There are multiple components involved to provide SR-IOV support in KubeVirt environment.
- SR-IOV device plugin
discovers available SR-IOV resources, advertises them to Kubernetes resource
manager, and allocates them as needed to pods and VMIs. This component
doesn't modify host resources, only discovers, advertises and allocates them.
When resources are advertized, they are registered in
capacitysection of each node, that is then used for scheduling purposes. For VMIs, it allocatesvfiodevice nodes to pods; it also sets environment variables with PCI IDs of allocated devices. These variables are later used by KubeVirt to configure libvirt domain. - SR-IOV CNI plugin configures allocated SR-IOV resources before a pod or VMI is started. This component modifies host resources to prepare them to be used inside a pod / VMI. Executed in root network namespace context. Uses netlink and other commands to configure and move SR-IOV VF / PF resources into pod namespaces.
- Multus is a meta-plugin. It will call
to SR-IOV CNI plugin when VMI is attached to an SR-IOV interface. It is
configured through
NetworkAttachmentDefinitionCRD objects. For SR-IOV, the object annotations should refer to the resource name configured inside device pluginconfig.jsonconfiguration file. This reference is used by KubeVirt to automatically fill inrequestsandlimitssections ofvirt-launcherpods. (The same mechanism is used by other plugins, for example,bridge.) If used alone, SR-IOV CNI plugin would need the PCI address of the device we want to use inside the pod (and then, inside the VM). By using it in combination with the device plugin and Multus, thanks toresourceNameannotation, the pod will receive a device from the pool allocated by the device plugin, which allows to avoid manually passing the required PCI address. - OpenShift SR-IOV operator configures kernel for SR-IOV, drains resources and reboots the kernel as needed, deploys components listed above, and, based on values in policy CRD resources managed by admin, configures the above listed components and the host.
- KubeVirt, based on values of environment variables set by SR-IOV device
plugin, configures libvirt domain for SR-IOV attached VMIs to use the right
PCI IDs. Also, fills in
requestsandlimitssections ofvirt-launcherpod spec as per attached NetworkAttachmentDefinition CRD.
NOTE: steps to configure SR-IOV on a host are only applicable if you don't use OpenShift SR-IOV operator to deploy SR-IOV components. Despite the name, the operator supports installation on a plain Kubernetes cluster. The operator handles most of the steps discussed below, including configuring kernel parameters. The only step that cannot be handled by the operator is BIOS setup, which should be handled by other means (either manually or through some kind of IPMI driven automation).
Documentation on how to use the operator is located elsewhere. Just remember to set
SriovNetworkNodePolicyto usedeviceType: vfio-pciwhen configuring the operator.For local development purposes, one should be able to (re)use the same kind based provider that the official upstream SR-IOV CI relies on, for example:
$ export KUBEVIRT_PROVIDER=kind-k8s-sriov-1.14.2
$ make cluster-up
Assuming you run these commands on a SR-IOV enabled host, they should bring up a dockerized cluster with all SR-IOV components and resources set up and ready to use.
If you know what you are doing and still would like to follow the manual configuration path, keep reading.
Before you deploy your cluster, make sure your host has a SR-IOV capable NIC plugged in, and that it supports it. You may need to adjust BIOS settings to make it work. For example, make sure VT-x (hardware virtualization) and Intel VT for Directed I/O are enabled in BIOS.
You should also configure kernel to enable IOMMU. This can be achieved by adding the following kernel parameters to kernel command line:
intel_iommu=on
Some hosts may experience problems detecting VFs. If you experience issues configuring VFs, you may try to add one of the following parameters:
pci=realloc
pci=assign-busses
If all goes well, after reboot your SR-IOV capable NICs should be ready to use.
Check for SR-IOV devices by doing the following:
$ find /sys -name *vfs*
/sys/devices/pci0000:00/0000:00:09.0/0000:05:00.0/sriov_numvfs
/sys/devices/pci0000:00/0000:00:09.0/0000:05:00.0/sriov_totalvfs
/sys/devices/pci0000:00/0000:00:09.0/0000:05:00.1/sriov_numvfs
/sys/devices/pci0000:00/0000:00:09.0/0000:05:00.1/sriov_totalvfs
KubeVirt will use vfio
userspace driver to pass through PCI devices into qemu. VFIO is an
established way to pass raw devices into running virtual machines, in contrast
to using the regular netdevice device plugin mode used to attach regular pods
to netlink interfaces registered with corresponding Linux kernel network
drivers. More information on VFIO can also be found
here.
For this to work, load the following driver:
$ modprobe vfio-pci
Depending on your hardware platform, the driver may need additional kernel options. For example, if your platform does not support interrupt remapping, you may need to configure the host as follows:
$ echo "options vfio_iommu_type1 allow_unsafe_interrupts=1" > /etc/modprobe.d/iommu_unsafe_interrupts.conf
Now you are ready to set up your cluster.
You can use your preferred mechanism to deploy your kubernetes cluster as long as you deploy on bare metal. Note that using virtualized environment is problematic with SR-IOV because to use SR-IOV PFs in such environment, one would first need to pass through PF devices from hypervisor level into the virtual machines. That's why right now it's impossible to use regular providers that use qemu machines for SR-IOV development.
Current recommendation is to use the official KubeVirt operator to deploy clusters.
You may still want to deploy software using local provider if you'd like to
deploy from KubeVirt sources though.
In the following example, we configure the cluster using local provider which
is part of kubevirt/kubevirt repo. Please consult
documentation
for general information on setting up a host using the local provider.
The local provider does not install default CNI plugins like loopback. So
first, install default CNI plugins:
$ go get -u -d github.com/containernetworking/plugins/
$ cd $GOPATH/src/github.com/containernetworking/plugins/
$ ./build.sh
$ mkdir -p /opt/cni/bin/
$ cp bin/* /opt/cni/bin/
Then, prepare kubernetes tree for CNI enabled deployment:
$ go get -u -d k8s.io/kubernetes
$ cd $GOPATH/src/k8s.io/kubernetes
$ git diff
diff --git a/hack/local-up-cluster.sh b/hack/local-up-cluster.sh
index bcf988b..9911eed 100755
--- a/hack/local-up-cluster.sh
+++ b/hack/local-up-cluster.sh
@@ -639,6 +639,8 @@ function start_controller_manager {
--use-service-account-credentials \
--controllers="${KUBE_CONTROLLERS}" \
--leader-elect=false \
+ --cert-dir="$CERT_DIR" \
+ --allocate-node-cidrs=true --cluster-cidr=10.244.0.0/16 \
--master="https://${API_HOST}:${API_SECURE_PORT}" >"${CTLRMGR_LOG}" 2>&1 &
CTLRMGR_PID=$!
}
export NET_PLUGIN=cni
export CNI_CONF_DIR=/etc/cni/net.d/
export CNI_BIN_DIR=/opt/cni/bin/
Install etcd:
$ ./hack/install-etcd.sh
Use local provider for kubevirt:
$ export KUBEVIRT_PROVIDER=local
Now finally, deploy kubernetes:
$ cd $GOPATH/src/kubevirt.io/kubevirt
$ make cluster-up
Once the cluster is deployed, we can move to SR-IOV specific components.
NOTE: as stated above, manual deployment of SR-IOV components is not recommended. Please consider using SR-IOV operator instead. But if you know what you are doing, keep reading.
First, deploy latest Multus with default Flannel backend.
$ go get -u -d github.com/intel/multus-cni
$ cd $GOPATH/src/github.com/intel/multus-cni/
$ mkdir -p /etc/cni/net.d
$ cp images/70-multus.conf /etc/cni/net.d/
$ ./cluster-up/kubectl.sh create -f $GOPATH/src/github.com/intel/multus-cni/images/multus-daemonset.yml
$ ./cluster-up/kubectl.sh create -f $GOPATH/src/github.com/intel/multus-cni/images/flannel-daemonset.yml
Now, deploy SR-IOV device plugin. Adjust config.json file for your particular setup. More information about configuration file format: https://github.com/intel/sriov-network-device-plugin/blob/master/README.md#configurations
$ go get -u -d github.com/intel/sriov-network-device-plugin/
$ cat <<EOF > /etc/pcidp/config.json
{
"resourceList":
[
{
"resourceName": "sriov",
"rootDevices": ["05:00.0", "05:00.1"],
"sriovMode": true,
"deviceType": "vfio"
}
]
}
EOF
$ ./cluster-up/kubectl.sh create -f $GOPATH/src/github.com/intel/sriov-network-device-plugin/images/sriovdp-daemonset.yaml
Deploy SR-IOV CNI plugin.
$ go get -u -d github.com/intel/sriov-cni/
$ ./cluster-up/kubectl.sh create -f $GOPATH/src/github.com/intel/sriov-cni/images/sriov-cni-daemonset.yaml
Finally, create a new SR-IOV network CRD that will use SR-IOV device plugin to allocate devices.
./cluster-up/kubectl.sh create -f $GOPATH/src/github.com/intel/sriov-network-device-plugin/deployments/sriov-crd.yaml
Just make sure that the network spec refers to the right resource name for SR-IOV resources configured in SR-IOV device plugin configuration file (config.json).
This particular step is not specific to SR-IOV.
make cluster-sync
If all goes well, you should be able to post a VMI spec referring to the SR-IOV multus network and get a PCI device allocated to virt-launcher and passed through into qemu. Please consult the VMI spec example.
As long as the VMI spec networks section refers to the proper
NetworkAttachmentDefinition that describes a SR-IOV network, you should be
able to post it and get a machine attached to an SR-IOV device via VFIO. Note
that the NetworkAttachmentDefinition resource should also refer, in its
annotations, to a correct resource name as reported by SR-IOV device plugin for
all this to work. More details on usage can be found in
KubeVirt
and SR-IOV operator
user documentation.