CPU topologies

The NUMA topology and CPU pinning features in OpenStack provide high-level control over how instances run on hypervisor CPUs and the topology of virtual CPUs available to instances. These features help minimize latency and maximize performance.

Important

In deployments older than Train, or in mixed Stein/Train deployments with a rolling upgrade in progress, unless specifically enabled, live migration is not possible for instances with a NUMA topology when using the libvirt driver. A NUMA topology may be specified explicitly or can be added implicitly due to the use of CPU pinning or huge pages. Refer to bug #1289064 for more information. As of Train, live migration of instances with a NUMA topology when using the libvirt driver is fully supported.

SMP, NUMA, and SMT

Symmetric multiprocessing (SMP)

SMP is a design found in many modern multi-core systems. In an SMP system, there are two or more CPUs and these CPUs are connected by some interconnect. This provides CPUs with equal access to system resources like memory and input/output ports.

Non-uniform memory access (NUMA)

NUMA is a derivative of the SMP design that is found in many multi-socket systems. In a NUMA system, system memory is divided into cells or nodes that are associated with particular CPUs. Requests for memory on other nodes are possible through an interconnect bus. However, bandwidth across this shared bus is limited. As a result, competition for this resource can incur performance penalties.

Simultaneous Multi-Threading (SMT)

SMT is a design complementary to SMP. Whereas CPUs in SMP systems share a bus and some memory, CPUs in SMT systems share many more components. CPUs that share components are known as thread siblings. All CPUs appear as usable CPUs on the system and can execute workloads in parallel. However, as with NUMA, threads compete for shared resources.

Non-Uniform I/O Access (NUMA I/O)

In a NUMA system, I/O to a device mapped to a local memory region is more efficient than I/O to a remote device. A device connected to the same socket providing the CPU and memory offers lower latencies for I/O operations due to its physical proximity. This generally manifests itself in devices connected to the PCIe bus, such as NICs or vGPUs, but applies to any device support memory-mapped I/O.

In OpenStack, SMP CPUs are known as cores, NUMA cells or nodes are known as sockets, and SMT CPUs are known as threads. For example, a quad-socket, eight core system with Hyper-Threading would have four sockets, eight cores per socket and two threads per core, for a total of 64 CPUs.

PCPU and VCPU

PCPU

Resource class representing an amount of dedicated CPUs for a single guest.

VCPU

Resource class representing a unit of CPU resources for a single guest approximating the processing power of a single physical processor.

Customizing instance NUMA placement policies

Important

The functionality described below is currently only supported by the libvirt/KVM driver.

When running workloads on NUMA hosts, it is important that the vCPUs executing processes are on the same NUMA node as the memory used by these processes. This ensures all memory accesses are local to the node and thus do not consume the limited cross-node memory bandwidth, adding latency to memory accesses. Similarly, large pages are assigned from memory and benefit from the same performance improvements as memory allocated using standard pages. Thus, they also should be local. Finally, PCI devices are directly associated with specific NUMA nodes for the purposes of DMA. Instances that use PCI or SR-IOV devices should be placed on the NUMA node associated with these devices.

NUMA topology can exist on both the physical hardware of the host and the virtual hardware of the instance. In OpenStack, when booting a process, the hypervisor driver looks at the NUMA topology field of both the instance and the host it is being booted on, and uses that information to generate an appropriate configuration.

By default, an instance floats across all NUMA nodes on a host. NUMA awareness can be enabled implicitly through the use of huge pages or pinned CPUs or explicitly through the use of flavor extra specs or image metadata. If the instance has requested a specific NUMA topology, compute will try to pin the vCPUs of different NUMA cells on the instance to the corresponding NUMA cells on the host. It will also expose the NUMA topology of the instance to the guest OS.

In all cases where NUMA awareness is used, the NUMATopologyFilter filter must be enabled. Details on this filter are provided in Compute schedulers.

The host’s NUMA node(s) used are chosen based on some logic and controlled by packing_host_numa_cells_allocation_strategy configuration variable in nova.conf. By default packing_host_numa_cells_allocation_strategy variable is set to True. It leads to attempt to chose NUMA node(s) with less amount of free resources (or in other words more used NUMA nodes) first. It is so-called “pack” strategy - we try to place as much as possible load at more used host’s NUMA node until it will be completely exhausted. And only after we will choose most used host’s NUMA node from the rest available nodes on host. “Spread” strategy is reverse to “pack” strategy. The NUMA node(s) with more free resources will be used first. So “spread” strategy will try to balance load between all NUMA nodes and keep number of free resources on all NUMA nodes as more equal as possible.

Caution

Host’s NUMA nodes are placed in list and list is sorted based on strategy chosen and resource available in each NUMA node. Sorts are performed on same list one after another, so the last sort implemented is the sort with most priority.

The python performed so-called stable sort. It means that each sort executed on same list will change order of list items only if item’s property we sort on differs. If this properties in all list’s items are equal than elements order will not changed.

Sorts are performed on host’s NUMA nodes list in the following order:

  • sort based on available memory on node(first sort-less priority)

  • sort based on cpu usage (in case of shared CPUs requested by guest VM topology) or free pinned cpus otherwise.

  • sort based on number of free PCI device on node(last sort-top priority)

Top sorting priority is for host’s NUMA nodes with PCI devices attached. If VM requested PCI device(s) logic always puts host’s NUMA nodes with more PCI devices at the beginning of the host’s NUMA nodes list. If PCI devices isn’t requested by VM than NUMA nodes with no (or less) PCI device available will be placed at the beginning of the list.

Caution

The described logic for PCI devices is used both for “pack” and “spread” strategies. It is done to keep backward compatibility with previous nova versions.

During “pack” logic implementation rest (two) sorts are performed with sort order to move NUMA nodes with more available resources (CPUs and memory) at the END of host’s NUMA nodes list. Sort based on memory is the first sort implemented and has least priority.

During “spread” logic implementation rest (two) sorts are performed with sort order to move NUMA nodes with more available resources (CPUs and memory) at the BEGINNING of host’s NUMA nodes list. Sort based on memory is the first sort implemented and has least priority.

Finally resulting list (after all sorts) is passed next and attempts to place VM’s NUMA node to host’s NUMA node are performed starting from the first host’s NUMA node in list.

Caution

Inadequate per-node resources will result in scheduling failures. Resources that are specific to a node include not only CPUs and memory, but also PCI and SR-IOV resources. It is not possible to use multiple resources from different nodes without requesting a multi-node layout. As such, it may be necessary to ensure PCI or SR-IOV resources are associated with the same NUMA node or force a multi-node layout.

When used, NUMA awareness allows the operating system of the instance to intelligently schedule the workloads that it runs and minimize cross-node memory bandwidth. To configure guest NUMA nodes, you can use the hw:numa_nodes flavor extra spec. For example, to restrict an instance’s vCPUs to a single host NUMA node, run:

$ openstack flavor set $FLAVOR --property hw:numa_nodes=1

Some workloads have very demanding requirements for memory access latency or bandwidth that exceed the memory bandwidth available from a single NUMA node. For such workloads, it is beneficial to spread the instance across multiple host NUMA nodes, even if the instance’s RAM/vCPUs could theoretically fit on a single NUMA node. To force an instance’s vCPUs to spread across two host NUMA nodes, run:

$ openstack flavor set $FLAVOR --property hw:numa_nodes=2

The allocation of instance vCPUs and memory from different host NUMA nodes can be configured. This allows for asymmetric allocation of vCPUs and memory, which can be important for some workloads. You can configure the allocation of instance vCPUs and memory across each guest NUMA node using the hw:numa_cpus.{num} and hw:numa_mem.{num} extra specs respectively. For example, to spread the 6 vCPUs and 6 GB of memory of an instance across two NUMA nodes and create an asymmetric 1:2 vCPU and memory mapping between the two nodes, run:

$ openstack flavor set $FLAVOR --property hw:numa_nodes=2
# configure guest node 0
$ openstack flavor set $FLAVOR \
  --property hw:numa_cpus.0=0,1 \
  --property hw:numa_mem.0=2048
# configure guest node 1
$ openstack flavor set $FLAVOR \
  --property hw:numa_cpus.1=2,3,4,5 \
  --property hw:numa_mem.1=4096

Note

The {num} parameter is an index of guest NUMA nodes and may not correspond to host NUMA nodes. For example, on a platform with two NUMA nodes, the scheduler may opt to place guest NUMA node 0, as referenced in hw:numa_mem.0 on host NUMA node 1 and vice versa. Similarly, the CPUs bitmask specified in the value for hw:numa_cpus.{num} refer to guest vCPUs and may not correspond to host CPUs. As such, this feature cannot be used to constrain instances to specific host CPUs or NUMA nodes.

Warning

If the combined values of hw:numa_cpus.{num} or hw:numa_mem.{num} are greater than the available number of CPUs or memory respectively, an exception will be raised.

For more information about the syntax for hw:numa_nodes, hw:numa_cpus.N and hw:num_mem.N, refer to Extra Specs.

Customizing instance CPU pinning policies

Important

The functionality described below is currently only supported by the libvirt/KVM driver and requires some host configuration for this to work.

Note

There is no correlation required between the NUMA topology exposed in the instance and how the instance is actually pinned on the host. This is by design. See this invalid bug for more information.

By default, instance vCPU processes are not assigned to any particular host CPU, instead, they float across host CPUs like any other process. This allows for features like overcommitting of CPUs. In heavily contended systems, this provides optimal system performance at the expense of performance and latency for individual instances.

Some workloads require real-time or near real-time behavior, which is not possible with the latency introduced by the default CPU policy. For such workloads, it is beneficial to control which host CPUs are bound to an instance’s vCPUs. This process is known as pinning. No instance with pinned CPUs can use the CPUs of another pinned instance, thus preventing resource contention between instances.

CPU pinning policies can be used to determine whether an instance should be pinned or not. They can be configured using the hw:cpu_policy extra spec and equivalent image metadata property. There are three policies: dedicated, mixed and shared (the default). The dedicated CPU policy is used to specify that all CPUs of an instance should use pinned CPUs. To configure a flavor to use the dedicated CPU policy, run:

$ openstack flavor set $FLAVOR --property hw:cpu_policy=dedicated

This works by ensuring PCPU allocations are used instead of VCPU allocations. As such, it is also possible to request this resource type explicitly. To configure this, run:

$ openstack flavor set $FLAVOR --property resources:PCPU=N

(where N is the number of vCPUs defined in the flavor).

Note

It is not currently possible to request PCPU and VCPU resources in the same instance.

The shared CPU policy is used to specify that an instance should not use pinned CPUs. To configure a flavor to use the shared CPU policy, run:

$ openstack flavor set $FLAVOR --property hw:cpu_policy=shared

The mixed CPU policy is used to specify that an instance use pinned CPUs along with unpinned CPUs. The instance pinned CPU could be specified in the hw:cpu_dedicated_mask or, if real-time is enabled, in the hw:cpu_realtime_mask extra spec. For example, to configure a flavor to use the mixed CPU policy with 4 vCPUs in total and the first 2 vCPUs as pinned CPUs, run:

$ openstack flavor set $FLAVOR \
  --vcpus=4 \
  --property hw:cpu_policy=mixed \
  --property hw:cpu_dedicated_mask=0-1

To configure a flavor to use the mixed CPU policy with 4 vCPUs in total and the first 2 vCPUs as pinned real-time CPUs, run:

$ openstack flavor set $FLAVOR \
  --vcpus=4 \
  --property hw:cpu_policy=mixed \
  --property hw:cpu_realtime=yes \
  --property hw:cpu_realtime_mask=0-1

Note

For more information about the syntax for hw:cpu_policy, hw:cpu_dedicated_mask, hw:realtime_cpu and hw:cpu_realtime_mask, refer to Extra Specs

Note

For more information about real-time functionality, refer to the documentation.

It is also possible to configure the CPU policy via image metadata. This can be useful when packaging applications that require real-time or near real-time behavior by ensuring instances created with a given image are always pinned regardless of flavor. To configure an image to use the dedicated CPU policy, run:

$ openstack image set $IMAGE --property hw_cpu_policy=dedicated

Likewise, to configure an image to use the shared CPU policy, run:

$ openstack image set $IMAGE --property hw_cpu_policy=shared

Note

For more information about image metadata, refer to the Image metadata guide.

Important

Flavor-based policies take precedence over image-based policies. For example, if a flavor specifies a CPU policy of dedicated then that policy will be used. If the flavor specifies a CPU policy of shared and the image specifies no policy or a policy of shared then the shared policy will be used. However, the flavor specifies a CPU policy of shared and the image specifies a policy of dedicated, or vice versa, an exception will be raised. This is by design. Image metadata is often configurable by non-admin users, while flavors are only configurable by admins. By setting a shared policy through flavor extra-specs, administrators can prevent users configuring CPU policies in images and impacting resource utilization.

Customizing instance CPU thread pinning policies

Important

The functionality described below requires the use of pinned instances and is therefore currently only supported by the libvirt/KVM driver and requires some host configuration for this to work.

When running pinned instances on SMT hosts, it may also be necessary to consider the impact that thread siblings can have on the instance workload. The presence of an SMT implementation like Intel Hyper-Threading can boost performance by up to 30% for some workloads. However, thread siblings share a number of components and contention on these components can diminish performance for other workloads. For this reason, it is also possible to explicitly request hosts with or without SMT.

To configure whether an instance should be placed on a host with SMT or not, a CPU thread policy may be specified. For workloads where sharing benefits performance, you can request hosts with SMT. To configure this, run:

$ openstack flavor set $FLAVOR \
  --property hw:cpu_policy=dedicated \
  --property hw:cpu_thread_policy=require

This will ensure the instance gets scheduled to a host with SMT by requesting hosts that report the HW_CPU_HYPERTHREADING trait. It is also possible to request this trait explicitly. To configure this, run:

$ openstack flavor set $FLAVOR \
  --property resources:PCPU=N \
  --property trait:HW_CPU_HYPERTHREADING=required

For other workloads where performance is impacted by contention for resources, you can request hosts without SMT. To configure this, run:

$ openstack flavor set $FLAVOR \
  --property hw:cpu_policy=dedicated \
  --property hw:cpu_thread_policy=isolate

This will ensure the instance gets scheduled to a host without SMT by requesting hosts that do not report the HW_CPU_HYPERTHREADING trait. It is also possible to request this trait explicitly. To configure this, run:

$ openstack flavor set $FLAVOR \
  --property resources:PCPU=N \
  --property trait:HW_CPU_HYPERTHREADING=forbidden

Finally, for workloads where performance is minimally impacted, you may use thread siblings if available and fallback to not using them if necessary. This is the default, but it can be set explicitly:

$ openstack flavor set $FLAVOR \
  --property hw:cpu_policy=dedicated \
  --property hw:cpu_thread_policy=prefer

This does not utilize traits and, as such, there is no trait-based equivalent.

Note

For more information about the syntax for hw:cpu_thread_policy, refer to Extra Specs.

As with CPU policies, it also possible to configure the CPU thread policy via image metadata. This can be useful when packaging applications that require real-time or near real-time behavior by ensuring instances created with a given image are always pinned regardless of flavor. To configure an image to use the require CPU policy, run:

$ openstack image set $IMAGE \
  --property hw_cpu_policy=dedicated \
  --property hw_cpu_thread_policy=require

Likewise, to configure an image to use the isolate CPU thread policy, run:

$ openstack image set $IMAGE \
  --property hw_cpu_policy=dedicated \
  --property hw_cpu_thread_policy=isolate

Finally, to configure an image to use the prefer CPU thread policy, run:

$ openstack image set $IMAGE \
  --property hw_cpu_policy=dedicated \
  --property hw_cpu_thread_policy=prefer

If the flavor does not specify a CPU thread policy then the CPU thread policy specified by the image (if any) will be used. If both the flavor and image specify a CPU thread policy then they must specify the same policy, otherwise an exception will be raised.

Note

For more information about image metadata, refer to the Image metadata guide.

Customizing instance emulator thread pinning policies

Important

The functionality described below requires the use of pinned instances and is therefore currently only supported by the libvirt/KVM driver and requires some host configuration for this to work.

In addition to the work of the guest OS and applications running in an instance, there is a small amount of overhead associated with the underlying hypervisor. By default, these overhead tasks - known collectively as emulator threads - run on the same host CPUs as the instance itself and will result in a minor performance penalty for the instance. This is not usually an issue, however, for things like real-time instances, it may not be acceptable for emulator thread to steal time from instance CPUs.

Emulator thread policies can be used to ensure emulator threads are run on cores separate from those used by the instance. There are two policies: isolate and share. The default is to run the emulator threads on the same core. The isolate emulator thread policy is used to specify that emulator threads for a given instance should be run on their own unique core, chosen from one of the host cores listed in compute.cpu_dedicated_set. To configure a flavor to use the isolate emulator thread policy, run:

$ openstack flavor set $FLAVOR \
  --property hw:cpu_policy=dedicated \
  --property hw:emulator_threads_policy=isolate

The share policy is used to specify that emulator threads from a given instance should be run on the pool of host cores listed in compute.cpu_shared_set if configured, else across all pCPUs of the instance. To configure a flavor to use the share emulator thread policy, run:

$ openstack flavor set $FLAVOR \
  --property hw:cpu_policy=dedicated \
  --property hw:emulator_threads_policy=share

The above behavior can be summarized in this helpful table:

compute.cpu_shared_set set

compute.cpu_shared_set unset

hw:emulator_treads_policy unset (default)

Pinned to all of the instance’s pCPUs

Pinned to all of the instance’s pCPUs

hw:emulator_threads_policy = share

Pinned to compute.cpu_shared_set

Pinned to all of the instance’s pCPUs

hw:emulator_threads_policy = isolate

Pinned to a single pCPU distinct from the instance’s pCPUs

Pinned to a single pCPU distinct from the instance’s pCPUs

Note

For more information about the syntax for hw:emulator_threads_policy, refer to hw:emulator_threads_policy.

Customizing instance CPU topologies

Important

The functionality described below is currently only supported by the libvirt/KVM driver.

Note

Currently it also works with libvirt/QEMU driver but we don’t recommend it in production use cases. This is because vCPUs are actually running in one thread on host in qemu TCG (Tiny Code Generator), which is the backend for libvirt/QEMU driver. Work to enable full multi-threading support for TCG (a.k.a. MTTCG) is on going in QEMU community. Please see this MTTCG project page for detail.

In addition to configuring how an instance is scheduled on host CPUs, it is possible to configure how CPUs are represented in the instance itself. By default, when instance NUMA placement is not specified, a topology of N sockets, each with one core and one thread, is used for an instance, where N corresponds to the number of instance vCPUs requested. When instance NUMA placement is specified, the number of sockets is fixed to the number of host NUMA nodes to use and the total number of instance CPUs is split over these sockets.

Some workloads benefit from a custom topology. For example, in some operating systems, a different license may be needed depending on the number of CPU sockets. To configure a flavor to use two sockets, run:

$ openstack flavor set $FLAVOR --property hw:cpu_sockets=2

Similarly, to configure a flavor to use one core and one thread, run:

$ openstack flavor set $FLAVOR \
  --property hw:cpu_cores=1 \
  --property hw:cpu_threads=1

Caution

If specifying all values, the product of sockets multiplied by cores multiplied by threads must equal the number of instance vCPUs. If specifying any one of these values or the multiple of two values, the values must be a factor of the number of instance vCPUs to prevent an exception. For example, specifying hw:cpu_sockets=2 on a host with an odd number of cores fails. Similarly, specifying hw:cpu_cores=2 and hw:cpu_threads=4 on a host with ten cores fails.

For more information about the syntax for hw:cpu_sockets, hw:cpu_cores and hw:cpu_threads, refer to Extra Specs.

It is also possible to set upper limits on the number of sockets, cores, and threads used. Unlike the hard values above, it is not necessary for this exact number to used because it only provides a limit. This can be used to provide some flexibility in scheduling, while ensuring certain limits are not exceeded. For example, to ensure no more than two sockets, eight cores and one thread are defined in the instance topology, run:

$ openstack flavor set $FLAVOR \
  --property hw:cpu_max_sockets=2 \
  --property hw:cpu_max_cores=8 \
  --property hw:cpu_max_threads=1

For more information about the syntax for hw:cpu_max_sockets, hw:cpu_max_cores, and hw:cpu_max_threads, refer to Extra Specs.

Applications are frequently packaged as images. For applications that prefer certain CPU topologies, configure image metadata to hint that created instances should have a given topology regardless of flavor. To configure an image to request a two-socket, four-core per socket topology, run:

$ openstack image set $IMAGE \
  --property hw_cpu_sockets=2 \
  --property hw_cpu_cores=4

To constrain instances to a given limit of sockets, cores or threads, use the max_ variants. To configure an image to have a maximum of two sockets and a maximum of one thread, run:

$ openstack image set $IMAGE \
  --property hw_cpu_max_sockets=2 \
  --property hw_cpu_max_threads=1

The value specified in the flavor is treated as the absolute limit. The image limits are not permitted to exceed the flavor limits, they can only be equal to or lower than what the flavor defines. By setting a max value for sockets, cores, or threads, administrators can prevent users configuring topologies that might, for example, incur an additional licensing fees.

For more information about image metadata, refer to the Image metadata guide.

Configuring libvirt compute nodes for CPU pinning

Changed in version 20.0.0: Prior to 20.0.0 (Train), it was not necessary to explicitly configure hosts for pinned instances. However, it was not possible to place pinned instances on the same host as unpinned CPUs, which typically meant hosts had to be grouped into host aggregates. If this was not done, unpinned instances would continue floating across all enabled host CPUs, even those that some instance CPUs were pinned to. Starting in 20.0.0, it is necessary to explicitly identify the host cores that should be used for pinned instances.

Nova treats host CPUs used for unpinned instances differently from those used by pinned instances. The former are tracked in placement using the VCPU resource type and can be overallocated, while the latter are tracked using the PCPU resource type. By default, nova will report all host CPUs as VCPU inventory, however, this can be configured using the compute.cpu_shared_set config option, to specify which host CPUs should be used for VCPU inventory, and the compute.cpu_dedicated_set config option, to specify which host CPUs should be used for PCPU inventory.

Consider a compute node with a total of 24 host physical CPU cores with hyperthreading enabled. The operator wishes to reserve 1 physical CPU core and its thread sibling for host processing (not for guest instance use). Furthermore, the operator wishes to use 8 host physical CPU cores and their thread siblings for dedicated guest CPU resources. The remaining 15 host physical CPU cores and their thread siblings will be used for shared guest vCPU usage, with an 8:1 allocation ratio for those physical processors used for shared guest CPU resources.

The operator could configure nova.conf like so:

[DEFAULT]
cpu_allocation_ratio=8.0

[compute]
cpu_dedicated_set=2-17
cpu_shared_set=18-47

The virt driver will construct a provider tree containing a single resource provider representing the compute node and report inventory of PCPU and VCPU for this single provider accordingly:

COMPUTE NODE provider
    PCPU:
        total: 16
        reserved: 0
        min_unit: 1
        max_unit: 16
        step_size: 1
        allocation_ratio: 1.0
    VCPU:
        total: 30
        reserved: 0
        min_unit: 1
        max_unit: 30
        step_size: 1
        allocation_ratio: 8.0

Instances using the dedicated CPU policy or an explicit PCPU resource request, PCPU inventory will be consumed. Instances using the shared CPU policy, meanwhile, will consume VCPU inventory.

Note

PCPU and VCPU allocations are currently combined to calculate the value for the cores quota class.

Configuring CPU power management for dedicated cores

Changed in version 27.0.0: This feature was only introduced by the 2023.1 Antelope release

Important

The functionality described below is currently only supported by the libvirt/KVM driver.

For power saving reasons, operators can decide to turn down the power usage of CPU cores whether they are in use or not. For obvious reasons, Nova only allows to change the power consumption of a dedicated CPU core and not a shared one. Accordingly, usage of this feature relies on the reading of compute.cpu_dedicated_set config option to know which CPU cores to handle. The main action to enable the power management of dedicated cores is to set libvirt.cpu_power_management config option to True.

By default, if this option is enabled, Nova will lookup the dedicated cores and power them down at the compute service startup. Then, once an instance starts by being attached to a dedicated core, this below core will be powered up right before the libvirt guest starts. On the other way, once an instance is stopped, migrated or deleted, then the corresponding dedicated core will be powered down.

There are two distinct strategies for powering up or down :

  • the default is to offline the CPU core and online it when needed.

  • an alternative strategy is to use two distinct CPU governors for the up state and the down state.

The strategy can be chosen using libvirt.cpu_power_management_strategy config option. cpu_state supports the first online/offline strategy, while governor sets the alternative strategy. We default to turning off the cores as it provides you the best power savings while there could be other tools outside Nova to manage the governor, like tuned. That being said, we also provide a way to automatically change the governors on the fly, as explained below.

Important

Some OS platforms don’t support cpufreq resources in sysfs, so the governor strategy could be not available. Please verify if your OS supports scaling govenors before modifying the configuration option.

If the strategy is set to governor, a couple of config options are provided to define which exact CPU governor to use for each of the up and down states :

Important

This is the responsibility of the operator to ensure that the govenors defined by the configuration options are currently supported by the OS underlying kernel that runs the compute service.

As a side note, we recommend the schedutil governor as an alternative for the high-power state (if the kernel supports it) as the CPU frequency is dynamically set based on CPU task states. Other governors may be worth to be tested, including conservative and ondemand which are quite a bit more power consuming than schedutil but more efficient than performance. See Linux kernel docs for further explanations.

As an example, a nova.conf part of configuration would look like:

[compute]
cpu_dedicated_set=2-17

[libvirt]
cpu_power_management=True
cpu_power_management_strategy=cpu_state

Warning

The CPU core #0 has a special meaning in most of the recent Linux kernels. This is always highly discouraged to use it for CPU pinning but please refrain to have it power managed or you could have surprises if Nova turns it off!

One last important note : you can decide to change the CPU management strategy during the compute lifecycle, or you can currently already manage the CPU states. For ensuring that Nova can correctly manage the CPU performances, we added a couple of checks at startup that refuse to start nova-compute service if those arbitrary rules aren’t enforced :

  • if the operator opts for cpu_state strategy, then all dedicated CPU governors MUST be identical.

  • if they decide using governor, then all dedicated CPU cores MUST be online.