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import ietf-inet-types {
prefix inet;
}
import ietf-yang-types {
prefix yang;
}
description
"Models for VNFD according to GS NFV-IFA 011.";
revision 2019-10-01 {
description
"Version 2.7.1.
Common data structures to support VNFD and NSD according to:
ETSI GS NFV-IFA 014 Ed271v264
ETSI GS NFV-IFA 011 Ed271v264";
}
description
"Initial revision.
Common data structure to support VNFD according to:
VNFD according to ETSI GS NFV-IFA 011 Ed261v254";
"ETSI GS NFV-IFA 011 Ed261v254";
}
grouping virtual-network-interface-requirements {
list virtual-network-interface-requirement {
key "name";
description
"Specifies requirements on a virtual network interface
realising the CPs instantiated from this CPD.";
reference
"GS NFV-IFA011: Section 7.1.6.4, VduCpd information
element";
leaf name {
type string;
description
"Provides a human readable name for the requirement.";
reference
"GS NFV-IFA011: Section 7.1.6.6,
VirtualNetworkInterfaceRequirements information element";
}
leaf description {
type string;
description
"Provides a human readable description of the requirement.";
reference
"GS NFV-IFA011: Section 7.1.6.6,
VirtualNetworkInterfaceRequirements information element";
}
type boolean;
description
"Indicates whether fulfilling the constraint is
mandatory (true) for successful operation or desirable
(false).";
reference
"GS NFV-IFA011: Section 7.1.6.6,
VirtualNetworkInterfaceRequirements information element";
}
list network-interface-requirements {
key "key";
leaf key {
type string;
}
leaf value {
type string;
}
description
"The network interface requirements. An element from an
array of key-value pairs that articulate the network
interface deployment requirements.";
reference
"GS NFV-IFA011: Section 7.1.6.6,
VirtualNetworkInterfaceRequirements information element";
}
leaf nic-io-requirements {
type leafref {
path "/nfv:nfv/nfv:vnfd/nfv:virtual-compute-desc/" +
"nfv:logical-node/nfv:id";
}
description
"This references (couples) the CPD with any logical node
I/O requirements (for network devices) that may have been
created. Linking these attributes is necessary so that I/O
requirements that need to be articulated at the logical
node level can be associated with the network interface
requirements associated with the CPD.";
reference
"GS NFV-IFA011: Section 7.1.6.6,
VirtualNetworkInterfaceRequirements information element";
}
}
}
grouping vnfd {
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leaf id {
type string;
description
"Identifier of this VNFD information element. This attribute
shall be globally unique. The format will be defined in the
data model specification phase.";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
leaf provider {
type string;
mandatory true;
description
"Provider of the VNF and of the VNFD";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
leaf product-name {
type string;
mandatory true;
description
"Name to identify the VNF Product. Invariant for the VNF
Product lifetime.";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
leaf software-version {
type string;
mandatory true;
description
"Software version of the VNF. This is changed when there is
any change to the software that is included in the VNF
Package";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
leaf version {
type string;
mandatory true;
description
"Identifies the version of the VNFD";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
leaf product-info-name {
type string;
description
"Human readable name of the VNFD. Can change
during the VNF Product lifetime.";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
leaf product-info-description {
type string;
description
"Human readable description of the VNFD. Can change during
the VNF Product lifetime.";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
leaf-list vnfm-info {
type string;
min-elements 1;
description
"Identifies VNFM(s) compatible with the VNF described in
this version of the VNFD.";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
leaf localization-language {
type string;
"Information about the language of the VNF.";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
leaf default-localization-language {
when "../localization-language";
type string;
description
"Default localization language that is instantiated if no
information about selected localization language is
available. Shall be present if 'localization-language'
is present and shall be absent otherwise.";
reference
"GS NFV-IFA011: Section 7.1.2, VNFD information element";
}
list vdu {
key "id";
min-elements 1;
description
"The Virtualisation Deployment Unit (VDU) is a construct supporting
the description of the deployment and operational behaviour of a
VNF component, or the entire VNF if it was not componentized in
components.";
reference
"GS NFV IFA011: Section 7.1.2, VNFD information element";
leaf id {
type string;
description
"Unique identifier of this VDU in VNFD.";
"GS NFV IFA011: Section 7.1.6.2, Vdu information element";
type string;
mandatory true;
description
"GS NFV IFA011: Section 7.1.6.2, Vdu information element";
"Human readable description of the VDU.";
"GS NFV IFA011: Section 7.1.6.2, Vdu information element";
list int-cpd {
key "id";
min-elements 1;
"A internal-connection-point element is a type of
connection point and describes network connectivity
between a VDU instance and an internal Virtual Link or
an external connection point.";
"GS NFV IFA011: Section 7.1.6.2, Vdu information element";
leaf int-virtual-link-desc {
type leafref {
path "/nfv:nfv/nfv:vnfd/nfv:int-virtual-link-desc/nfv:id";
}
description
"Reference of the internal VLD which this internal CPD
connects to.";
reference
"GS NFV IFA011: Section 7.1.6.4, VduCpd information
element";
}
leaf bitrate-requirement {
type uint64;
units "Mbps";
description
"Bitrate requirement on this CP.";
reference
"GS NFV IFA011: Section 7.1.6.4, VduCpd information
element.";
}
uses virtual-network-interface-requirements;
leaf nicio-requirements {
type leafref {
path "/nfv:nfv/nfv:vnfd/nfv:virtual-compute-desc/nfv:id";
}
description
"This references (couples) the CPD with any logical node I/O
requirements (for network devices) that may have been
created. Linking these attributes is necessary so that so
that I/O requirements that need to be articulated at the
logical node level can be associated with the network
interface requirements associated with the CPD.";
reference
"GS NFV-IFA011: Section 7.1.6.6,
VirtualNetworkInterfaceRequirements information element";
}
type uint32;
description
"The order of the NIC to be assigned on the compute
instance (e.g. 2 for eth2).
Note: when binding more than one port to a single
compute (aka multi vNICs) and ordering is desired, it
is mandatory that all ports will be set with an order
value. The order values shall represent a positive,
arithmetic progression that starts with 0 (i.e. 0, 1,
2,..., n).
If the property is not present, it shall be left to the
VIM to assign a value when creating the instance.";
reference
"GS NFV IFA011: Section 7.1.6.4, VduCpd information
element.";
}
leaf vnic-type {
type identityref {
base vnic-type;
}
description
"Describes the type of the virtual network interface
realizing the CPs instantiated from this CPD. This is
used to determine which mechanism driver(s) to be used
to bind the port. Value:
• NORMAL
• VIRTIO
• DIRECT
• BAREMETAL
• VIRTIO-FORWARDER
• DIRECT-PHYSICAL
• SMART-NIC";
reference
"GS NFV IFA011: Section 7.1.6.4, VduCpd information
element.";
}
uses cpd;
leaf security-group-rule-id {
type leafref {
path "../../../security-group-rule/id";
}
description
"Reference of the security group rules bound to this
CPD.";
reference
"GS NFV IFA011: Section 7.1.6.3 Cpd information element";
}
leaf virtual-compute-desc {
type leafref {
path "../../virtual-compute-desc/id";
}
must "../../virtual-compute-desc[id=current()]/" +
"virtual-memory/size >=" +
"../../sw-image-desc[id=current()/" +
"../sw-image-desc]/min-ram" {
}
"Describes CPU, Memory and acceleration requirements of
the Virtualisation Container realizing this VDU.";
"GS NFV IFA011: Section 7.1.6.2, VDU information
element, and Section 7.1.9.2.2, VirtualComputeDesc
information element.";
leaf-list virtual-storage-desc {
type leafref {
path "../../virtual-storage-desc/id";
}
"Describes storage requirements for a VirtualStorage
instance attached to the virtualisation container
created from virtualComputeDesc defined for this VDU.";
"GS NFV IFA011: Section 7.1.6.2, VDU information
element, and Section 7.1.9.4, Information elements
related to Virtual Storage.";
list boot-order {
ordered-by user;
key "key";
leaf key {
type uint32;
}
leaf value {
type leafref {
path "../../virtual-storage-desc";
}
}
"The key indicates the boot index (lowest index defines
highest boot priority). The Value references a descriptor
from which a valid boot device is created e.g.
VirtualStorageDesc from which a VirtualStorage instance
is created.
Editor's note: The boot-order node requires further
study.";
"GS NFV IFA011: Section 7.1.6.2, Vdu information
element.";
leaf sw-image-desc {
type leafref {
path "../../sw-image-desc/id";
}
"Describes the software image which is directly loaded on
the virtualisation container realising this Vdu.";
"GS NFV IFA011: Section 7.1.6.2, Vdu information
element.";
"Describes constraints on the NFVI for the VNFC
instance(s) created from this Vdu. For example, aspects
of a secure hosting environment for the VNFC instance
that involve additional entities or processes.";
"GS NFV IFA011: Section 7.1.6.2, VDU Information
element.";
key "id";
leaf id {
type string;
description
"Unique identifier of the monitoring parameter.";
"GS NFV IFA011: Section 7.1.11.3, MonitoringParameter
information element.";
uses monitoring-parameter;
}
list configurable-properties {
key "key";
leaf key {
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description
"It provides VNFC configurable properties that can be
modified using the ModifyVnfInfo operation.";
reference
"GS NFV IFA011: Section 7.1.6.7,
VnfcConfigurableProperties Information element.";
}
leaf boot-data {
type string;
description
"Contains a string or a URL to a file contained in the
VNF package used to customize a virtualised compute
resource at boot time. The bootData may contain variable
parts that are replaced by deployment specific values
before being sent to the VIM.";
reference
"GS NFV IFA011: Section 7.1.6.7,
VnfcConfigurableProperties Information element.";
}
}
list virtual-compute-desc {
key "id";
description
"Defines descriptors of virtual compute resources to be
used by the VNF.";
leaf id {
type string;
description
"Unique identifier of this VirtualComputeDesc in the
VNFD.";
reference
"GS NFV IFA011: Section 7.1.9.2, Information elements
related to Virtual CPU.";
}
list logical-node {
key "id";
leaf id {
type string;
"Identifies this set of logical node requirements.";
"GS NFV IFA011: Section 7.1.9.6, LogicalNodeRequirements
Information elements.";
}
list requirement-detail {
key "key";
"The logical node-level compute, memory and I/O
requirements. An array of key-value pairs that
articulate the deployment requirements.
This could include the number of CPU cores on this
logical node, a memory configuration specific to a
logical node (e.g. such as available in the Linux
kernel via the libnuma library) or a requirement
related to the association of an I/O device with the
logical node.";
"GS NFV IFA011: Section 7.1.9.6, LogicalNodeRequirements
description
"The logical node requirements.";
reference
"GS NFV IFA011: Section 7.1.9.2, VirtualComputeDesc
information element.";
}
list request-additional-capability {
key "name";
leaf name {
type string;
"Identifies a requested additional capability for the
VDU. ETSI GS NFV-IFA 002 [i.1] describes acceleration
capabilities.";
"GS NFV IFA011: Section 7.1.9.5,
RequestedAdditionalCapabilityData Information element.";
leaf support-mandatory {
type boolean;
description
"Indicates whether the requested additional capability
is mandatory for successful operation.";
"GS NFV IFA011: Section 7.1.9.5,
RequestedAdditionalCapabilityData Information
leaf min-version {
type string;
"Identifies the minimum version of the requested
additional capability.";
"GS NFV IFA011: Section 7.1.9.5,
RequestedAdditionalCapabilityData Information element.";
"Identifies the preferred version of the requested
additional capability.";
"GS NFV IFA011: Section 7.1.9.5,
RequestedAdditionalCapabilityData Information element.";
list target-performance-parameters {
leaf key {
type string;
}
leaf value {
type string;
}
"Identifies specific attributes, dependent on the
requested additional capability type.";
"GS NFV IFA011: Section 7.1.9.5,
RequestedAdditionalCapabilityData Information element.";
leaf compute-requirements {
type string;
"Specifies compute requirements.";
reference
"GS NFV IFA011: Section 7.1.9.2.2, VirtualComputeDesc
Information element.";
}
container virtual-memory {
leaf size {
type decimal64 {
fraction-digits 1;
range "0..max";
units "GB";
default 1;
description
"Amount of virtual memory in GB.";
reference
"GS NFV IFA011: Section 7.1.9.3, Information elements
related to Virtual Memory.";
}
leaf over-subscription-policy {
type string;
"The memory core oversubscription policy in terms of
virtual memory to physical memory on the platform.
The cardinality can be 0 during the allocation
request, if no particular value is requested.";
"GS NFV IFA011: Section 7.1.9.3, Information elements
related to Virtual Memory.";
list vdu-mem-requirements {
key "key";
description
"Array of key-value pair requirements on the memory for
the VDU.";
reference
"GS NFV IFA011: Section 7.1.9.3.2, VirtualMemoryData
information element.";
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leaf numa-enabled {
type boolean;
description
"It specifies the memory allocation to be cognisant of
the relevant process/core allocation. The cardinality
can be 0 during the allocation request, if no
particular value is requested.";
reference
"GS NFV IFA011: Section 7.1.9.3, Information elements
related to Virtual Memory.";
}
description
"The virtual memory of the virtualised compute.";
reference
"GS NFV IFA011: Section 7.1.9.2.2, VirtualComputeDesc
Information element.";
}
container virtual-cpu {
description
"The virtual CPU(s)of the virtualised compute.";
reference
"GS NFV IFA011: Section 7.1.9.2.2, VirtualComputeDesc
Information element.";
leaf cpu-architecture {
"CPU architecture type. Examples are x86, ARM. The
cardinality can be 0 during the allocation request,
if no particular CPU architecture type is requested.";
"GS NFV IFA011: Section 7.1.9.2.3, VirtualCpuData
information elements.";
leaf num-virtual-cpu {
type uint16 {
range "1..max";
default 1;
description
"Number of virtual CPUs.";
reference
"GS NFV IFA011: Section 7.1.9.2.3, VirtualCpuData
information elements.";
}
leaf clock {
type uint32;
units "MHz";
"Minimum virtual CPU clock rate (e.g. in MHz). The
cardinality can be 0 during the allocation request,
if no particular value is requested.";
"GS NFV IFA011: Section 7.1.9.2.3, VirtualCpuData
information elements.";
leaf oversubscription-policy {
type string;
"The CPU core oversubscription policy e.g. the relation
of virtual CPU cores to physical CPU cores/threads.
The cardinality can be 0 during the allocation request,
if no particular value is requested.";
"GS NFV IFA011: Section 7.1.9.2.3, VirtualCpuData
information elements.";
}
list vdu-cpu-requirements {
key "key";
}
description
"Array of key-value pair requirements on the compute
(CPU) for the VDU.";
reference
"GS NFV IFA011: Section 7.1.9.3.2, VirtualCpuData
information element.";
}
container pinning {
presence "Set to specify CPU pinning.";
leaf policy {
default "dynamic";
type enumeration {
enum "static";
enum "dynamic";
}
"The policy can take values of 'static' or 'dynamic'.
In case of 'static' the virtual CPU cores are
requested to be allocated to logical CPU cores
according to the rules defined in
virtualCpuPinningRules. In case of 'dynamic' the
allocation of virtual CPU cores to logical CPU cores
is decided by the VIM. (e.g. SMT (Simultaneous
MultiThreading) requirements).";
"GS NFV IFA011: Section 7.1.9.2.4,
VirtualCpuPinningData information element.";
list rule {
when "../policy = 'static'";
leaf key {
type string;
}
leaf value {
type string;
}
description
"A list of rules that should be considered during the
allocation of the virtual CPUs to logical CPUs in case
of 'static' virtualCpuPinningPolicy.";
"GS NFV IFA011: Section 7.1.9.2.4,
VirtualCpuPinningData information element.";
description
"The virtual CPU pinning configuration for the
virtualised compute resource.";
reference
"GS NFV IFA011: Section 7.1.9.2.3,
VirtualCpuData information element.";
}
}
}
list virtual-storage-desc {
key "id";
description
"Storage requirements for a Virtual Storage instance
attached to the VNFC created from this VDU";
leaf id {
type string;
description
"Unique identifier of this VirtualStorageDesc in the
VNFD.";
reference
"GS NFV IFA011: Section 7.1.9.4, Information elements
related to Virtual Storage.";
}
leaf type-of-storage {
// Needed to be able to onboard images
default root-storage;
type identityref {
base storage-type;
description
"Type of virtualised storage resource (e.g. volume,
object).";
reference
"GS NFV IFA011: Section 7.1.9.4, Information elements
related to Virtual Storage.";
leaf size-of-storage {
type uint64;
units "GB";
default 0;
"Size of virtualised storage resource (e.g. size of
volume, in GB)";
reference
"GS NFV IFA011: Section 7.1.9.4, Information elements
related to Virtual Storage.";
}
list vdu-storage-requirements {
key "key";
leaf key {
description
"Array of key-value pairs that articulate the storage
deployment requirements.";
reference
"GS NFV IFA011: Section 7.1.9.4.2, VirtualStorageDesc
information element.";
}
leaf rdma-enabled {
type boolean;
description
"Indicate if the storage support RDMA.";
reference
"GS NFV IFA011: Section 7.1.9.4, Information elements
related to Virtual Storage.";
}
leaf sw-image-desc {
type leafref {
path "../../sw-image-desc/id";
must "../size-of-storage >=" +
"../../sw-image-desc[id=current()]/min-disk" {
description
"Software image to be loaded on the VirtualStorage
resource created based on this VirtualStorageDesc.";
reference
"GS NFV IFA011: Section 7.1.9.4, Information elements
related to Virtual Storage.";
list sw-image-desc {
key "id";
description
"Defines descriptors of software images to be used by the
VNF.";
reference
"GS NFV IFA011: Section 7.1.2, VNFD Information element.";
leaf id {
type string;
"The identifier of this software image.";
"GS NFV IFA011: Section 7.1.6.5, SwImageDesc information
element";
}
leaf name {
mandatory true;
type string;
description
"The name of this software image.";
reference
"GS NFV IFA011: Section 7.1.6.5 SwImageDesc
information element.";
}
leaf version {
mandatory true;
type string;
description
"The version of this software image.";
reference
"GS NFV IFA011: Section 7.1.6.5 SwImageDesc
information element.";
}
leaf provider {
type string;
description
"The provider of this software image. If not present the
provider of the software image is assumed to be same as
the VNF provider.";
reference
"GS NFV IFA011: Section 7.1.6.5 SwImageDesc
information element.";
}
container checksum {
leaf algorithm {
type identityref {
base checksum-algorithm;
}
"Species the algorithm used to obtain the checksum
value.";
"GS NFV IFA011: Section 7.1.6.10 ChecksumData
"Contains the result of applying the algorithm
indicated by the algorithm attribute to the data to
which this ChecksumData refers.";
"GS NFV IFA011: Section 7.1.6.10 ChecksumData
description
"The checksum of the software image file.";
reference
"GS NFV IFA011: Section 7.1.6.5 SwImageDesc
information element.";
}
leaf container-format {
default "bare";
type enumeration {
enum "aki" {
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"An Amazon kernel image.";
}
enum "ami" {
description
"An Amazon machine image.";
}
enum "ari" {
description
"An Amazon ramdisk image.";
}
enum "bare" {
description
"The image does not have a container or metadata
envelope.";
}
enum "docker" {
description
"A docker container format.";
}
enum "ova" {
description
"An OVF package in a tarfile.";
}
enum "ovf" {
description
"The OVF container format.";
description
"The container format describes the container file
format in which software image is provided.";