54. Poll Mode Driver for Emulated Virtio NIC

Virtio is a para-virtualization framework initiated by IBM, and supported by KVM hypervisor. In the Data Plane Development Kit (DPDK), we provide a virtio Poll Mode Driver (PMD) as a software solution, comparing to SRIOV hardware solution, for fast guest VM to guest VM communication and guest VM to host communication.

Vhost is a kernel acceleration module for virtio qemu backend. The DPDK extends kni to support vhost raw socket interface, which enables vhost to directly read/ write packets from/to a physical port. With this enhancement, virtio could achieve quite promising performance.

For basic qemu-KVM installation and other Intel EM poll mode driver in guest VM, please refer to Chapter “Driver for VM Emulated Devices”.

In this chapter, we will demonstrate usage of virtio PMD with two backends, standard qemu vhost back end and vhost kni back end.

54.1. Virtio Implementation in DPDK

For details about the virtio spec, refer to the latest VIRTIO (Virtual I/O) Device Specification.

As a PMD, virtio provides packet reception and transmission callbacks.

In Rx, packets described by the used descriptors in vring are available for virtio to burst out.

In Tx, packets described by the used descriptors in vring are available for virtio to clean. Virtio will enqueue to be transmitted packets into vring, make them available to the device, and then notify the host back end if necessary.

54.2. Features and Limitations of virtio PMD

In this release, the virtio PMD provides the basic functionality of packet reception and transmission.

  • It supports merge-able buffers per packet when receiving packets and scattered buffer per packet when transmitting packets. The packet size supported is from 64 to 1518.
  • It supports multicast packets and promiscuous mode.
  • The descriptor number for the Rx/Tx queue is hard-coded to be 256 by qemu 2.7 and below. If given a different descriptor number by the upper application, the virtio PMD generates a warning and fall back to the hard-coded value. Rx queue size can be configurable and up to 1024 since qemu 2.8 and above. Rx queue size is 256 by default. Tx queue size is still hard-coded to be 256.
  • Features of mac/vlan filter are supported, negotiation with vhost/backend are needed to support them. When backend can’t support vlan filter, virtio app on guest should not enable vlan filter in order to make sure the virtio port is configured correctly. E.g. do not specify ‘–enable-hw-vlan’ in testpmd command line. Note that, mac/vlan filter is best effort: unwanted packets could still arrive.
  • “RTE_PKTMBUF_HEADROOM” should be defined no less than “sizeof(struct virtio_net_hdr_mrg_rxbuf)”, which is 12 bytes when mergeable or “VIRTIO_F_VERSION_1” is set. no less than “sizeof(struct virtio_net_hdr)”, which is 10 bytes, when using non-mergeable.
  • Virtio does not support runtime configuration.
  • Virtio supports Link State interrupt.
  • Virtio supports Rx interrupt (so far, only support 1:1 mapping for queue/interrupt).
  • Virtio supports software vlan stripping and inserting.
  • Virtio supports using port IO to get PCI resource when UIO module is not available.
  • Virtio supports RSS Rx mode with 40B configurable hash key length, 128 configurable RETA entries and configurable hash types.

54.3. Prerequisites

The following prerequisites apply:

  • In the BIOS, turn VT-x and VT-d on
  • Linux kernel with KVM module; vhost module loaded and ioeventfd supported. Qemu standard backend without vhost support isn’t tested, and probably isn’t supported.
  • When using legacy interface, SYS_RAWIO capability is required for iopl() call to enable access to PCI I/O ports.

54.4. Virtio with kni vhost Back End

This section demonstrates kni vhost back end example setup for Phy-VM Communication.

../_images/host_vm_comms.png

Fig. 54.8 Host2VM Communication Example Using kni vhost Back End

Host2VM communication example

  1. Load the kni kernel module:

    insmod rte_kni.ko
    

    Other basic DPDK preparations like hugepage enabling, UIO port binding are not listed here. Please refer to the DPDK Getting Started Guide for detailed instructions.

  2. Launch the kni user application:

    <build_dir>/examples/dpdk-kni -l 0-3 -n 4 -- -p 0x1 -P --config="(0,1,3)"
    

    This command generates one network device vEth0 for physical port. If specify more physical ports, the generated network device will be vEth1, vEth2, and so on.

    For each physical port, kni creates two user threads. One thread loops to fetch packets from the physical NIC port into the kni receive queue. The other user thread loops to send packets in the kni transmit queue.

    For each physical port, kni also creates a kernel thread that retrieves packets from the kni receive queue, place them onto kni’s raw socket’s queue and wake up the vhost kernel thread to exchange packets with the virtio virt queue.

    For more details about kni, please refer to Kernel NIC Interface.

  3. Enable the kni raw socket functionality for the specified physical NIC port, get the generated file descriptor and set it in the qemu command line parameter. Always remember to set ioeventfd_on and vhost_on.

    Example:

    echo 1 > /sys/class/net/vEth0/sock_en
    fd=`cat /sys/class/net/vEth0/sock_fd`
    exec qemu-system-x86_64 -enable-kvm -cpu host \
    -m 2048 -smp 4 -name dpdk-test1-vm1 \
    -drive file=/data/DPDKVMS/dpdk-vm.img \
    -netdev tap, fd=$fd,id=mynet_kni, script=no,vhost=on \
    -device virtio-net-pci,netdev=mynet_kni,bus=pci.0,addr=0x3,ioeventfd=on \
    -vnc:1 -daemonize
    

    In the above example, virtio port 0 in the guest VM will be associated with vEth0, which in turns corresponds to a physical port, which means received packets come from vEth0, and transmitted packets is sent to vEth0.

  4. In the guest, bind the virtio device to the uio_pci_generic kernel module and start the forwarding application. When the virtio port in guest bursts Rx, it is getting packets from the raw socket’s receive queue. When the virtio port bursts Tx, it is sending packet to the tx_q.

    modprobe uio
    dpdk-hugepages.py --setup 1G
    modprobe uio_pci_generic
    ./usertools/dpdk-devbind.py -b uio_pci_generic 00:03.0
    

    We use testpmd as the forwarding application in this example.

    ../_images/console.png

    Fig. 54.9 Running testpmd

  5. Use IXIA packet generator to inject a packet stream into the KNI physical port.

    The packet reception and transmission flow path is:

    IXIA packet generator->82599 PF->KNI Rx queue->KNI raw socket queue->Guest VM virtio port 0 Rx burst->Guest VM virtio port 0 Tx burst-> KNI Tx queue ->82599 PF-> IXIA packet generator

54.5. Virtio with qemu virtio Back End

../_images/host_vm_comms_qemu.png

Fig. 54.10 Host2VM Communication Example Using qemu vhost Back End

qemu-system-x86_64 -enable-kvm -cpu host -m 2048 -smp 2 -mem-path /dev/
hugepages -mem-prealloc
-drive file=/data/DPDKVMS/dpdk-vm1
-netdev tap,id=vm1_p1,ifname=tap0,script=no,vhost=on
-device virtio-net-pci,netdev=vm1_p1,bus=pci.0,addr=0x3,ioeventfd=on
-device pci-assign,host=04:10.1 \

In this example, the packet reception flow path is:

IXIA packet generator->82599 PF->Linux Bridge->TAP0’s socket queue-> Guest VM virtio port 0 Rx burst-> Guest VM 82599 VF port1 Tx burst-> IXIA packet generator

The packet transmission flow is:

IXIA packet generator-> Guest VM 82599 VF port1 Rx burst-> Guest VM virtio port 0 Tx burst-> tap -> Linux Bridge->82599 PF-> IXIA packet generator

54.6. Virtio PMD Rx/Tx Callbacks

Virtio driver has 6 Rx callbacks and 3 Tx callbacks.

Rx callbacks:

  1. virtio_recv_pkts: Regular version without mergeable Rx buffer support for split virtqueue.
  2. virtio_recv_mergeable_pkts: Regular version with mergeable Rx buffer support for split virtqueue.
  3. virtio_recv_pkts_vec: Vector version without mergeable Rx buffer support, also fixes the available ring indexes and uses vector instructions to optimize performance for split virtqueue.
  4. virtio_recv_pkts_inorder: In-order version with mergeable and non-mergeable Rx buffer support for split virtqueue.
  5. virtio_recv_pkts_packed: Regular and in-order version without mergeable Rx buffer support for packed virtqueue.
  6. virtio_recv_mergeable_pkts_packed: Regular and in-order version with mergeable Rx buffer support for packed virtqueue.

Tx callbacks:

  1. virtio_xmit_pkts: Regular version for split virtqueue.
  2. virtio_xmit_pkts_inorder: In-order version for split virtqueue.
  3. virtio_xmit_pkts_packed: Regular and in-order version for packed virtqueue.

By default, the non-vector callbacks are used:

  • For Rx: If mergeable Rx buffers is disabled then virtio_recv_pkts or virtio_recv_pkts_packed will be used, otherwise virtio_recv_mergeable_pkts or virtio_recv_mergeable_pkts_packed will be used.
  • For Tx: virtio_xmit_pkts or virtio_xmit_pkts_packed will be used.

Vector callbacks will be used when:

  • Mergeable Rx buffers is disabled.

The corresponding callbacks are:

  • For Rx: virtio_recv_pkts_vec.

There is no vector callbacks for packed virtqueue for now.

Example of using the vector version of the virtio poll mode driver in testpmd:

dpdk-testpmd -l 0-2 -n 4 -- -i --rxq=1 --txq=1 --nb-cores=1

In-order callbacks only work on simulated virtio user vdev.

For split virtqueue:

  • For Rx: If in-order is enabled then virtio_recv_pkts_inorder is used.
  • For Tx: If in-order is enabled then virtio_xmit_pkts_inorder is used.

For packed virtqueue, the default callbacks already support the in-order feature.

54.7. Interrupt mode

There are three kinds of interrupts from a virtio device over PCI bus: config interrupt, Rx interrupts, and Tx interrupts. Config interrupt is used for notification of device configuration changes, especially link status (lsc). Interrupt mode is translated into Rx interrupts in the context of DPDK.

Note

Virtio PMD already has support for receiving lsc from qemu when the link status changes, especially when vhost user disconnects. However, it fails to do that if the VM is created by qemu 2.6.2 or below, since the capability to detect vhost user disconnection is introduced in qemu 2.7.0.

54.7.1. Prerequisites for Rx interrupts

To support Rx interrupts, #. Check if guest kernel supports VFIO-NOIOMMU:

Linux started to support VFIO-NOIOMMU since 4.8.0. Make sure the guest kernel is compiled with:

CONFIG_VFIO_NOIOMMU=y
  1. Properly set msix vectors when starting VM:

    Enable multi-queue when starting VM, and specify msix vectors in qemu cmdline. (N+1) is the minimum, and (2N+2) is mostly recommended.

    $(QEMU) ... -device virtio-net-pci,mq=on,vectors=2N+2 ...
    
  2. In VM, insert vfio module in NOIOMMU mode:

    modprobe vfio enable_unsafe_noiommu_mode=1
    modprobe vfio-pci
    
  3. In VM, bind the virtio device with vfio-pci:

    ./usertools/dpdk-devbind.py -b vfio-pci 00:03.0
    

54.7.2. Example

Here we use l3fwd-power as an example to show how to get started.

Example:

$ dpdk-l3fwd-power -l 0-1 -- -p 1 -P --config="(0,0,1)" \
                                       --no-numa --parse-ptype

54.8. Virtio PMD arguments

Below devargs are supported by the PCI virtio driver:

  1. vdpa:

    A virtio device could also be driven by vDPA (vhost data path acceleration) driver, and works as a HW vhost backend. This argument is used to specify a virtio device needs to work in vDPA mode. (Default: 0 (disabled))

  2. speed:

    It is used to specify link speed of virtio device. Link speed is a part of link status structure. It could be requested by application using rte_eth_link_get_nowait function. (Default: 0xffffffff (Unknown))

  3. vectorized:

    It is used to specify whether virtio device prefers to use vectorized path. Afterwards, dependencies of vectorized path will be checked in path election. (Default: 0 (disabled))

Below devargs are supported by the virtio-user vdev:

  1. path:

    It is used to specify a path to connect to vhost backend.

  2. mac:

    It is used to specify the MAC address.

  3. cq:

    It is used to enable the control queue. (Default: 0 (disabled))

  4. queue_size:

    It is used to specify the queue size. (Default: 256)

  5. queues:

    It is used to specify the queue number. (Default: 1)

  6. iface:

    It is used to specify the host interface name for vhost-kernel backend.

  7. server:

    It is used to enable the server mode when using vhost-user backend. (Default: 0 (disabled))

  8. mrg_rxbuf:

    It is used to enable virtio device mergeable Rx buffer feature. (Default: 1 (enabled))

  9. in_order:

    It is used to enable virtio device in-order feature. (Default: 1 (enabled))

  10. packed_vq:

    It is used to enable virtio device packed virtqueue feature. (Default: 0 (disabled))

  11. speed:

    It is used to specify link speed of virtio device. Link speed is a part of link status structure. It could be requested by application using rte_eth_link_get_nowait function. (Default: 0xffffffff (Unknown))

  12. vectorized:

    It is used to specify whether virtio device prefers to use vectorized path. Afterwards, dependencies of vectorized path will be checked in path election. (Default: 0 (disabled))

54.9. Virtio paths Selection and Usage

Logically virtio-PMD has 9 paths based on the combination of virtio features (Rx mergeable, In-order, Packed virtqueue), below is an introduction of these features:

  • Rx mergeable: With this feature negotiated, device can receive large packets by combining individual descriptors.
  • In-order: Some devices always use descriptors in the same order in which they have been made available, these devices can offer the VIRTIO_F_IN_ORDER feature. With this feature negotiated, driver will use descriptors in order.
  • Packed virtqueue: The structure of packed virtqueue is different from split virtqueue, split virtqueue is composed of available ring, used ring and descriptor table, while packed virtqueue is composed of descriptor ring, driver event suppression and device event suppression. The idea behind this is to improve performance by avoiding cache misses and make it easier for hardware to implement.

54.9.1. Virtio paths Selection

If packed virtqueue is not negotiated, below split virtqueue paths will be selected according to below configuration:

  1. Split virtqueue mergeable path: If Rx mergeable is negotiated, in-order feature is not negotiated, this path will be selected.
  2. Split virtqueue non-mergeable path: If Rx mergeable and in-order feature are not negotiated, also Rx offload(s) are requested, this path will be selected.
  3. Split virtqueue in-order mergeable path: If Rx mergeable and in-order feature are both negotiated, this path will be selected.
  4. Split virtqueue in-order non-mergeable path: If in-order feature is negotiated and Rx mergeable is not negotiated, this path will be selected.
  5. Split virtqueue vectorized Rx path: If Rx mergeable is disabled and no Rx offload requested, this path will be selected.

If packed virtqueue is negotiated, below packed virtqueue paths will be selected according to below configuration:

  1. Packed virtqueue mergeable path: If Rx mergeable is negotiated, in-order feature is not negotiated, this path will be selected.
  2. Packed virtqueue non-mergeable path: If Rx mergeable and in-order feature are not negotiated, this path will be selected.
  3. Packed virtqueue in-order mergeable path: If in-order and Rx mergeable feature are both negotiated, this path will be selected.
  4. Packed virtqueue in-order non-mergeable path: If in-order feature is negotiated and Rx mergeable is not negotiated, this path will be selected.
  5. Packed virtqueue vectorized Rx path: If building and running environment support (AVX512 || NEON) && in-order feature is negotiated && Rx mergeable is not negotiated && TCP_LRO Rx offloading is disabled && vectorized option enabled, this path will be selected.
  6. Packed virtqueue vectorized Tx path: If building and running environment support (AVX512 || NEON) && in-order feature is negotiated && vectorized option enabled, this path will be selected.

54.9.2. Rx/Tx callbacks of each Virtio path

Refer to above description, virtio path and corresponding Rx/Tx callbacks will be selected automatically. Rx callbacks and Tx callbacks for each virtio path are shown in below table:

Table 54.18 Virtio Paths and Callbacks
Virtio paths Rx callbacks Tx callbacks
Split virtqueue mergeable path virtio_recv_mergeable_pkts virtio_xmit_pkts
Split virtqueue non-mergeable path virtio_recv_pkts virtio_xmit_pkts
Split virtqueue in-order mergeable path virtio_recv_pkts_inorder virtio_xmit_pkts_inorder
Split virtqueue in-order non-mergeable path virtio_recv_pkts_inorder virtio_xmit_pkts_inorder
Split virtqueue vectorized Rx path virtio_recv_pkts_vec virtio_xmit_pkts
Packed virtqueue mergeable path virtio_recv_mergeable_pkts_packed virtio_xmit_pkts_packed
Packed virtqueue non-mergeable path virtio_recv_pkts_packed virtio_xmit_pkts_packed
Packed virtqueue in-order mergeable path virtio_recv_mergeable_pkts_packed virtio_xmit_pkts_packed
Packed virtqueue in-order non-mergeable path virtio_recv_pkts_packed virtio_xmit_pkts_packed
Packed virtqueue vectorized Rx path virtio_recv_pkts_packed_vec virtio_xmit_pkts_packed
Packed virtqueue vectorized Tx path virtio_recv_pkts_packed virtio_xmit_pkts_packed_vec

54.9.3. Virtio paths Support Status from Release to Release

Virtio feature implementation:

  • In-order feature is supported since DPDK 18.08 by adding new Rx/Tx callbacks virtio_recv_pkts_inorder and virtio_xmit_pkts_inorder.
  • Packed virtqueue is supported since DPDK 19.02 by adding new Rx/Tx callbacks virtio_recv_pkts_packed , virtio_recv_mergeable_pkts_packed and virtio_xmit_pkts_packed.

All virtio paths support status are shown in below table:

Table 54.19 Virtio Paths and Releases
Virtio paths 16.11 ~ 18.05 18.08 ~ 18.11 19.02 ~ 19.11 20.05 ~
Split virtqueue mergeable path Y Y Y Y
Split virtqueue non-mergeable path Y Y Y Y
Split virtqueue vectorized Rx path Y Y Y Y
Split virtqueue simple Tx path Y N N N
Split virtqueue in-order mergeable path   Y Y Y
Split virtqueue in-order non-mergeable path   Y Y Y
Packed virtqueue mergeable path     Y Y
Packed virtqueue non-mergeable path     Y Y
Packed virtqueue in-order mergeable path     Y Y
Packed virtqueue in-order non-mergeable path     Y Y
Packed virtqueue vectorized Rx path       Y
Packed virtqueue vectorized Tx path       Y

54.9.4. QEMU Support Status

  • Qemu now supports three paths of split virtqueue: Split virtqueue mergeable path, Split virtqueue non-mergeable path, Split virtqueue vectorized Rx path.
  • Since qemu 4.2.0, Packed virtqueue mergeable path and Packed virtqueue non-mergeable path can be supported.

54.9.5. How to Debug

If you meet performance drop or some other issues after upgrading the driver or configuration, below steps can help you identify which path you selected and root cause faster.

  1. Run vhost/virtio test case;
  2. Run “perf top” and check virtio Rx/Tx callback names;
  3. Identify which virtio path is selected refer to above table.