libvirt
This section documents how to set up and use openSUSE Leap 42.3 as a QEMU-KVM based virtual machine host.
In general, the virtual guest system needs the same hardware resources as when installed on a physical machine. The more guests you plan to run on the host system, the more hardware resources—CPU, disk, memory, and network—you need to add to the VM Host Server.
To run KVM, your CPU must support virtualization, and
virtualization needs to be enabled in BIOS. The file
/proc/cpuinfo
includes information about your CPU
features.
The KVM host requires several packages to be installed. To install all necessary packages, do the following:
Run
› › .Select
and preferably also , and confirm with .During the installation process, you can optionally let YaST create a
for you automatically. If you do not plan to dedicate an additional physical network card to your virtual guests, network bridge is a standard way to connect the guest machines to the network.
After all the required packages are installed (and new network setup
activated), try to load the KVM kernel module relevant for your CPU
type—kvm-intel
or
kvm-amd
:
root #
modprobe kvm-intel
Check if the module is loaded into memory:
tux >
lsmod | grep kvm
kvm_intel 64835 6
kvm 411041 1 kvm_intel
Now the KVM host is ready to serve KVM VM Guests. For more information, see Chapter 28, Running Virtual Machines with qemu-system-ARCH.
You can improve the performance of KVM-based VM Guests by letting them fully use specific features of the VM Host Server's hardware (paravirtualization). This section introduces techniques to make the guests access the physical host's hardware directly—without the emulation layer—to make the most use of it.
Examples included in this section assume basic knowledge of the
qemu-system-ARCH
command
line options. For more information, see
Chapter 28, Running Virtual Machines with qemu-system-ARCH.
virtio-scsi
#
virtio-scsi
is an advanced storage stack for
KVM. It replaces the former virtio-blk
stack
for SCSI devices pass-through. It has several advantages over
virtio-blk
:
KVM guests have a limited number of PCI controllers, which results
in a limited number of possibly attached devices.
virtio-scsi
solves this limitation by
grouping multiple storage devices on a single controller. Each device
on a virtio-scsi
controller is represented
as a logical unit, or LUN.
virtio-blk
uses a small set of
commands that need to be known to both the
virtio-blk
driver and the virtual machine
monitor, and so introducing a new command requires updating both the
driver and the monitor.
By comparison, virtio-scsi
does not define
commands, but rather a transport protocol for these commands following
the industry-standard SCSI specification. This approach is shared with
other technologies, such as Fibre Channel, ATAPI, and USB devices.
virtio-blk
devices are presented inside the
guest as /dev/vdX
,
which is different from device
names in physical systems and may cause migration problems.
virtio-scsi
keeps the device names identical
to those on physical systems, making the virtual machines easily
relocatable.
For virtual disks backed by a whole LUN on the host, it is preferable
for the guest to send SCSI commands directly to the LUN
(pass-through). This is limited in
virtio-blk
, as guests need to use the
virtio-blk protocol instead of SCSI command pass-through, and,
moreover, it is not available for Windows guests.
virtio-scsi
natively removes these
limitations.
virtio-scsi
Usage #
KVM supports the SCSI pass-through feature with the
virtio-scsi-pci
device:
qemu-system-x86_64 [...] \ -device virtio-scsi-pci,id=scsi
vhost-net
#
The vhost-net
module is used to accelerate
KVM's paravirtualized network drivers. It provides better latency and
greater network throughput. Use the vhost-net
driver by starting the guest with the following example command line:
qemu-system-x86_64 [...] \ -netdev tap,id=guest0,vhost=on,script=no \ -net nic,model=virtio,netdev=guest0,macaddr=00:16:35:AF:94:4B
Note that guest0
is an identification string of the
vhost-driven device.
As the number of virtual CPUs increases in VM Guests, QEMU offers a way of improving the network performance using multiqueue. Multiqueue virtio-net scales the network performance by allowing VM Guest virtual CPUs to transfer packets in parallel. Multiqueue support is required on both the VM Host Server and VM Guest sides.
The multiqueue virtio-net solution is most beneficial in the following cases:
Network traffic packets are large.
VM Guest has many connections active at the same time, mainly between the guest systems, or between the guest and the host, or between the guest and an external system.
The number of active queues is equal to the number of virtual CPUs in the VM Guest.
While multiqueue virtio-net increases the total network throughput, it increases CPU consumption as it uses of the virtual CPU's power.
The following procedure lists important steps to enable the multiqueue
feature with qemu-system-ARCH
. It assumes that a tap
network device with multiqueue capability (supported since kernel
version 3.8) is set up on the VM Host Server.
In qemu-system-ARCH
, enable multiqueue for the tap
device:
-netdev tap,vhost=on,queues=2*N
where N
stands for the number of queue pairs.
In qemu-system-ARCH
, enable multiqueue and specify
MSI-X (Message Signaled Interrupt) vectors for the virtio-net-pci
device:
-device virtio-net-pci,mq=on,vectors=2*N+2
where the formula for the number of MSI-X vectors results from: N vectors for TX (transmit) queues, N for RX (receive) queues, one for configuration purposes, and one for possible VQ (vector quantization) control.
In VM Guest, enable multiqueue on the relevant network interface
(eth0
in this example):
ethtool -L eth0 combined 2*N
The resulting qemu-system-ARCH
command line will look
similar to the following example:
qemu-system-x86_64 [...] -netdev tap,id=guest0,queues=8,vhost=on \ -device virtio-net-pci,netdev=guest0,mq=on,vectors=10
Note that the id
of the network device
(guest0
) needs to be identical for both options.
Inside the running VM Guest, specify the following command as
root
:
ethtool -L eth0 combined 8
Now the guest system networking uses the multiqueue support from the
qemu-system-ARCH
hypervisor.
Directly assigning a PCI device to a VM Guest (PCI pass-through) avoids performance issues caused by avoiding any emulation in performance-critical paths. VFIO replaces the traditional KVM PCI Pass-Through device assignment. A prerequisite for this feature is a VM Host Server configuration as described in Important: Requirements for VFIO and SR-IOV.
To be able to assign a PCI device via VFIO to a VM Guest, you need to find out which IOMMU Group it belongs to. The IOMMU (input/output memory management unit that connects a direct memory access-capable I/O bus to the main memory) API supports the notion of groups. A group is a set of devices that can be isolated from all other devices in the system. Groups are therefore the unit of ownership used by VFIO.
Identify the host PCI device to assign to the guest.
tux >
sudo lspci -nn
[...]
00:10.0 Ethernet controller [0200]: Intel Corporation 82576 \
Virtual Function [8086:10ca] (rev 01)
[...]
Note down the device ID (00:10.0
in this case) and
the vendor ID (8086:10ca
).
Find the IOMMU group of this device:
tux >
sudo readlink /sys/bus/pci/devices/0000\:00\:10.0/iommu_group
../../../kernel/iommu_groups/20
The IOMMU group for this device is 20
. Now you can
check the devices belonging to the same IOMMU group:
ls -l /sys/bus/pci/devices/0000:01:10.0/iommu_group/devices/0000:01:10.0 [...] 0000:00:1e.0 -> ../../../../devices/pci0000:00/0000:00:1e.0 [...] 0000:01:10.0 -> ../../../../devices/pci0000:00/0000:00:1e.0/0000:01:10.0 [...] 0000:01:10.1 -> ../../../../devices/pci0000:00/0000:00:1e.0/0000:01:10.1
Unbind the device from the device driver:
sudo echo "0000:01:10.0" > /sys/bus/pci/devices/0000\:01\:10.0/driver/unbind
Bind the device to the vfio-pci driver using the vendor ID from step 1:
sudo echo "8086 153a" > /sys/bus/pci/drivers/vfio-pci/new_id
A new device
/dev/vfio/IOMMU_GROUP
will be created as a result, /dev/vfio/20
in this
case.
Change the ownership of the newly created device:
chown qemu.qemu /dev/vfio/DEVICE
Now run the VM Guest with the PCI device assigned.
qemu-system-ARCH [...] -device vfio-pci,host=00:10.0,id=ID
As of openSUSE Leap 42.3 hotplugging of PCI devices passed to a VM Guest via VFIO is not supported.
You can find more detailed information on the
VFIO driver in the
/usr/src/linux/Documentation/vfio.txt
file (package
kernel-source
needs to be installed).
VM Guests usually run in a separate computing space—they are provided their own memory range, dedicated CPUs, and file system space. The ability to share parts of the VM Host Server's file system makes the virtualization environment more flexible by simplifying mutual data exchange. Network file systems, such as CIFS and NFS, have been the traditional way of sharing directories. But as they are not specifically designed for virtualization purposes, they suffer from major performance and feature issues.
KVM introduces a new optimized method called VirtFS (sometimes called “file system pass-through”). VirtFS uses a paravirtual file system driver, which avoids converting the guest application file system operations into block device operations, and then again into host file system operations.
You typically use VirtFS for the following situations:
To access a shared directory from several guests, or to provide guest-to-guest file system access.
To replace the virtual disk as the root file system to which the guest's RAM disk connects during the guest boot process.
To provide storage services to different customers from a single host file system in a cloud environment.
In QEMU, the implementation of VirtFS is simplified by defining two types of devices:
virtio-9p-pci
device which transports protocol
messages and data between the host and the guest.
fsdev
device which defines the export file system
properties, such as file system type and security model.
qemu-system-x86_64 [...] \ -fsdev local,id=exp11,path=/tmp/2,security_model=mapped3 \ -device virtio-9p-pci,fsdev=exp14,mount_tag=v_tmp5
Identification of the file system to be exported. | |
File system path on the host to be exported. | |
Security model to be used— | |
The exported file system ID defined before with | |
Mount tag used later on the guest to mount the exported file system. |
Such an exported file system can be mounted on the guest as follows:
sudo mount -t 9p -o trans=virtio v_tmp /mnt
where v_tmp
is the mount tag defined earlier with
-device mount_tag=
and /mnt
is
the mount point where you want to mount the exported file system.
Kernel Same Page Merging (KSM) is a Linux kernel feature that merges identical memory pages from multiple running processes into one memory region. Because KVM guests run as processes under Linux, KSM provides the memory overcommit feature to hypervisors for more efficient use of memory. Therefore, if you need to run multiple virtual machines on a host with limited memory, KSM may be helpful to you.
KSM stores its status information in
the files under the /sys/kernel/mm/ksm
directory:
tux >
ls -1 /sys/kernel/mm/ksm
full_scans
merge_across_nodes
pages_shared
pages_sharing
pages_to_scan
pages_unshared
pages_volatile
run
sleep_millisecs
For more information on the meaning of the
/sys/kernel/mm/ksm/*
files, see
/usr/src/linux/Documentation/vm/ksm.txt
(package
kernel-source
).
To use KSM, do the following.
Although openSUSE Leap includes KSM support in the kernel, it is disabled by default. To enable it, run the following command:
root #
echo 1 > /sys/kernel/mm/ksm/run
Now run several VM Guests under KVM and inspect the content of
files pages_sharing
and
pages_shared
, for example:
while [ 1 ]; do cat /sys/kernel/mm/ksm/pages_shared; sleep 1; done 13522 13523 13519 13518 13520 13520 13528