Features are advertised as labels in the Kubernetes Node object.
Label creation in nfd-worker is performed by a set of separate modules called label sources. The core.labelSources
configuration option (or -label-sources
flag) of nfd-worker controls which sources to enable for label generation.
All built-in labels use the feature.node.kubernetes.io
label namespace and have the following format.
feature.node.kubernetes.io/<feature> = <value>
NOTE: Consecutive runs of nfd-worker will update the labels on a given node. If features are not discovered on a consecutive run, the corresponding label will be removed. This includes any restrictions placed on the consecutive run, such as restricting discovered features with the
-label-whitelist
flag of nfd-master orcore.labelWhiteList
option of nfd-worker.
Feature name | Value | Description |
---|---|---|
cpu-cpuid.<cpuid-flag> | true | CPU capability is supported. NOTE: the capability might be supported but not enabled. |
cpu-cpuid.<cpuid-attribute> | string | CPU attribute value |
cpu-hardware_multithreading | true | Hardware multithreading, such as Intel HTT, enabled (number of logical CPUs is greater than physical CPUs) |
cpu-coprocessor.nx_gzip | true | Nest Accelerator for GZIP is supported(Power). |
cpu-power.sst_bf.enabled | true | Intel SST-BF (Intel Speed Select Technology - Base frequency) enabled |
cpu-pstate.status | string | The status of the Intel pstate driver when in use and enabled, either ‘active' or ‘passive'. |
cpu-pstate.turbo | bool | Set to ‘true' if turbo frequencies are enabled in Intel pstate driver, set to ‘false' if they have been disabled. |
cpu-pstate.scaling_governor | string | The value of the Intel pstate scaling_governor when in use, either ‘powersave' or ‘performance'. |
cpu-cstate.enabled | bool | Set to ‘true' if cstates are set in the intel_idle driver, otherwise set to ‘false'. Unset if intel_idle cpuidle driver is not active. |
cpu-security.sgx.enabled | true | Set to ‘true' if Intel SGX is enabled in BIOS (based on a non-zero sum value of SGX EPC section sizes). |
cpu-security.se.enabled | true | Set to ‘true' if IBM Secure Execution for Linux (IBM Z & LinuxONE) is available and enabled (requires /sys/firmware/uv/prot_virt_host facility) |
cpu-security.tdx.enabled | true | Set to ‘true' if Intel TDX is available on the host and has been enabled (requires /sys/module/kvm_intel/parameters/tdx ). |
cpu-security.tdx.protected | true | Set to ‘true' if Intel TDX was used to start the guest node, based on the existence of the "TDX_GUEST" information as part of cpuid features. |
cpu-security.sev.enabled | true | Set to ‘true' if ADM SEV is available on the host and has been enabled (requires /sys/module/kvm_amd/parameters/sev ). |
cpu-security.sev.es.enabled | true | Set to ‘true' if ADM SEV-ES is available on the host and has been enabled (requires /sys/module/kvm_amd/parameters/sev_es ). |
cpu-security.sev.snp.enabled | true | Set to ‘true' if ADM SEV-SNP is available on the host and has been enabled (requires /sys/module/kvm_amd/parameters/sev_snp ). |
cpu-model.vendor_id | string | Comparable CPU vendor ID. |
cpu-model.family | int | CPU family. |
cpu-model.id | int | CPU model number. |
The CPU label source is configurable, see worker configuration and sources.cpu
configuration options for details.
Flag | Description |
---|---|
ADX | Multi-Precision Add-Carry Instruction Extensions (ADX) |
AESNI | Advanced Encryption Standard (AES) New Instructions (AES-NI) |
APX_F | Intel Advanced Performance Extensions (APX) |
AVX10 | Intel Advanced Vector Extensions 10 (AVX10) |
AVX10_256, AVX10_512 | Intel AVX10 256-bit and 512-bit vector support |
AVX | Advanced Vector Extensions (AVX) |
AVX2 | Advanced Vector Extensions 2 (AVX2) |
AVXIFMA | AVX-IFMA instructions |
AVXVNNI | AVX (VEX encoded) VNNI neural network instructions |
AMXBF16 | Advanced Matrix Extension, tile multiplication operations on BFLOAT16 numbers |
AMXINT8 | Advanced Matrix Extension, tile multiplication operations on 8-bit integers |
AMXFP16 | Advanced Matrix Extension, tile multiplication operations on FP16 numbers |
AMXTILE | Advanced Matrix Extension, base tile architecture support |
AVX512BF16 | AVX-512 BFLOAT16 instructions |
AVX512BITALG | AVX-512 bit Algorithms |
AVX512BW | AVX-512 byte and word Instructions |
AVX512CD | AVX-512 conflict detection instructions |
AVX512DQ | AVX-512 doubleword and quadword instructions |
AVX512ER | AVX-512 exponential and reciprocal instructions |
AVX512F | AVX-512 foundation |
AVX512FP16 | AVX-512 FP16 instructions |
AVX512IFMA | AVX-512 integer fused multiply-add instructions |
AVX512PF | AVX-512 prefetch instructions |
AVX512VBMI | AVX-512 vector bit manipulation instructions |
AVX512VBMI2 | AVX-512 vector bit manipulation instructions, version 2 |
AVX512VL | AVX-512 vector length extensions |
AVX512VNNI | AVX-512 vector neural network instructions |
AVX512VP2INTERSECT | AVX-512 intersect for D/Q |
AVX512VPOPCNTDQ | AVX-512 vector population count doubleword and quadword |
AVXNECONVERT | AVX-NE-CONVERT instructions |
AVXVNNIINT8 | AVX-VNNI-INT8 instructions |
CMPCCXADD | CMPCCXADD instructions |
ENQCMD | Enqueue Command |
GFNI | Galois Field New Instructions |
HYPERVISOR | Running under hypervisor |
MSRLIST | Read/Write List of Model Specific Registers |
PREFETCHI | PREFETCHIT0/1 instructions |
VAES | AVX-512 vector AES instructions |
VPCLMULQDQ | Carry-less multiplication quadword |
WRMSRNS | Non-Serializing Write to Model Specific Register |
By default, the following CPUID flags have been blacklisted: AVX10 (use AVX10_VERSION instead), BMI1, BMI2, CLMUL, CMOV, CX16, ERMS, F16C, HTT, LZCNT, MMX, MMXEXT, NX, POPCNT, RDRAND, RDSEED, RDTSCP, SGX, SSE, SSE2, SSE3, SSE4, SSE42, SSSE3 and TDX_GUEST. See sources.cpu
configuration options to change the behavior.
See the full list in github.com/klauspost/cpuid.
Attribute | Description |
---|---|
AVX10_VERSION | AVX10 vector ISA version (if supported) |
Flag | Description |
---|---|
IDIVA | Integer divide instructions available in ARM mode |
IDIVT | Integer divide instructions available in Thumb mode |
THUMB | Thumb instructions |
FASTMUL | Fast multiplication |
VFP | Vector floating point instruction extension (VFP) |
VFPv3 | Vector floating point extension v3 |
VFPv4 | Vector floating point extension v4 |
VFPD32 | VFP with 32 D-registers |
HALF | Half-word loads and stores |
EDSP | DSP extensions |
NEON | NEON SIMD instructions |
LPAE | Large Physical Address Extensions |
Flag | Description |
---|---|
AES | Announcing the Advanced Encryption Standard |
EVSTRM | Event Stream Frequency Features |
FPHP | Half Precision(16bit) Floating Point Data Processing Instructions |
ASIMDHP | Half Precision(16bit) Asimd Data Processing Instructions |
ATOMICS | Atomic Instructions to the A64 |
ASIMRDM | Support for Rounding Double Multiply Add/Subtract |
PMULL | Optional Cryptographic and CRC32 Instructions |
JSCVT | Perform Conversion to Match Javascript |
DCPOP | Persistent Memory Support |
Feature | Value | Description |
---|---|---|
kernel-config.<option> | true | Kernel config option is enabled (set ‘y' or ‘m'). Default options are NO_HZ , NO_HZ_IDLE , NO_HZ_FULL and PREEMPT |
kernel-selinux.enabled | true | Selinux is enabled on the node |
kernel-version.full | string | Full kernel version as reported by /proc/sys/kernel/osrelease (e.g. ‘4.5.6-7-g123abcde') |
kernel-version.major | string | First component of the kernel version (e.g. ‘4') |
kernel-version.minor | string | Second component of the kernel version (e.g. ‘5') |
kernel-version.revision | string | Third component of the kernel version (e.g. ‘6') |
The kernel label source is configurable, see worker configuration and sources.kernel
configuration options for details.
Feature | Value | Description |
---|---|---|
memory-numa | true | Multiple memory nodes i.e. NUMA architecture detected |
memory-nv.present | true | NVDIMM device(s) are present |
memory-nv.dax | true | NVDIMM region(s) configured in DAX mode are present |
memory-swap.enabled | true | Swap is enabled on the node |
Feature | Value | Description |
---|---|---|
network-sriov.capable | true | Single Root Input/Output Virtualization (SR-IOV) enabled Network Interface Card(s) present |
network-sriov.configured | true | SR-IOV virtual functions have been configured |
Feature | Value | Description |
---|---|---|
pci-<device label>.present | true | PCI device is detected |
pci-<device label>.sriov.capable | true | Single Root Input/Output Virtualization (SR-IOV) enabled PCI device present |
<device label>
is format is configurable and set to <class>_<vendor>
by default. For more more details about configuration of the pci labels, see sources.pci
options and worker configuration instructions.
Feature | Value | Description |
---|---|---|
usb-<device label>.present | true | USB device is detected |
<device label>
is format is configurable and set to <class>_<vendor>_<device>
by default. For more more details about configuration of the usb labels, see sources.usb
options and worker configuration instructions.
Feature | Value | Description |
---|---|---|
storage-nonrotationaldisk | true | Non-rotational disk, like SSD, is present in the node |
Feature | Value | Description |
---|---|---|
system-os_release.ID | string | Operating system identifier |
system-os_release.VERSION_ID | string | Operating system version identifier (e.g. ‘6.7') |
system-os_release.VERSION_ID.major | string | First component of the OS version id (e.g. ‘6') |
system-os_release.VERSION_ID.minor | string | Second component of the OS version id (e.g. ‘7') |
The custom label source is designed for creating user defined labels. However, it has a few statically defined built-in labels:
Feature | Value | Description |
---|---|---|
custom-rdma.capable | true | The node has an RDMA capable Network adapter |
custom-rdma.enabled | true | The node has the needed RDMA modules loaded to run RDMA traffic |
NFD has many extension points for creating vendor and application specific labels. See the customization guide for detailed documentation.
NFD is able to create extended resources, see the NodeFeatureRule CRD and its extendedResources field for more details.
Note that NFD is not a replacement for the usage of device plugins.
An example use-case for extended resources could be based on custom feature (created e.g. with feature files that exposes the node SGX EPC memory section size. This value will then be turned into an extended resource of the node, allowing PODs to request that resource and the Kubernetes scheduler to schedule such PODs to only those nodes which have a sufficient capacity of said resource left.