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Reviewed-by: Peter Krempa <pkrempa@redhat.com> Signed-off-by: Daniel P. Berrangé <berrange@redhat.com>
215 lines
8.0 KiB
ReStructuredText
215 lines
8.0 KiB
ReStructuredText
==========================
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KVM Real Time Guest Config
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==========================
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.. contents::
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The KVM hypervisor is capable of running real time guest workloads. This page
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describes the key pieces of configuration required in the domain XML to achieve
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the low latency needs of real time workloads.
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For the most part, configuration of the host OS is out of scope of this
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documentation. Refer to the operating system vendor's guidance on configuring
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the host OS and hardware for real time. Note in particular that the default
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kernel used by most Linux distros is not suitable for low latency real time and
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must be replaced by a special kernel build.
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Host partitioning plan
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======================
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Running real time workloads requires carefully partitioning up the host OS
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resources, such that the KVM / QEMU processes are strictly separated from any
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other workload running on the host, both userspace processes and kernel threads.
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As such, some subset of host CPUs need to be reserved exclusively for running
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KVM guests. This requires that the host kernel be booted using the ``isolcpus``
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kernel command line parameter. This parameter removes a set of CPUs from the
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scheduler, such that that no kernel threads or userspace processes will ever get
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placed on those CPUs automatically. KVM guests are then manually placed onto
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these CPUs.
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Deciding which host CPUs to reserve for real time requires understanding of the
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guest workload needs and balancing with the host OS needs. The trade off will
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also vary based on the physical hardware available.
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For the sake of illustration, this guide will assume a physical machine with two
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NUMA nodes, each with 2 sockets and 4 cores per socket, giving a total of 16
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CPUs on the host. Furthermore, it is assumed that hyperthreading is either not
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supported or has been disabled in the BIOS, since it is incompatible with real
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time. Each NUMA node is assumed to have 32 GB of RAM, giving 64 GB total for
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the host.
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It is assumed that 2 CPUs in each NUMA node are reserved for the host OS, with
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the remaining 6 CPUs available for KVM real time. With this in mind, the host
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kernel should have booted with ``isolcpus=2-7,10-15`` to reserve CPUs.
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To maximise efficiency of page table lookups for the guest, the host needs to be
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configured with most RAM exposed as huge pages, ideally 1 GB sized. 6 GB of RAM
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in each NUMA node will be reserved for general host OS usage as normal sized
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pages, leaving 26 GB for KVM usage as huge pages.
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Once huge pages are reserved on the hypothetical machine, the ``virsh
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capabilities`` command output is expected to look approximately like:
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::
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<topology>
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<cells num='2'>
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<cell id='0'>
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<memory unit='KiB'>33554432</memory>
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<pages unit='KiB' size='4'>1572864</pages>
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<pages unit='KiB' size='2048'>0</pages>
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<pages unit='KiB' size='1048576'>26</pages>
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<distances>
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<sibling id='0' value='10'/>
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<sibling id='1' value='21'/>
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</distances>
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<cpus num='8'>
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<cpu id='0' socket_id='0' core_id='0' siblings='0'/>
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<cpu id='1' socket_id='0' core_id='1' siblings='1'/>
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<cpu id='2' socket_id='0' core_id='2' siblings='2'/>
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<cpu id='3' socket_id='0' core_id='3' siblings='3'/>
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<cpu id='4' socket_id='1' core_id='0' siblings='4'/>
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<cpu id='5' socket_id='1' core_id='1' siblings='5'/>
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<cpu id='6' socket_id='1' core_id='2' siblings='6'/>
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<cpu id='7' socket_id='1' core_id='3' siblings='7'/>
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</cpus>
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</cell>
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<cell id='1'>
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<memory unit='KiB'>33554432</memory>
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<pages unit='KiB' size='4'>1572864</pages>
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<pages unit='KiB' size='2048'>0</pages>
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<pages unit='KiB' size='1048576'>26</pages>
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<distances>
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<sibling id='0' value='21'/>
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<sibling id='1' value='10'/>
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</distances>
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<cpus num='8'>
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<cpu id='8' socket_id='0' core_id='0' siblings='8'/>
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<cpu id='9' socket_id='0' core_id='1' siblings='9'/>
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<cpu id='10' socket_id='0' core_id='2' siblings='10'/>
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<cpu id='11' socket_id='0' core_id='3' siblings='11'/>
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<cpu id='12' socket_id='1' core_id='0' siblings='12'/>
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<cpu id='13' socket_id='1' core_id='1' siblings='13'/>
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<cpu id='14' socket_id='1' core_id='2' siblings='14'/>
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<cpu id='15' socket_id='1' core_id='3' siblings='15'/>
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</cpus>
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</cell>
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</cells>
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</topology>
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Be aware that CPU ID numbers are not always allocated sequentially as shown
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here. It is not unusual to see IDs interleaved between sockets on the two NUMA
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nodes, such that ``0-3,8-11`` are on the first node and ``4-7,12-15`` are on
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the second node. Carefully check the ``virsh capabilities`` output to determine
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the CPU ID numbers when configiring both ``isolcpus`` and the guest ``cpuset``
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values.
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Guest configuration
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===================
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What follows is an overview of the key parts of the domain XML that need to be
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configured to achieve low latency for real time workflows. The following example
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will assume a 4 CPU guest, requiring 16 GB of RAM. It is intended to be placed
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on the second host NUMA node.
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CPU configuration
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-----------------
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Real time KVM guests intended to run Linux should have a minimum of 2 CPUs.
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One vCPU is for running non-real time processes and performing I/O. The other
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vCPUs will run real time applications. Some non-Linux OS may not require a
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special non-real time CPU to be available, in which case the 2 CPU minimum would
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not apply.
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Each guest CPU, even the non-real time one, needs to be pinned to a dedicated
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host core that is in the `isolcpus` reserved set. The QEMU emulator threads
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need to be pinned to host CPUs that are not in the `isolcpus` reserved set.
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The vCPUs need to be given a real time CPU scheduler policy.
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When configuring the `guest CPU count <../formatdomain.html#elementsCPUAllocation>`_,
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do not include any CPU affinity at this stage:
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::
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<vcpu placement='static'>4</vcpu>
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The guest CPUs now need to be placed individually. In this case, they will all
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be put within the same host socket, such that they can be exposed as core
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siblings. This is achieved using the `CPU tuning config <../formatdomain.html#elementsCPUTuning>`_:
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::
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<cputune>
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<emulatorpin cpuset="8-9"/>
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<vcpupin vcpu="0" cpuset="12"/>
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<vcpupin vcpu="1" cpuset="13"/>
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<vcpupin vcpu="2" cpuset="14"/>
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<vcpupin vcpu="3" cpuset="15"/>
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<vcpusched vcpus='0-4' scheduler='fifo' priority='1'/>
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</cputune>
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The `guest CPU model <formatdomain.html#elementsCPU>`_ now needs to be
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configured to pass through the host model unchanged, with topology matching the
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placement:
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::
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<cpu mode='host-passthrough'>
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<topology sockets='1' dies='1' cores='4' threads='1'/>
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<feature policy='require' name='tsc-deadline'/>
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</cpu>
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The performance monitoring unit virtualization needs to be disabled
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via the `hypervisor features <../formatdomain.html#elementsFeatures>`_:
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::
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<features>
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...
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<pmu state='off'/>
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</features>
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Memory configuration
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--------------------
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The host memory used for guest RAM needs to be allocated from huge pages on the
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second NUMA node, and all other memory allocation needs to be locked into RAM
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with memory page sharing disabled.
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This is achieved by using the `memory backing config <formatdomain.html#elementsMemoryBacking>`_:
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::
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<memoryBacking>
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<hugepages>
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<page size="1" unit="G" nodeset="1"/>
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</hugepages>
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<locked/>
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<nosharepages/>
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</memoryBacking>
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Device configuration
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--------------------
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Libvirt adds a few devices by default to maintain historical QEMU configuration
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behaviour. It is unlikely these devices are required by real time guests, so it
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is wise to disable them. Remove all USB controllers that may exist in the XML
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config and replace them with:
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::
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<controller type="usb" model="none"/>
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Similarly the memory balloon config should be changed to
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::
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<memballoon model="none"/>
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If the guest had a graphical console at installation time this can also be
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disabled, with remote access being over SSH, with a minimal serial console
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for emergencies.
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