14. ENIC Poll Mode Driver

ENIC PMD is the DPDK poll-mode driver for the Cisco System Inc. VIC Ethernet NICs. These adapters are also referred to as vNICs below. If you are running or would like to run DPDK software applications on Cisco UCS servers using Cisco VIC adapters the following documentation is relevant.

14.1. How to obtain ENIC PMD integrated DPDK

ENIC PMD support is integrated into the DPDK suite. dpdk-<version>.tar.gz should be downloaded from http://core.dpdk.org/download/

14.2. Configuration information

  • DPDK Configuration Parameters

    The following configuration options are available for the ENIC PMD:

    • CONFIG_RTE_LIBRTE_ENIC_PMD (default y): Enables or disables inclusion of the ENIC PMD driver in the DPDK compilation.
  • vNIC Configuration Parameters

    • Number of Queues

      The maximum number of receive queues (RQs), work queues (WQs) and completion queues (CQs) are configurable on a per vNIC basis through the Cisco UCS Manager (CIMC or UCSM).

      These values should be configured as follows:

      • The number of WQs should be greater or equal to the value of the expected nb_tx_q parameter in the call to rte_eth_dev_configure()
      • The number of RQs configured in the vNIC should be greater or equal to twice the value of the expected nb_rx_q parameter in the call to rte_eth_dev_configure(). With the addition of Rx scatter, a pair of RQs on the vnic is needed for each receive queue used by DPDK, even if Rx scatter is not being used. Having a vNIC with only 1 RQ is not a valid configuration, and will fail with an error message.
      • The number of CQs should set so that there is one CQ for each WQ, and one CQ for each pair of RQs.

      For example: If the application requires 3 Rx queues, and 3 Tx queues, the vNIC should be configured to have at least 3 WQs, 6 RQs (3 pairs), and 6 CQs (3 for use by WQs + 3 for use by the 3 pairs of RQs).

    • Size of Queues

      Likewise, the number of receive and transmit descriptors are configurable on a per-vNIC basis via the UCS Manager and should be greater than or equal to the nb_rx_desc and nb_tx_desc parameters expected to be used in the calls to rte_eth_rx_queue_setup() and rte_eth_tx_queue_setup() respectively. An application requesting more than the set size will be limited to that size.

      Unless there is a lack of resources due to creating many vNICs, it is recommended that the WQ and RQ sizes be set to the maximum. This gives the application the greatest amount of flexibility in its queue configuration.

      • Note: Since the introduction of Rx scatter, for performance reasons, this PMD uses two RQs on the vNIC per receive queue in DPDK. One RQ holds descriptors for the start of a packet, and the second RQ holds the descriptors for the rest of the fragments of a packet. This means that the nb_rx_desc parameter to rte_eth_rx_queue_setup() can be a greater than 4096. The exact amount will depend on the size of the mbufs being used for receives, and the MTU size.

        For example: If the mbuf size is 2048, and the MTU is 9000, then receiving a full size packet will take 5 descriptors, 1 from the start-of-packet queue, and 4 from the second queue. Assuming that the RQ size was set to the maximum of 4096, then the application can specify up to 1024 + 4096 as the nb_rx_desc parameter to rte_eth_rx_queue_setup().

    • Interrupts

      At least one interrupt per vNIC interface should be configured in the UCS manager regardless of the number receive/transmit queues. The ENIC PMD uses this interrupt to get information about link status and errors in the fast path.

      In addition to the interrupt for link status and errors, when using Rx queue interrupts, increase the number of configured interrupts so that there is at least one interrupt for each Rx queue. For example, if the app uses 3 Rx queues and wants to use per-queue interrupts, configure 4 (3 + 1) interrupts.

    • Receive Side Scaling

      In order to fully utilize RSS in DPDK, enable all RSS related settings in CIMC or UCSM. These include the following items listed under Receive Side Scaling: TCP, IPv4, TCP-IPv4, IPv6, TCP-IPv6, IPv6 Extension, TCP-IPv6 Extension.

14.3. Flow director support

Advanced filtering support was added to 1300 series VIC firmware starting with version 2.0.13 for C-series UCS servers and version 3.1.2 for UCSM managed blade servers. In order to enable advanced filtering the ‘Advanced filter’ radio button should be enabled via CIMC or UCSM followed by a reboot of the server.

With advanced filters, perfect matching of all fields of IPv4, IPv6 headers as well as TCP, UDP and SCTP L4 headers is available through flow director. Masking of these fields for partial match is also supported.

Without advanced filter support, the flow director is limited to IPv4 perfect filtering of the 5-tuple with no masking of fields supported.

14.4. SR-IOV mode utilization

UCS blade servers configured with dynamic vNIC connection policies in UCSM are capable of supporting SR-IOV. SR-IOV virtual functions (VFs) are specialized vNICs, distinct from regular Ethernet vNICs. These VFs can be directly assigned to virtual machines (VMs) as ‘passthrough’ devices.

In UCS, SR-IOV VFs require the use of the Cisco Virtual Machine Fabric Extender (VM-FEX), which gives the VM a dedicated interface on the Fabric Interconnect (FI). Layer 2 switching is done at the FI. This may eliminate the requirement for software switching on the host to route intra-host VM traffic.

Please refer to Creating a Dynamic vNIC Connection Policy for information on configuring SR-IOV adapter policies and port profiles using UCSM.

Once the policies are in place and the host OS is rebooted, VFs should be visible on the host, E.g.:

# lspci | grep Cisco | grep Ethernet
0d:00.0 Ethernet controller: Cisco Systems Inc VIC Ethernet NIC (rev a2)
0d:00.1 Ethernet controller: Cisco Systems Inc VIC SR-IOV VF (rev a2)
0d:00.2 Ethernet controller: Cisco Systems Inc VIC SR-IOV VF (rev a2)
0d:00.3 Ethernet controller: Cisco Systems Inc VIC SR-IOV VF (rev a2)
0d:00.4 Ethernet controller: Cisco Systems Inc VIC SR-IOV VF (rev a2)
0d:00.5 Ethernet controller: Cisco Systems Inc VIC SR-IOV VF (rev a2)
0d:00.6 Ethernet controller: Cisco Systems Inc VIC SR-IOV VF (rev a2)
0d:00.7 Ethernet controller: Cisco Systems Inc VIC SR-IOV VF (rev a2)

Enable Intel IOMMU on the host and install KVM and libvirt, and reboot again as required. Then, using libvirt, create a VM instance with an assigned device. Below is an example interface block (part of the domain configuration XML) that adds the host VF 0d:00:01 to the VM. profileid='pp-vlan-25' indicates the port profile that has been configured in UCSM.

<interface type='hostdev' managed='yes'>
  <mac address='52:54:00:ac:ff:b6'/>
  <driver name='vfio'/>
  <source>
    <address type='pci' domain='0x0000' bus='0x0d' slot='0x00' function='0x1'/>
  </source>
  <virtualport type='802.1Qbh'>
    <parameters profileid='pp-vlan-25'/>
  </virtualport>
</interface>

Alternatively, the configuration can be done in a separate file using the network keyword. These methods are described in the libvirt documentation for Network XML format.

When the VM instance is started, libvirt will bind the host VF to vfio, complete provisioning on the FI and bring up the link.

Note

It is not possible to use a VF directly from the host because it is not fully provisioned until libvirt brings up the VM that it is assigned to.

In the VM instance, the VF will now be visible. E.g., here the VF 00:04.0 is seen on the VM instance and should be available for binding to a DPDK.

# lspci | grep Ether
00:04.0 Ethernet controller: Cisco Systems Inc VIC SR-IOV VF (rev a2)

Follow the normal DPDK install procedure, binding the VF to either igb_uio or vfio in non-IOMMU mode.

In the VM, the kernel enic driver may be automatically bound to the VF during boot. Unbinding it currently hangs due to a known issue with the driver. To work around the issue, blacklist the enic module as follows. Please see Limitations for limitations in the use of SR-IOV.

# cat /etc/modprobe.d/enic.conf
blacklist enic

# dracut --force

Note

Passthrough does not require SR-IOV. If VM-FEX is not desired, the user may create as many regular vNICs as necessary and assign them to VMs as passthrough devices. Since these vNICs are not SR-IOV VFs, using them as passthrough devices do not require libvirt, port profiles, and VM-FEX.

14.5. Generic Flow API support

Generic Flow API is supported. The baseline support is:

  • 1200 series VICs

    5-tuple exact flow support for 1200 series adapters. This allows:

    • Attributes: ingress
    • Items: ipv4, ipv6, udp, tcp (must exactly match src/dst IP addresses and ports and all must be specified)
    • Actions: queue and void
    • Selectors: ‘is’
  • 1300 and later series VICS with advanced filters disabled

    With advanced filters disabled, an IPv4 or IPv6 item must be specified in the pattern.

    • Attributes: ingress
    • Items: eth, ipv4, ipv6, udp, tcp, vxlan, inner eth, ipv4, ipv6, udp, tcp
    • Actions: queue and void
    • Selectors: ‘is’, ‘spec’ and ‘mask’. ‘last’ is not supported
    • In total, up to 64 bytes of mask is allowed across all headers
  • 1300 and later series VICS with advanced filters enabled

    • Attributes: ingress
    • Items: eth, ipv4, ipv6, udp, tcp, vxlan, inner eth, ipv4, ipv6, udp, tcp
    • Actions: queue, mark, drop, flag and void
    • Selectors: ‘is’, ‘spec’ and ‘mask’. ‘last’ is not supported
    • In total, up to 64 bytes of mask is allowed across all headers

More features may be added in future firmware and new versions of the VIC. Please refer to the release notes.

14.6. Overlay Offload

Recent hardware models support overlay offload. When enabled, the NIC performs the following operations for VXLAN, NVGRE, and GENEVE packets. In all cases, inner and outer packets can be IPv4 or IPv6.

  • TSO for VXLAN and GENEVE packets.

    Hardware supports NVGRE TSO, but DPDK currently has no NVGRE offload flags.

  • Tx checksum offloads.

    The NIC fills in IPv4/UDP/TCP checksums for both inner and outer packets.

  • Rx checksum offloads.

    The NIC validates IPv4/UDP/TCP checksums of both inner and outer packets. Good checksum flags (e.g. PKT_RX_L4_CKSUM_GOOD) indicate that the inner packet has the correct checksum, and if applicable, the outer packet also has the correct checksum. Bad checksum flags (e.g. PKT_RX_L4_CKSUM_BAD) indicate that the inner and/or outer packets have invalid checksum values.

  • Inner Rx packet type classification

    PMD sets inner L3/L4 packet types (e.g. RTE_PTYPE_INNER_L4_TCP), and RTE_PTYPE_TUNNEL_GRENAT to indicate that the packet is tunneled. PMD does not set L3/L4 packet types for outer packets.

  • Inner RSS

    RSS hash calculation, therefore queue selection, is done on inner packets.

In order to enable overlay offload, the ‘Enable VXLAN’ box should be checked via CIMC or UCSM followed by a reboot of the server. When PMD successfully enables overlay offload, it prints the following message on the console.

Overlay offload is enabled

By default, PMD enables overlay offload if hardware supports it. To disable it, set devargs parameter disable-overlay=1. For example:

-w 12:00.0,disable-overlay=1

By default, the NIC uses 4789 as the VXLAN port. The user may change it through rte_eth_dev_udp_tunnel_port_{add,delete}. However, as the current NIC has a single VXLAN port number, the user cannot configure multiple port numbers.

14.7. Ingress VLAN Rewrite

VIC adapters can tag, untag, or modify the VLAN headers of ingress packets. The ingress VLAN rewrite mode controls this behavior. By default, it is set to pass-through, where the NIC does not modify the VLAN header in any way so that the application can see the original header. This mode is sufficient for many applications, but may not be suitable for others. Such applications may change the mode by setting devargs parameter ig-vlan-rewrite to one of the following.

  • pass: Pass-through mode. The NIC does not modify the VLAN header. This is the default mode.
  • priority: Priority-tag default VLAN mode. If the ingress packet is tagged with the default VLAN, the NIC replaces its VLAN header with the priority tag (VLAN ID 0).
  • trunk: Default trunk mode. The NIC tags untagged ingress packets with the default VLAN. Tagged ingress packets are not modified. To the application, every packet appears as tagged.
  • untag: Untag default VLAN mode. If the ingress packet is tagged with the default VLAN, the NIC removes or untags its VLAN header so that the application sees an untagged packet. As a result, the default VLAN becomes untagged. This mode can be useful for applications such as OVS-DPDK performance benchmarks that utilize only the default VLAN and want to see only untagged packets.

14.8. Limitations

  • VLAN 0 Priority Tagging

    If a vNIC is configured in TRUNK mode by the UCS manager, the adapter will priority tag egress packets according to 802.1Q if they were not already VLAN tagged by software. If the adapter is connected to a properly configured switch, there will be no unexpected behavior.

    In test setups where an Ethernet port of a Cisco adapter in TRUNK mode is connected point-to-point to another adapter port or connected though a router instead of a switch, all ingress packets will be VLAN tagged. Programs such as l3fwd may not account for VLAN tags in packets and may misbehave. One solution is to enable VLAN stripping on ingress so the VLAN tag is removed from the packet and put into the mbuf->vlan_tci field. Here is an example of how to accomplish this:

vlan_offload = rte_eth_dev_get_vlan_offload(port);
vlan_offload |= ETH_VLAN_STRIP_OFFLOAD;
rte_eth_dev_set_vlan_offload(port, vlan_offload);

Another alternative is modify the adapter’s ingress VLAN rewrite mode so that packets with the default VLAN tag are stripped by the adapter and presented to DPDK as untagged packets. In this case mbuf->vlan_tci and the PKT_RX_VLAN and PKT_RX_VLAN_STRIPPED mbuf flags would not be set. This mode is enabled with the devargs parameter ig-vlan-rewrite=untag. For example:

-w 12:00.0,ig-vlan-rewrite=untag
  • Limited flow director support on 1200 series and 1300 series Cisco VIC adapters with old firmware. Please see Flow director support.
  • Flow director features are not supported on generation 1 Cisco VIC adapters (M81KR and P81E)
  • SR-IOV
    • KVM hypervisor support only. VMware has not been tested.
    • Requires VM-FEX, and so is only available on UCS managed servers connected to Fabric Interconnects. It is not on standalone C-Series servers.
    • VF devices are not usable directly from the host. They can only be used as assigned devices on VM instances.
    • Currently, unbind of the ENIC kernel mode driver ‘enic.ko’ on the VM instance may hang. As a workaround, enic.ko should be blacklisted or removed from the boot process.
    • pci_generic cannot be used as the uio module in the VM. igb_uio or vfio in non-IOMMU mode can be used.
    • The number of RQs in UCSM dynamic vNIC configurations must be at least 2.
    • The number of SR-IOV devices is limited to 256. Components on target system might limit this number to fewer than 256.
  • Flow API
    • The number of filters that can be specified with the Generic Flow API is dependent on how many header fields are being masked. Use ‘flow create’ in a loop to determine how many filters your VIC will support (not more than 1000 for 1300 series VICs). Filters are checked for matching in the order they were added. Since there currently is no grouping or priority support, ‘catch-all’ filters should be added last.
  • Statistics
    • rx_good_bytes (ibytes) always includes VLAN header (4B) and CRC bytes (4B). This behavior applies to 1300 and older series VIC adapters. 1400 series VICs do not count CRC bytes, and count VLAN header only when VLAN stripping is disabled.
    • When the NIC drops a packet because the Rx queue has no free buffers, rx_good_bytes still increments by 4B if the packet is not VLAN tagged or VLAN stripping is disabled, or by 8B if the packet is VLAN tagged and stripping is enabled. This behavior applies to 1300 and older series VIC adapters. 1400 series VICs do not increment this byte counter when packets are dropped.
  • RSS Hashing
    • Hardware enables and disables UDP and TCP RSS hashing together. The driver cannot control UDP and TCP hashing individually.

14.9. How to build the suite

The build instructions for the DPDK suite should be followed. By default the ENIC PMD library will be built into the DPDK library.

Refer to the document compiling and testing a PMD for a NIC for details.

For configuring and using UIO and VFIO frameworks, please refer to the documentation that comes with DPDK suite.

14.10. Supported Cisco VIC adapters

ENIC PMD supports all recent generations of Cisco VIC adapters including:

  • VIC 1200 series
  • VIC 1300 series
  • VIC 1400 series

14.11. Supported Operating Systems

Any Linux distribution fulfilling the conditions described in Dependencies section of DPDK documentation.

14.12. Supported features

  • Unicast, multicast and broadcast transmission and reception
  • Receive queue polling
  • Port Hardware Statistics
  • Hardware VLAN acceleration
  • IP checksum offload
  • Receive side VLAN stripping
  • Multiple receive and transmit queues
  • Flow Director ADD, UPDATE, DELETE, STATS operation support IPv4 and IPv6
  • Promiscuous mode
  • Setting RX VLAN (supported via UCSM/CIMC only)
  • VLAN filtering (supported via UCSM/CIMC only)
  • Execution of application by unprivileged system users
  • IPV4, IPV6 and TCP RSS hashing
  • UDP RSS hashing (1400 series and later adapters)
  • Scattered Rx
  • MTU update
  • SR-IOV on UCS managed servers connected to Fabric Interconnects
  • Flow API
  • Overlay offload
    • Rx/Tx checksum offloads for VXLAN, NVGRE, GENEVE
    • TSO for VXLAN and GENEVE packets
    • Inner RSS

14.13. Known bugs and unsupported features in this release

  • Signature or flex byte based flow direction
  • Drop feature of flow direction
  • VLAN based flow direction
  • Non-IPV4 flow direction
  • Setting of extended VLAN
  • MTU update only works if Scattered Rx mode is disabled
  • Maximum receive packet length is ignored if Scattered Rx mode is used

14.14. Prerequisites

  • Prepare the system as recommended by DPDK suite. This includes environment variables, hugepages configuration, tool-chains and configuration.
  • Insert vfio-pci kernel module using the command ‘modprobe vfio-pci’ if the user wants to use VFIO framework.
  • Insert uio kernel module using the command ‘modprobe uio’ if the user wants to use UIO framework.
  • DPDK suite should be configured based on the user’s decision to use VFIO or UIO framework.
  • If the vNIC device(s) to be used is bound to the kernel mode Ethernet driver use ‘ip’ to bring the interface down. The dpdk-devbind.py tool can then be used to unbind the device’s bus id from the ENIC kernel mode driver.
  • Bind the intended vNIC to vfio-pci in case the user wants ENIC PMD to use VFIO framework using dpdk-devbind.py.
  • Bind the intended vNIC to igb_uio in case the user wants ENIC PMD to use UIO framework using dpdk-devbind.py.

At this point the system should be ready to run DPDK applications. Once the application runs to completion, the vNIC can be detached from vfio-pci or igb_uio if necessary.

Root privilege is required to bind and unbind vNICs to/from VFIO/UIO. VFIO framework helps an unprivileged user to run the applications. For an unprivileged user to run the applications on DPDK and ENIC PMD, it may be necessary to increase the maximum locked memory of the user. The following command could be used to do this.

sudo sh -c "ulimit -l <value in Kilo Bytes>"

The value depends on the memory configuration of the application, DPDK and PMD. Typically, the limit has to be raised to higher than 2GB. e.g., 2621440

The compilation of any unused drivers can be disabled using the configuration file in config/ directory (e.g., config/common_linuxapp). This would help in bringing down the time taken for building the libraries and the initialization time of the application.

14.16. Contact Information

Any questions or bugs should be reported to DPDK community and to the ENIC PMD maintainers: