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20.11. CPU Model and Topology
This section covers the requirements for CPU model. Note that every hypervisor has its own policy for which CPU features guest will see by default. The set of CPU features presented to the guest by QEMU/KVM depends on the CPU model chosen in the guest virtual machine configuration.
qemu32
and qemu64
are basic CPU models but there are other models (with additional features) available. Each model and its topology is specified using the following elements from the domain XML:
<cpu match='exact'> <model fallback='allow'>core2duo</model> <vendor>Intel</vendor> <topology sockets='1' cores='2' threads='1'/> <feature policy='disable' name='lahf_lm'/> </cpu>
Figure 20.13. CPU model and topology example 1
<cpu mode='host-model'> <model fallback='forbid'/> <topology sockets='1' cores='2' threads='1'/> </cpu>
Figure 20.14. CPU model and topology example 2
<cpu mode='host-passthrough'/>
Figure 20.15. CPU model and topology example 3
In cases where no restrictions are to be put on either the CPU model nor its features, a simpler cpu element such as the following may be used.
<cpu> <topology sockets='1' cores='2' threads='1'/> </cpu>
Figure 20.16. CPU model and topology example 4
The components of this section of the domain XML are as follows:
Element | Description |
---|---|
<cpu> | This element contains all parameters for the vCPU feature set. |
<match> | Specifies how closely the features indicated in the <cpu> element must match the vCPUs that are available. The match attribute can be omitted if <topology> is the only element nested in the <cpu> element. Possible values for the match attribute are:
match attribute is omitted from the <cpu> element, the default setting match='exact' is used. |
<mode> | This optional attribute may be used to make it easier to configure a guest virtual machine CPU to be as close to the host physical machine CPU as possible. Possible values for the mode attribute are:
|
<model> | Specifies CPU model requested by the guest virtual machine. The list of available CPU models and their definition can be found in cpu_map.xml file installed in libvirt's data directory. If a hypervisor is not able to use the exact CPU model, libvirt automatically falls back to a closest model supported by the hypervisor while maintaining the list of CPU features. An optional fallback attribute can be used to forbid this behavior, in which case an attempt to start a domain requesting an unsupported CPU model will fail. Supported values for fallback attribute are: allow (this is the default), and forbid . The optional vendor_id attribute can be used to set the vendor id seen by the guest virtual machine. It must be exactly 12 characters long. If not set, the vendor id of the host physical machine is used. Typical possible values are AuthenticAMD and GenuineIntel . |
<vendor> | Specifies CPU vendor requested by the guest virtual machine. If this element is missing, the guest virtual machine runs on a CPU matching given features regardless of its vendor. The list of supported vendors can be found in cpu_map.xml . |
<topology> | Specifies requested topology of virtual CPU provided to the guest virtual machine. Three non-zero values have to be given for sockets, cores, and threads: total number of CPU sockets, number of cores per socket, and number of threads per core, respectively. |
<feature> | Can contain zero or more elements used to fine-tune features provided by the selected CPU model. The list of known feature names can be found in the same file as CPU models. The meaning of each feature element depends on its policy attribute, which has to be set to one of the following values:
|
20.11.1. Guest virtual machine NUMA topology
Guest virtual machine NUMA topology can be specified using the
<numa>
element and the following from the domain XML:
<cpu> <numa> <cell cpus='0-3' memory='512000'/> <cell cpus='4-7' memory='512000'/> </numa> </cpu> ...
Figure 20.17. Guest Virtual Machine NUMA Topology
Each cell element specifies a NUMA cell or a NUMA node.
cpus
specifies the CPU or range of CPUs that are part of the node. memory
specifies the node memory in kibibytes (blocks of 1024 bytes). Each cell or node is assigned cellid
or nodeid
in increasing order starting from 0.