19. IXGBE Driver

19.1. Vector PMD for IXGBE

Vector PMD uses IntelĀ® SIMD instructions to optimize packet I/O. It improves load/store bandwidth efficiency of L1 data cache by using a wider SSE/AVX register 1 (1). The wider register gives space to hold multiple packet buffers so as to save instruction number when processing bulk of packets.

There is no change to PMD API. The RX/TX handler are the only two entries for vPMD packet I/O. They are transparently registered at runtime RX/TX execution if all condition checks pass.

  1. To date, only an SSE version of IX GBE vPMD is available. To ensure that vPMD is in the binary code, ensure that the option CONFIG_RTE_IXGBE_INC_VECTOR=y is in the configure file.

Some constraints apply as pre-conditions for specific optimizations on bulk packet transfers. The following sections explain RX and TX constraints in the vPMD.

19.1.1. RX Constraints

19.1.1.1. Prerequisites and Pre-conditions

The following prerequisites apply:

  • To enable vPMD to work for RX, bulk allocation for Rx must be allowed.

Ensure that the following pre-conditions are satisfied:

  • rxq->rx_free_thresh >= RTE_PMD_IXGBE_RX_MAX_BURST
  • rxq->rx_free_thresh < rxq->nb_rx_desc
  • (rxq->nb_rx_desc % rxq->rx_free_thresh) == 0
  • rxq->nb_rx_desc < (IXGBE_MAX_RING_DESC - RTE_PMD_IXGBE_RX_MAX_BURST)

These conditions are checked in the code.

Scattered packets are not supported in this mode. If an incoming packet is greater than the maximum acceptable length of one “mbuf” data size (by default, the size is 2 KB), vPMD for RX would be disabled.

By default, IXGBE_MAX_RING_DESC is set to 4096 and RTE_PMD_IXGBE_RX_MAX_BURST is set to 32.

19.1.1.2. Feature not Supported by RX Vector PMD

Some features are not supported when trying to increase the throughput in vPMD. They are:

  • IEEE1588
  • FDIR
  • Header split
  • RX checksum off load

Other features are supported using optional MACRO configuration. They include:

  • HW VLAN strip
  • HW extend dual VLAN

To guarantee the constraint, capabilities in dev_conf.rxmode.offloads will be checked:

  • DEV_RX_OFFLOAD_VLAN_STRIP
  • DEV_RX_OFFLOAD_VLAN_EXTEND
  • DEV_RX_OFFLOAD_CHECKSUM
  • DEV_RX_OFFLOAD_HEADER_SPLIT
  • dev_conf

fdir_conf->mode will also be checked.

19.1.1.3. RX Burst Size

As vPMD is focused on high throughput, it assumes that the RX burst size is equal to or greater than 32 per burst. It returns zero if using nb_pkt < 32 as the expected packet number in the receive handler.

19.1.2. TX Constraint

19.1.2.1. Prerequisite

The only prerequisite is related to tx_rs_thresh. The tx_rs_thresh value must be greater than or equal to RTE_PMD_IXGBE_TX_MAX_BURST, but less or equal to RTE_IXGBE_TX_MAX_FREE_BUF_SZ. Consequently, by default the tx_rs_thresh value is in the range 32 to 64.

19.1.2.2. Feature not Supported by TX Vector PMD

TX vPMD only works when offloads is set to 0

This means that it does not support any TX offload.

19.2. Application Programming Interface

In DPDK release v16.11 an API for ixgbe specific functions has been added to the ixgbe PMD. The declarations for the API functions are in the header rte_pmd_ixgbe.h.

19.3. Sample Application Notes

19.3.1. l3fwd

When running l3fwd with vPMD, there is one thing to note. In the configuration, ensure that DEV_RX_OFFLOAD_CHECKSUM in port_conf.rxmode.offloads is NOT set. Otherwise, by default, RX vPMD is disabled.

19.3.2. load_balancer

As in the case of l3fwd, to enable vPMD, do NOT set DEV_RX_OFFLOAD_CHECKSUM in port_conf.rxmode.offloads. In addition, for improved performance, use -bsz “(32,32),(64,64),(32,32)” in load_balancer to avoid using the default burst size of 144.

19.4. Limitations or Known issues

19.4.1. Malicious Driver Detection not Supported

The Intel x550 series NICs support a feature called MDD (Malicious Driver Detection) which checks the behavior of the VF driver. If this feature is enabled, the VF must use the advanced context descriptor correctly and set the CC (Check Context) bit. DPDK PF doesn’t support MDD, but kernel PF does. We may hit problem in this scenario kernel PF + DPDK VF. If user enables MDD in kernel PF, DPDK VF will not work. Because kernel PF thinks the VF is malicious. But actually it’s not. The only reason is the VF doesn’t act as MDD required. There’s significant performance impact to support MDD. DPDK should check if the advanced context descriptor should be set and set it. And DPDK has to ask the info about the header length from the upper layer, because parsing the packet itself is not acceptable. So, it’s too expensive to support MDD. When using kernel PF + DPDK VF on x550, please make sure to use a kernel PF driver that disables MDD or can disable MDD.

Some kernel drivers already disable MDD by default while some kernels can use the command insmod ixgbe.ko MDD=0,0 to disable MDD. Each “0” in the command refers to a port. For example, if there are 6 ixgbe ports, the command should be changed to insmod ixgbe.ko MDD=0,0,0,0,0,0.

19.4.2. Statistics

The statistics of ixgbe hardware must be polled regularly in order for it to remain consistent. Running a DPDK application without polling the statistics will cause registers on hardware to count to the maximum value, and “stick” at that value.

In order to avoid statistic registers every reaching the maximum value, read the statistics from the hardware using rte_eth_stats_get() or rte_eth_xstats_get().

The maximum time between statistics polls that ensures consistent results can be calculated as follows:

max_read_interval = UINT_MAX / max_packets_per_second
max_read_interval = 4294967295 / 14880952
max_read_interval = 288.6218096127183 (seconds)
max_read_interval = ~4 mins 48 sec.

In order to ensure valid results, it is recommended to poll every 4 minutes.

19.4.3. MTU setting

Although the user can set the MTU separately on PF and VF ports, the ixgbe NIC only supports one global MTU per physical port. So when the user sets different MTUs on PF and VF ports in one physical port, the real MTU for all these PF and VF ports is the largest value set. This behavior is based on the kernel driver behavior.

19.4.4. VF MAC address setting

On ixgbe, the concept of “pool” can be used for different things depending on the mode. In VMDq mode, “pool” means a VMDq pool. In IOV mode, “pool” means a VF.

There is no RTE API to add a VF’s MAC address from the PF. On ixgbe, the rte_eth_dev_mac_addr_add() function can be used to add a VF’s MAC address, as a workaround.

19.5. Inline crypto processing support

Inline IPsec processing is supported for RTE_SECURITY_ACTION_TYPE_INLINE_CRYPTO mode for ESP packets only:

  • ESP authentication only: AES-128-GMAC (128-bit key)
  • ESP encryption and authentication: AES-128-GCM (128-bit key)

IPsec Security Gateway Sample Application supports inline IPsec processing for ixgbe PMD.

For more details see the IPsec Security Gateway Sample Application and Security library documentation.

19.6. Virtual Function Port Representors

The IXGBE PF PMD supports the creation of VF port representors for the control and monitoring of IXGBE virtual function devices. Each port representor corresponds to a single virtual function of that device. Using the devargs option representor the user can specify which virtual functions to create port representors for on initialization of the PF PMD by passing the VF IDs of the VFs which are required.:

-w DBDF,representor=[0,1,4]

Currently hot-plugging of representor ports is not supported so all required representors must be specified on the creation of the PF.

19.7. Supported Chipsets and NICs

  • Intel 82599EB 10 Gigabit Ethernet Controller
  • Intel 82598EB 10 Gigabit Ethernet Controller
  • Intel 82599ES 10 Gigabit Ethernet Controller
  • Intel 82599EN 10 Gigabit Ethernet Controller
  • Intel Ethernet Controller X540-AT2
  • Intel Ethernet Controller X550-BT2
  • Intel Ethernet Controller X550-AT2
  • Intel Ethernet Controller X550-AT
  • Intel Ethernet Converged Network Adapter X520-SR1
  • Intel Ethernet Converged Network Adapter X520-SR2
  • Intel Ethernet Converged Network Adapter X520-LR1
  • Intel Ethernet Converged Network Adapter X520-DA1
  • Intel Ethernet Converged Network Adapter X520-DA2
  • Intel Ethernet Converged Network Adapter X520-DA4
  • Intel Ethernet Converged Network Adapter X520-QDA1
  • Intel Ethernet Converged Network Adapter X520-T2
  • Intel 10 Gigabit AF DA Dual Port Server Adapter
  • Intel 10 Gigabit AT Server Adapter
  • Intel 10 Gigabit AT2 Server Adapter
  • Intel 10 Gigabit CX4 Dual Port Server Adapter
  • Intel 10 Gigabit XF LR Server Adapter
  • Intel 10 Gigabit XF SR Dual Port Server Adapter
  • Intel 10 Gigabit XF SR Server Adapter
  • Intel Ethernet Converged Network Adapter X540-T1
  • Intel Ethernet Converged Network Adapter X540-T2
  • Intel Ethernet Converged Network Adapter X550-T1
  • Intel Ethernet Converged Network Adapter X550-T2