Linux* Driver for Intel(R) Ethernet Adaptive Virtual Function
=============================================================

September 18, 2019


Contents
========
- Overview
- Building and Installation
- Command Line Parameters
- Additional Configurations
- Known Issues
- Support
- License

Overview
========
The virtual function driver supports virtual functions generated by the
physical function driver, with one or more VFs enabled through sysfs.

The associated Physical Function (PF) driver for this driver is i40e.

SR-IOV requires the correct platform and OS support.

The guest OS loading this driver must support MSI-X interrupts.

For questions related to hardware requirements, refer to the documentation
supplied with your Intel adapter. All hardware requirements listed apply to use
with Linux.

Driver information can be obtained using ethtool, lspci, and ifconfig.
Instructions on updating ethtool can be found in the section Additional
Configurations later in this document.


Adaptive Virtual Function
-------------------------
Adaptive Virtual Function (AVF) allows the virtual function driver, or VF, to
adapt to changing feature sets of the physical function driver (PF) with which
it is associated. This allows system administrators to update a PF without
having to update all the VFs associated with it. All AVFs have a single common
device ID and branding string.

AVFs have a minimum set of features known as "base mode," but may provide
additional features depending on what features are available in the PF with
which the AVF is associated. The following are base mode features:

- 4 Queue Pairs (QP) and associated Configuration Status Registers (CSRs)
  for Tx/Rx
- iavf descriptors and ring format
- Descriptor write-back completion
- 1 control queue, with iavf descriptors, CSRs and ring format
- 5 MSI-X interrupt vectors and corresponding iavf CSRs
- 1 Interrupt Throttle Rate (ITR) index
- 1 Virtual Station Interface (VSI) per VF
- 1 Traffic Class (TC), TC0
- Receive Side Scaling (RSS) with 64 entry indirection table and key,
  configured through the PF
- 1 unicast MAC address reserved per VF
- 16 MAC address filters for each VF
- Stateless offloads - non-tunneled checksums
- AVF device ID
- HW mailbox is used for VF to PF communications (including on Windows)


Identifying Your Adapter
========================
For information on how to identify your adapter, and for the latest Intel
network drivers, refer to the Intel Support website:
http://www.intel.com/support


Building and Installation
=========================

To build a binary RPM package of this driver
--------------------------------------------
Note: RPM functionality has only been tested in Red Hat distributions.

1. Run the following command, where <x.x.x> is the version number for the
   driver tar file.

   # rpmbuild -tb iavf-<x.x.x>.tar.gz

   NOTE: For the build to work properly, the currently running kernel MUST
   match the version and configuration of the installed kernel sources. If
   you have just recompiled the kernel, reboot the system before building.

2. After building the RPM, the last few lines of the tool output contain the
   location of the RPM file that was built. Install the RPM with one of the
   following commands, where <RPM> is the location of the RPM file:

   # rpm -Uvh <RPM>
       or
   # dnf/yum localinstall <RPM>

NOTES:
- To compile the driver on some kernel/arch combinations, you may need to
install a package with the development version of libelf (e.g. libelf-dev,
libelf-devel, elfutilsl-libelf-devel).
- When compiling an out-of-tree driver, details will vary by distribution.
However, you will usually need a kernel-devel RPM or some RPM that provides the
kernel headers at a minimum. The RPM kernel-devel will usually fill in the link
at /lib/modules/'uname -r'/build.


To manually build the driver
----------------------------
1. Move the virtual function driver tar file to the directory of your choice.
   For example, use '/home/username/iavf' or '/usr/local/src/iavf'.

2. Untar/unzip the archive, where <x.x.x> is the version number for the
   driver tar file:

   # tar zxf iavf-<x.x.x>.tar.gz

3. Change to the driver src directory, where <x.x.x> is the version number
   for the driver tar:

   # cd iavf-<x.x.x>/src/

4. Compile the driver module:

   # make install

   The binary will be installed as:
   /lib/modules/<KERNEL VER>/updates/drivers/net/ethernet/intel/iavf/iavf.ko

   The install location listed above is the default location. This may differ
   for various Linux distributions.

5. Load the module using the modprobe command.

   To check the version of the driver and then load it:

   # modinfo iavf
   # modprobe iavf

   Alternately, make sure that any older iavf drivers are removed from the
   kernel before loading the new module:

   # rmmod iavf; modprobe iavf

6. Assign an IP address to the interface by entering the following,
   where <ethX> is the interface name that was shown in dmesg after modprobe:

   # ip address add <IP_address>/<netmask bits> dev <ethX>

7. Verify that the interface works. Enter the following, where IP_address
   is the IP address for another machine on the same subnet as the interface
   that is being tested:

   # ping <IP_address>



Command Line Parameters
=======================

The iavf driver does not support any command line parameters.


Additional Features and Configurations
======================================

Viewing Link Messages
---------------------
Link messages will not be displayed to the console if the distribution is
restricting system messages. In order to see network driver link messages on
your console, set dmesg to eight by entering the following:

# dmesg -n 8

NOTE: This setting is not saved across reboots.


ethtool
-------
The driver utilizes the ethtool interface for driver configuration and
diagnostics, as well as displaying statistical information. The latest ethtool
version is required for this functionality. Download it at:
https://kernel.org/pub/software/network/ethtool/


Setting VLAN Tag Stripping
--------------------------
If you have applications that require Virtual Functions (VFs) to receive
packets with VLAN tags, you can disable VLAN tag stripping for the VF. The
Physical Function (PF) processes requests issued from the VF to enable or
disable VLAN tag stripping. Note that if the PF has assigned a VLAN to a VF,
then requests from that VF to set VLAN tag stripping will be ignored.

To enable/disable VLAN tag stripping for a VF, issue the following command
from inside the VM in which you are running the VF:

# ethtool -K <if_name> rxvlan on/off

    or alternatively:

# ethtool --offload <if_name> rxvlan on/off


IEEE 802.1ad (QinQ) Support
---------------------------
The IEEE 802.1ad standard, informally known as QinQ, allows for multiple VLAN
IDs within a single Ethernet frame. VLAN IDs are sometimes referred to as
"tags," and multiple VLAN IDs are thus referred to as a "tag stack." Tag stacks
allow L2 tunneling and the ability to segregate traffic within a particular
VLAN ID, among other uses.

NOTES:
- 802.1ad (QinQ) is supported in 3.19 and later kernels.
- Receive checksum offloads, cloud filters, and VLAN acceleration are not
supported for 802.1ad (QinQ) packets.

The following are examples of how to configure 802.1ad (QinQ):

# ip link add link eth0 eth0.24 type vlan proto 802.1ad id 24
# ip link add link eth0.24 eth0.24.371 type vlan proto 802.1Q id 371
  Where "24" and "371" are example VLAN IDs.


Application Device Queues (ADQ)
-------------------------------
Application Device Queues (ADQ) allow you to dedicate one or more queues to a
specific application. This can reduce latency for the specified application,
and allow Tx traffic to be rate limited per application.

Requirements:
- Kernel version 4.15 or later
- Depending on the underlying PF device, ADQ cannot be enabled when the
following features are enabled: Data Center Bridging (DCB), Multiple Functions
per Port (MFP), or Sideband Filters.
- If another driver (for example, DPDK) has set cloud filters, you cannot
enable ADQ.

To create TCs on the interface:
NOTE: Run all TC commands from the ../iproute2/tc/ directory.
1. Use the tc command to create traffic classes (TCs). You can create a maximum
   of 8 TCs per interface.

   # tc qdisc add dev <interface> root mqprio num_tc <tcs> map <priorities>
     queues <count1@offset1 ...> hw 1 mode channel shaper bw_rlimit
     min_rate <min_rate1 ...> max_rate <max_rate1 ...>
   Where:
      num_tc <tcs>: The number of TCs to use.
      map <priorities>: The map of priorities to TCs. You can map up to
          16 priorities to TCs.
      queues <count1@offset1 ...>: For each TC, <num queues>@<offset>. The max
          total number of queues for all TCs is the number of cores.
      hw 1 mode channel: 'channel' with 'hw' set to 1 is a new hardware offload
          mode in mqprio that makes full use of the mqprio options, the TCs,
          the queue configurations, and the QoS parameters.
      shaper bw_rlimit: For each TC, sets the minimum and maximum bandwidth
          rates. The totals must be equal to or less than the port speed. This
          parameter is optional and is required only to set up the Tx rates.
      min_rate <min_rate1>: Sets the minimum bandwidth rate limit for each TC.
      max_rate <max_rate1 ...>: Sets the maximum bandwidth rate limit for each
          TC. You can set a min and max rate together.

NOTE: See the mqprio man page and the examples below for more information.

2. Verify the bandwidth limit using network monitoring tools such as ifstat or
sar -n DEV [interval] [number of samples]

NOTE: Setting up channels via ethtool (ethtool -L) is not supported when the
TCs are configured using mqprio.

3. Enable hardware TC offload on the interface:

   # ethtool -K <interface> hw-tc-offload on

4. Apply TCs to ingress (Rx) flow of the interface:

   # tc qdisc add dev <interface> ingress

EXAMPLE:
See the tc and tc-flower man pages for more information on traffic control and
TC flower filters.

- To set up two TCs (tc0 and tc1), with 16 queues each, priorities 0-3 for
  tc0 and 4-7 for tc1, and max Tx rate set to 1Gbit for tc0 and 3Gbit for tc1:

  # tc qdisc add dev ens4f0 root mqprio num_tc 2 map 0 0 0 0 1 1 1 1 queues
    16@0 16@16 hw 1 mode channel shaper bw_rlimit max_rate 1Gbit 3Gbit
  Where:
      map 0 0 0 0 1 1 1 1: Sets priorities 0-3 to use tc0 and 4-7 to use tc1
      queues 16@0 16@16: Assigns 16 queues to tc0 at offset 0 and 16 queues
          to tc1 at offset 16


SR-IOV Hypervisor Management Interface
--------------------------------------
The sysfs file structure below supports the SR-IOV hypervisor management
interface.

/sys/class/net/<interface-name>/device/sriov (see 1 below)
+-- [VF-id, 0 .. 255] (see 2 below)
| +-- trunk
| +-- vlan_mirror
| +-- egress_mirror
| +-- ingress_mirror
| +-- mac_anti_spoof
| +-- vlan_anti_spoof
| +-- loopback
| +-- mac
| +-- mac_list
| +-- promisc
| +-- vlan_strip
| +-- stats
| +-- link_state
| +-- max_tx_rate
| +-- min_tx_rate
| +-- spoofcheck
| +-- trust
| +-- vlan
*1: kobject started from “sriov” is not available from existing kernel
sysfs, and it requires device driver to implement this interface.
*2: maximum number of SR-IOV instances is 256. The actual number of instances
created depends on the value set for /sys/bus/devices/<device pci
address>/sriov_numvfs

SR-IOV hypervisor functions:

- trunk
  Supports two operations: add and rem.
  - add: adds one or more VLAN id into VF VLAN filtering.
  - rem: removes VLAN ids from the VF VLAN filtering list.
  Example 1: add multiple VLAN tags, VLANs 2,4,5,10-20, by PF, p1p2, on
  a selected VF, 1, for filtering, with the sysfs support:
  # echo add 2,4,5,10-20 > /sys/class/net/p1p2/device/sriov/1/trunk
  Example 2: remove VLANs 5, 11-13 from PF p1p2 VF 1 with sysfs:
  # echo rem 5,11-13 > /sys/class/net/p1p2/device/sriov/1/trunk
  Note: for rem, if VLAN id is not on the VLAN filtering list, the
  VLAN id will be ignored.

- vlan_mirror
  Supports both ingress and egress traffic mirroring.
  Example 1: mirror traffic based upon VLANs 2,4,6,18-22 to VF 3 of PF p1p1.
  # echo add 2,4,6,18-22 > /sys/class/net/p1p1/device/sriov/3/vlan_mirror
  Example 2: remove VLAN 4, 15-17 from traffic mirroring at destination VF 3.
  # echo rem 15-17 > /sys/class/net/p1p1/device/sriov/3/vlan_mirror
  Example 3: remove all VLANs from mirroring at VF 3.
  # echo rem 0 - 4095> /sys/class/net/p1p1/device/sriov/3/vlan_mirror

- egress_mirror
  Supports egress traffic mirroring.
  Example 1: add egress traffic mirroring on PF p1p2 VF 1 to VF 7.
  # echo add 7 > /sys/class/net/p1p2/device/sriov/1/egress_mirror
  Example 2: remove egress traffic mirroring on PF p1p2 VF 1 to VF 7.
  # echo rem 7 > /sys/class/net/p1p2/device/sriov/1/egress_mirror

- ingress_mirror
  Supports ingress traffic mirroring.
  Example 1: mirror ingress traffic on PF p1p2 VF 1 to VF 7.
  # echo add 7 > /sys/class/net/p1p2/device/sriov/1/ingress_mirror
  Example 2: show current ingress mirroring configuration.
  # cat /sys/class/net/p1p2/device/sriov/1/ingress_mirror

- mac_anti_spoof
  Supports Enable/Disable MAC anti-spoof. Allows VFs to transmit packets with
  any SRC MAC, which is needed for some L2 applications as well as vNIC bonding
  within VMs if set to OFF.
  Example 1: enable MAC anti-spoof for PF p2p1 VF 1.
  # echo ON /sys/class/net/p1p2/device/sriov/1/mac_anti_spoof
  Example 2: disable MAC anti-spoof for PF p2p1 VF 1.
  # echo OFF /sys/class/net/p1p2/device/sriov/1/mac_anti_spoof

- vlan_anti_spoof
  Supports Enable/Disable VLAN anti-spoof. Allows VFs to transmit packets only
  with VLAN tag specified in “trunk” settings, also will not allow to transmit
  “untagged” packets if set to ON. Violation have to increment tx_spoof stats
  counter.
  Example 1: enable VLAN anti-spoof for PF p2p1 VF 1.
  # echo ON /sys/class/net/p1p2/device/sriov/1/vlan_anti_spoof
  Example 2: disable VLAN anti-spoof for PF p2p1 VF 1.
  # echo OFF /sys/class/net/p1p2/device/sriov/1/vlan_anti_spoof

- loopback
  Supports Enable/Disable VEB/VEPA (Local loopback).
  Example 1: allow traffic switching between VFs on the same PF.
  # echo ON > /sys/class/net/p1p2/device/sriov/loopback
  Example 2: send Hairpin traffic to the switch to which the PF is connected.
  # echo OFF > /sys/class/net/p1p2/device/sriov/loopback
  Example 3: show loopback configuration.
  # cat /sys/class/net/p1p2/device/sriov/loopback

- mac
  Supports setting default MAC address. If MAC address is set by this
  command, the PF will not allow VF to change it using an MBOX request.
  Example 1: set default MAC address to VF 1.
  # echo "00:11:22:33:44:55" > /sys/class/net/p1p2/device/sriov/1/mac
  Example 2: show default MAC address.
  # cat /sys/class/net/p1p2/device/sriov/1/mac

- mac_list
  Supports adding additional MACs to the VF. The default MAC is taken from
  "ip link set p1p2 vf 1 mac 00:11:22:33:44:55" if configured. If not, a random
  address is assigned to the VF by the NIC. If the MAC is configured using
  the IP LINK command, the VF cannot change it via MBOX/AdminQ requests.
  Example 1: add mac 00:11:22:33:44:55 and 00:66:55:44:33:22 to PF p1p2 VF 1.
  # echo add "00:11:22:33:44:55,00:66:55:44:33:22" >
  /sys/class/net/p1p2/device/sriov/1/mac_list
  Example 2: delete mac 00:11:22:33:44:55 from above VF device.
  # echo rem 00:11:22:33:44:55 > /sys/class/net/p1p2/device/sriov/1/mac_list
  Example 3: display a VF MAC address list.
  # cat /sys/class/net/p1p2/device/sriov/1/mac_lis

- promisc
  Supports setting/unsetting VF device unicast promiscuous mode and multicast
  promiscuous mode.
  Example 1: set MCAST promiscuous on PF p1p2 VF 1.
  # echo add mcast > /sys/class/net/p1p2/device/sriov/1/promisc
  Example 2: set UCAST promiscuous on PF p1p2 VF 1.
  # echo add ucast > /sys/class/net/p1p2/device/sriov/1/promisc
  Example 3: unset MCAST promiscuous on PF p1p2 VF 1.
  # echo rem mcast > /sys/class/net/p1p2/device/sriov/1/promisc
  Example 4: show current promiscuous mode configuration.
  # cat /sys/class/net/p1p2/device/sriov/1/promisc

- vlan_strip
  Supports enabling/disabling VF device outer VLAN stripping
  Example 1: enable VLAN strip on VF 3.
  # echo ON > /sys/class/net/p1p1/device/sriov/3/vlan_strip
  Example 2: disable VLAN striping VF 3.
  # echo OFF > /sys/class/net/p1p1/device/sriov/3/vlan_strip

- stats
  Supports getting VF statistics
  Example 1: display stats of VF 1.
  # cat /sys/class/net/p1p2/device/sriov/1/stats

- link_state
  Sets/displays link status.
  Example 1: display link status on link speed.
  # cat /sys/class/net/p1p2/device/sriov/1/link_state
  Example 2 set VF 1 to track status of PF link.
  # echo auto > /sys/class/net/p1p2/device/sriov/1/link_state
  Example 3: disable VF 1.
  # echo disable > /sys/class/net/p1p2/device/sriov/1/link_state


Known Issues/Troubleshooting
============================

Software Issues
---------------
NOTE: After installing the driver, if your Intel Ethernet Network Connection
is not working, verify that you have installed the correct driver.


Linux bonding fails with Virtual Functions bound to an Intel(R) Ethernet
Controller 700 series based device
------------------------------------------------------------------------
If you bind Virtual Functions (VFs) to an Intel(R) Ethernet Controller 700
series based device, the VF slaves may fail when they become the active slave.
If the MAC address of the VF is set by the PF (Physical Function) of the
device, when you add a slave, or change the active-backup slave, Linux bonding
tries to sync the backup slave's MAC address to the same MAC address as the
active slave. Linux bonding will fail at this point. This issue will not occur
if the VF's MAC address is not set by the PF.


Traffic Is Not Being Passed Between VM and Client
-------------------------------------------------
You may not be able to pass traffic between a client system and a Virtual
Machine (VM) running on a separate host if the Virtual Function (VF, or Virtual
NIC) is not in trusted mode and spoof checking is enabled on the VF. Note that
this situation can occur in any combination of client, host, and guest
operating system. See the readme for the PF driver for information on spoof
checking and how to set the VF to trusted mode.


Using four traffic classes fails
--------------------------------
Do not try to reserve more than three traffic classes in the iavf driver. Doing
so will fail to set any traffic classes and will cause the driver to write
errors to stdout. Use a maximum of three queues to avoid this issue.


Multiple log error messages on iavf driver removal
----------------------------------------------------
If you have several VFs and you remove the iavf driver, several instances of
the following log errors are written to the log:
  Unable to send opcode 2 to PF, err I40E_ERR_QUEUE_EMPTY, aq_err ok
  Unable to send the message to VF 2 aq_err 12
  ARQ Overflow Error detected


Virtual machine does not get link
---------------------------------
If the virtual machine has more than one virtual port assigned to it, and those
virtual ports are bound to different physical ports, you may not get link on
all of the virtual ports. The following command may work around the issue:

# ethtool -r <PF>
Where <PF> is the PF interface in the host, for example: p5p1. You may need to
run the command more than once to get link on all virtual ports.


MAC address of Virtual Function changes unexpectedly
----------------------------------------------------
If a Virtual Function's MAC address is not assigned in the host, then the VF
(virtual function) driver will use a random MAC address. This random MAC
address may change each time the VF driver is reloaded. You can assign a static
MAC address in the host machine. This static MAC address will survive
a VF driver reload.


Driver Buffer Overflow Fix
--------------------------
The fix to resolve CVE-2016-8105, referenced in Intel SA-00069
<https://security-center.intel.com/advisory.aspx?intelid=INTEL-SA-00069&language
id=en-fr>, is included in this and future versions of the driver.


Compiling the Driver
--------------------
When trying to compile the driver by running make install, the following error
may occur: "Linux kernel source not configured - missing version.h"

To solve this issue, create the version.h file by going to the Linux source
tree and entering:

# make include/linux/version.h


Multiple Interfaces on Same Ethernet Broadcast Network
------------------------------------------------------
Due to the default ARP behavior on Linux, it is not possible to have one system
on two IP networks in the same Ethernet broadcast domain (non-partitioned
switch) behave as expected. All Ethernet interfaces will respond to IP traffic
for any IP address assigned to the system. This results in unbalanced receive
traffic.

If you have multiple interfaces in a server, either turn on ARP filtering by
entering the following:

# echo 1 > /proc/sys/net/ipv4/conf/all/arp_filter

This only works if your kernel's version is higher than 2.4.5.

NOTE: This setting is not saved across reboots. The configuration change can be
made permanent by adding the following line to the file /etc/sysctl.conf:

  net.ipv4.conf.all.arp_filter = 1

Another alternative is to install the interfaces in separate broadcast domains
(either in different switches or in a switch partitioned to VLANs).


Rx Page Allocation Errors
-------------------------
'Page allocation failure. order:0' errors may occur under stress with kernels
2.6.25 and newer. This is caused by the way the Linux kernel reports this
stressed condition.


Host May Reboot after Removing PF when VF is Active in Guest
------------------------------------------------------------
Using kernel versions earlier than 3.2, do not unload the PF driver with
active VFs. Doing this will cause your VFs to stop working until you reload
the PF driver and may cause a spontaneous reboot of your system.

Prior to unloading the PF driver, you must first ensure that all VFs are
no longer active. Do this by shutting down all VMs and unloading the VF driver.


SR-IOV virtual functions have identical MAC addresses in RHEL8
--------------------------------------------------------------
When you create multiple SR-IOV virtual functions on Red Hat Enterprise
Linux 8, the VFs may have identical MAC addresses. Only one VF will pass
traffic, and all traffic on other VFs with identical MAC addresses will fail.
This is related to the "MACAddressPolicy=persistent" setting in
/usr/lib/systemd/network/99-default.link.

To resolve this issue, edit the /usr/lib/systemd/network/99-default.link file
and change the MACAddressPolicy line to "MACAddressPolicy=none". For more
information, see the systemd documentation.


Support
=======
For general information, go to the Intel support website at:
http://www.intel.com/support/

or the Intel Wired Networking project hosted by Sourceforge at:
http://sourceforge.net/projects/e1000

If an issue is identified with the released source code on a supported kernel
with a supported adapter, email the specific information related to the issue
to e1000-devel@lists.sf.net.


License
=======
This program is free software; you can redistribute it and/or modify it under
the terms and conditions of the GNU General Public License, version 2, as
published by the Free Software Foundation.

This program is distributed in the hope it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A
PARTICULAR PURPOSE. See the GNU General Public License for more details.

You should have received a copy of the GNU General Public License along with
this program; if not, write to the Free Software Foundation, Inc., 51 Franklin
St - Fifth Floor, Boston, MA 02110-1301 USA.

The full GNU General Public License is included in this distribution in the
file called "COPYING".

Copyright(c) 2018 - 2019 Intel Corporation.


Trademarks
==========
Intel is a trademark or registered trademark of Intel Corporation or its
subsidiaries in the United States and/or other countries.

* Other names and brands may be claimed as the property of others.


