

dev_rx_discards

1

Packet can be discarded on the RX path for one of the following reasons:

  • The NIC is not in promisc mode, and the destination MAC address doesn't match the interfaces' MAC address.

  • The received packet is larger than the max buffer size on the host. I.e. it exceeds the Layer 3 MRU.

  • There is no freelist descriptor available on the host for the packet. It is likely that the NIC couldn't cache one in time.

  • A BPF program discarded the packet.

  • The datapath drop action was executed.

  • The MAC discarded the packet due to lack of ingress buffer space on the NIC.

dev_rx_errors

2

A packet can be counted (and dropped) as RX error for the following reasons:

  • A problem with the VEB lookup (only when SR-IOV is used).

  • A physical layer problem that causes Ethernet errors, like FCS or alignment errors. The cause is usually faulty cables or SFPs.

dev_rx_bytes

3

Total number of bytes received.

dev_rx_uc_bytes

4

Unicast bytes received.

dev_rx_mc_bytes

5

Multicast bytes received.

dev_rx_bc_bytes

6

Broadcast bytes received.

dev_rx_pkts

7

Total number of packets received.

dev_rx_mc_pkts

8

Multicast packets received.

dev_rx_bc_pkts

9

Broadcast packets received.

dev_tx_discards

10

A packet can be discarded in the TX direction if the MAC is being flow controlled and the NIC runs out of TX queue space.

dev_tx_errors

11

A packet can be counted as TX error (and dropped) for one for the following reasons:

  • The packet is an LSO segment, but the Layer 3 or Layer 4 offset could not be determined. Therefore LSO could not continue.

  • An invalid packet descriptor was received over PCIe.

  • The packet Layer 3 length exceeds the device MTU.

  • An error on the MAC/physical layer. Usually due to faulty cables or SFPs.

  • A CTM buffer could not be allocated.

  • The packet offset was incorrect and could not be fixed by the NIC.

dev_tx_bytes

12

Total number of bytes transmitted.

dev_tx_uc_bytes

13

Unicast bytes transmitted.

dev_tx_mc_bytes

14

Multicast bytes transmitted.

dev_tx_bc_bytes

15

Broadcast bytes transmitted.

dev_tx_pkts

16

Total number of packets transmitted.

dev_tx_mc_pkts

17

Multicast packets transmitted.

dev_tx_bc_pkts

18

Broadcast packets transmitted.

Note that statistics unknown to the driver will be displayed as dev_unknown_stat$ID, where $ID refers to the second column above.