Table of Contents
This Intel QAT device plugin provides support for Intel QAT devices under Kubernetes. The supported devices are determined by the VF device drivers available in your Linux Kernel. See the Prerequisites section for more details.
Supported Devices include, but may not be limited to, the following:
- Intel® Xeon® with Intel® C62X Series Chipset
- Intel® Xeon® with Intel® QAT Gen4 devices
- Intel® Atom™ Processor C3000
- Intel® Communications Chipset 8925 to 8955 Series
The QAT device plugin provides access to QAT hardware accelerated cryptographic and compression features. Demonstrations are provided utilising DPDK and OpenSSL.
Kata Containers QAT integration is documented in the Kata Containers documentation repository.
The QAT plugin can take a number of command line arguments, summarised in the following table:
Flag | Argument | Meaning |
---|---|---|
-dpdk-driver | string | DPDK Device driver for configuring the QAT device (default: vfio-pci ) |
-kernel-vf-drivers | string | Comma separated VF Device Driver of the QuickAssist Devices in the system. Devices supported: DH895xCC, C62x, C3xxx, 4xxx/401xx, C4xxx and D15xx (default: c6xxvf,4xxxvf ) |
-max-num-devices | int | maximum number of QAT devices to be provided to the QuickAssist device plugin (default: 32 ) |
-mode | string | plugin mode which can be either dpdk or kernel (default: dpdk ) |
-allocation-policy | string | 2 possible values: balanced and packed. Balanced mode spreads allocated QAT VF resources balanced among QAT PF devices, and packed mode packs one QAT PF device full of QAT VF resources before allocating resources from the next QAT PF. (There is no default.) |
The plugin also accepts a number of other arguments related to logging. Please use the -h
option to see
the complete list of logging related options.
For more details on the -dpdk-driver
choice, see
DPDK Linux Driver Guide.
Note:: With Linux 5.9+ kernels the
vfio-pci
module must be loaded withdisable_denylist=1
parameter for the QAT device plugin to work correctly with devices prior to Gen4 (4xxx
).
For more details on the available options to the -kernel-vf-drivers
option, see the list of
vf drivers available in the Linux Kernel.
If the -mode
parameter is set to kernel
, no other parameter documented above are valid,
except the klog
logging related parameters.
kernel
mode implements resource allocation based on system configured logical instances.
Note:
kernel
mode is excluded by default from all builds (including those hosted on the Docker hub), by default. See the Build the plugin image section for more details.
The kernel
mode does not guarantee full device isolation between containers
and therefore it's not recommended. This mode will be deprecated and removed once libqat
implements non-UIO based device access.
The below sections cover how to obtain, build and install this component.
The component can be installed either using a DaemonSet or running 'by hand' on each node.
The component has the same basic dependancies as the generic plugin framework dependencies.
You will also need appropriate hardware installed.
The QAT plugin requires Linux Kernel VF QAT drivers to be available. These drivers are available via two methods. One of them must be installed and enabled:
The demonstrations have their own requirements, listed in their own specific sections.
Pre-built images of this component are available on the Docker hub. These images are automatically built and uploaded to the hub from the latest main branch of this repository.
Release tagged images of the components are also available on the Docker hub, tagged with their
release version numbers in the format x.y.z
, corresponding to the branches and releases in this
repository. Thus the easiest way to deploy the plugin in your cluster is to run this command
$ kubectl apply -k https://github.com/intel/intel-device-plugins-for-kubernetes/deployments/qat_plugin?ref=<RELEASE_VERSION>
Where <RELEASE_VERSION>
needs to be substituted with the desired release tag or main
to get devel
images.
An alternative kustomization for deploying the plugin is with the debug mode switched on:
$ kubectl apply -k https://github.com/intel/intel-device-plugins-for-kubernetes/deployments/qat_plugin/overlays/debug?ref=<RELEASE_VERSION>
Note: It is also possible to run the QAT device plugin using a non-root user. To do this, the nodes' DAC rules must be configured to allow PCI driver unbinding/binding, device plugin socket creation and kubelet registration. Furthermore, the deployments
securityContext
must be configured with appropriaterunAsUser/runAsGroup
.
There's a sample qat initcontainer. Regardless of device types, the script running inside the initcontainer enables QAT SR-IOV VFs.
To deploy, run as follows:
$ kubectl apply -k deployments/qat_plugin/overlays/qat_initcontainer/
In addition to the default configuration, you can add device-specific configurations via ConfigMap.
Device | Possible Configuration | How To Customize | Options | Notes |
---|---|---|---|---|
4xxx, 401xx | cfg_services reports the configured services (crypto services or compression services) of the QAT device. | ServicesEnabled=<value> |
compress:dc , crypto:sym;asym |
Linux 6.0+ kernel is required. |
To create a provisioning config after customizing, run as follows:
$ kubectl create configmap --namespace=inteldeviceplugins-system qat-config --from-file=deployments/qat_plugin/overlays/qat_initcontainer/qat.conf
Note: When deploying the overlay qat_initcontainer, such a manual creation is not necessary since ConfigMap is generated automatically. Just set the values in the config file and deploy the overlay.
When using the operator for deploying the plugin with provisioning config, use provisioningConfig
field for the name of the ConfigMap, then the config is passed to initcontainer through the volume mount.
There's also a possibility for a node specific congfiguration through passing a nodename via NODE_NAME
into initcontainer's environment and passing a node specific profile (qat-$NODE_NAME.conf
) via ConfigMap volume mount.
Verification of the plugin deployment and detection of QAT hardware can be confirmed by examining the resource allocations on the nodes:
$ kubectl describe node <node name> | grep qat.intel.com/generic
qat.intel.com/generic: 10
qat.intel.com/generic: 10
The below sections cover DPDK
and OpenSSL
demos, both of which utilise the
QAT device plugin under Kubernetes.
The Data Plane Development Kit (DPDK) QAT demos use DPDK crypto-perf and compress-perf utilities to exercise DPDK QAT Poll-Mode Drivers (PMD). For more information on the tools' parameters, refer to the website links.
For the DPDK QAT demos to work, the DPDK drivers must be loaded and configured. For more information, refer to: DPDK Getting Started Guide for Linux and DPDK Getting Started Guide, Linux Drivers section
In the pod specification file, add container resource request and limit.
For example, qat.intel.com/generic: <number of devices>
for a container requesting QAT devices.
For a DPDK-based workload, you may need to add hugepage request and limit.
$ kubectl apply -k https://github.com/intel/intel-device-plugins-for-kubernetes/deployments/qat_dpdk_app/base/
$ kubectl get pods
NAME READY STATUS RESTARTS AGE
qat-dpdk 1/1 Running 0 27m
intel-qat-plugin-5zgvb 1/1 Running 0 3h
Note: If the
igb_uio
VF driver is used with the QAT device plugin, the workload be deployed withSYS_ADMIN
capabilities added.
Manually execute the dpdk-test-crypto-perf
application to review the logs:
$ kubectl exec -it qat-dpdk bash
$ dpdk-test-crypto-perf -l 6-7 -w $QAT1 \
-d /usr/lib64/librte_mempool_ring.so.1.1 \
-d /usr/lib64/librte_pmd_qat.so.1.1 -- \
--ptest throughput --devtype crypto_qat \
--optype cipher-only --cipher-algo aes-cbc --cipher-op encrypt \
--cipher-key-sz 16 --total-ops 10000000 --burst-sz 32 --buffer-sz 64
Note: Adapt the
.so
versions to what the DPDK version in the container provides.
It is also possible to deploy and run crypto-perf
using the following
kustomize
overlays:
$ kubectl apply -k https://github.com/intel/intel-device-plugins-for-kubernetes/deployments/qat_dpdk_app/test-crypto1
$ kubectl apply -k https://github.com/intel/intel-device-plugins-for-kubernetes/deployments/qat_dpdk_app/test-compress1
$ kubectl logs qat-dpdk-test-crypto-perf-tc1
$ kubectl logs qat-dpdk-test-compress-perf-tc1
Note: for
test-crypto1
andtest-compress1
to work, the cluster must enable Kubernetes CPU manager'sstatic
policy.
Please refer to the Kata Containers documentation for details on the OpenSSL QAT acceleration demo.
In order to utilise the QAT device plugin, QuickAssist SR-IOV virtual functions must be configured. You can verify this on your nodes by checking for the relevant PCI identifiers:
for i in 0442 0443 18a1 37c9 6f55 19e3 4941 4943; do lspci -d 8086:$i; done