ceph-csi/vendor/k8s.io/api/resource/v1alpha3/generated.proto

/*
Copyright The Kubernetes Authors.

Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at

    http://www.apache.org/licenses/LICENSE-2.0

Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/


// This file was autogenerated by go-to-protobuf. Do not edit it manually!

syntax = "proto2";

package k8s.io.api.resource.v1alpha3;

import "k8s.io/api/core/v1/generated.proto";
import "k8s.io/apimachinery/pkg/api/resource/generated.proto";
import "k8s.io/apimachinery/pkg/apis/meta/v1/generated.proto";
import "k8s.io/apimachinery/pkg/runtime/generated.proto";
import "k8s.io/apimachinery/pkg/runtime/schema/generated.proto";

// Package-wide variables from generator "generated".
option go_package = "k8s.io/api/resource/v1alpha3";

// AllocationResult contains attributes of an allocated resource.
message AllocationResult {
  // Devices is the result of allocating devices.
  //
  // +optional
  optional DeviceAllocationResult devices = 1;

  // NodeSelector defines where the allocated resources are available. If
  // unset, they are available everywhere.
  //
  // +optional
  optional .k8s.io.api.core.v1.NodeSelector nodeSelector = 3;

  // Controller is the name of the DRA driver which handled the
  // allocation. That driver is also responsible for deallocating the
  // claim. It is empty when the claim can be deallocated without
  // involving a driver.
  //
  // A driver may allocate devices provided by other drivers, so this
  // driver name here can be different from the driver names listed for
  // the results.
  //
  // This is an alpha field and requires enabling the DRAControlPlaneController
  // feature gate.
  //
  // +optional
  // +featureGate=DRAControlPlaneController
  optional string controller = 4;
}

// BasicDevice defines one device instance.
message BasicDevice {
  // Attributes defines the set of attributes for this device.
  // The name of each attribute must be unique in that set.
  //
  // The maximum number of attributes and capacities combined is 32.
  //
  // +optional
  map<string, DeviceAttribute> attributes = 1;

  // Capacity defines the set of capacities for this device.
  // The name of each capacity must be unique in that set.
  //
  // The maximum number of attributes and capacities combined is 32.
  //
  // +optional
  map<string, .k8s.io.apimachinery.pkg.api.resource.Quantity> capacity = 2;
}

// CELDeviceSelector contains a CEL expression for selecting a device.
message CELDeviceSelector {
  // Expression is a CEL expression which evaluates a single device. It
  // must evaluate to true when the device under consideration satisfies
  // the desired criteria, and false when it does not. Any other result
  // is an error and causes allocation of devices to abort.
  //
  // The expression's input is an object named "device", which carries
  // the following properties:
  //  - driver (string): the name of the driver which defines this device.
  //  - attributes (map[string]object): the device's attributes, grouped by prefix
  //    (e.g. device.attributes["dra.example.com"] evaluates to an object with all
  //    of the attributes which were prefixed by "dra.example.com".
  //  - capacity (map[string]object): the device's capacities, grouped by prefix.
  //
  // Example: Consider a device with driver="dra.example.com", which exposes
  // two attributes named "model" and "ext.example.com/family" and which
  // exposes one capacity named "modules". This input to this expression
  // would have the following fields:
  //
  //     device.driver
  //     device.attributes["dra.example.com"].model
  //     device.attributes["ext.example.com"].family
  //     device.capacity["dra.example.com"].modules
  //
  // The device.driver field can be used to check for a specific driver,
  // either as a high-level precondition (i.e. you only want to consider
  // devices from this driver) or as part of a multi-clause expression
  // that is meant to consider devices from different drivers.
  //
  // The value type of each attribute is defined by the device
  // definition, and users who write these expressions must consult the
  // documentation for their specific drivers. The value type of each
  // capacity is Quantity.
  //
  // If an unknown prefix is used as a lookup in either device.attributes
  // or device.capacity, an empty map will be returned. Any reference to
  // an unknown field will cause an evaluation error and allocation to
  // abort.
  //
  // A robust expression should check for the existence of attributes
  // before referencing them.
  //
  // For ease of use, the cel.bind() function is enabled, and can be used
  // to simplify expressions that access multiple attributes with the
  // same domain. For example:
  //
  //     cel.bind(dra, device.attributes["dra.example.com"], dra.someBool && dra.anotherBool)
  //
  // +required
  optional string expression = 1;
}

// Device represents one individual hardware instance that can be selected based
// on its attributes. Besides the name, exactly one field must be set.
message Device {
  // Name is unique identifier among all devices managed by
  // the driver in the pool. It must be a DNS label.
  //
  // +required
  optional string name = 1;

  // Basic defines one device instance.
  //
  // +optional
  // +oneOf=deviceType
  optional BasicDevice basic = 2;
}

// DeviceAllocationConfiguration gets embedded in an AllocationResult.
message DeviceAllocationConfiguration {
  // Source records whether the configuration comes from a class and thus
  // is not something that a normal user would have been able to set
  // or from a claim.
  //
  // +required
  optional string source = 1;

  // Requests lists the names of requests where the configuration applies.
  // If empty, its applies to all requests.
  //
  // +optional
  // +listType=atomic
  repeated string requests = 2;

  optional DeviceConfiguration deviceConfiguration = 3;
}

// DeviceAllocationResult is the result of allocating devices.
message DeviceAllocationResult {
  // Results lists all allocated devices.
  //
  // +optional
  // +listType=atomic
  repeated DeviceRequestAllocationResult results = 1;

  // This field is a combination of all the claim and class configuration parameters.
  // Drivers can distinguish between those based on a flag.
  //
  // This includes configuration parameters for drivers which have no allocated
  // devices in the result because it is up to the drivers which configuration
  // parameters they support. They can silently ignore unknown configuration
  // parameters.
  //
  // +optional
  // +listType=atomic
  repeated DeviceAllocationConfiguration config = 2;
}

// DeviceAttribute must have exactly one field set.
message DeviceAttribute {
  // IntValue is a number.
  //
  // +optional
  // +oneOf=ValueType
  optional int64 int = 2;

  // BoolValue is a true/false value.
  //
  // +optional
  // +oneOf=ValueType
  optional bool bool = 3;

  // StringValue is a string. Must not be longer than 64 characters.
  //
  // +optional
  // +oneOf=ValueType
  optional string string = 4;

  // VersionValue is a semantic version according to semver.org spec 2.0.0.
  // Must not be longer than 64 characters.
  //
  // +optional
  // +oneOf=ValueType
  optional string version = 5;
}

// DeviceClaim defines how to request devices with a ResourceClaim.
message DeviceClaim {
  // Requests represent individual requests for distinct devices which
  // must all be satisfied. If empty, nothing needs to be allocated.
  //
  // +optional
  // +listType=atomic
  repeated DeviceRequest requests = 1;

  // These constraints must be satisfied by the set of devices that get
  // allocated for the claim.
  //
  // +optional
  // +listType=atomic
  repeated DeviceConstraint constraints = 2;

  // This field holds configuration for multiple potential drivers which
  // could satisfy requests in this claim. It is ignored while allocating
  // the claim.
  //
  // +optional
  // +listType=atomic
  repeated DeviceClaimConfiguration config = 3;
}

// DeviceClaimConfiguration is used for configuration parameters in DeviceClaim.
message DeviceClaimConfiguration {
  // Requests lists the names of requests where the configuration applies.
  // If empty, it applies to all requests.
  //
  // +optional
  // +listType=atomic
  repeated string requests = 1;

  optional DeviceConfiguration deviceConfiguration = 2;
}

// DeviceClass is a vendor- or admin-provided resource that contains
// device configuration and selectors. It can be referenced in
// the device requests of a claim to apply these presets.
// Cluster scoped.
//
// This is an alpha type and requires enabling the DynamicResourceAllocation
// feature gate.
message DeviceClass {
  // Standard object metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ObjectMeta metadata = 1;

  // Spec defines what can be allocated and how to configure it.
  //
  // This is mutable. Consumers have to be prepared for classes changing
  // at any time, either because they get updated or replaced. Claim
  // allocations are done once based on whatever was set in classes at
  // the time of allocation.
  //
  // Changing the spec automatically increments the metadata.generation number.
  optional DeviceClassSpec spec = 2;
}

// DeviceClassConfiguration is used in DeviceClass.
message DeviceClassConfiguration {
  optional DeviceConfiguration deviceConfiguration = 1;
}

// DeviceClassList is a collection of classes.
message DeviceClassList {
  // Standard list metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ListMeta metadata = 1;

  // Items is the list of resource classes.
  repeated DeviceClass items = 2;
}

// DeviceClassSpec is used in a [DeviceClass] to define what can be allocated
// and how to configure it.
message DeviceClassSpec {
  // Each selector must be satisfied by a device which is claimed via this class.
  //
  // +optional
  // +listType=atomic
  repeated DeviceSelector selectors = 1;

  // Config defines configuration parameters that apply to each device that is claimed via this class.
  // Some classses may potentially be satisfied by multiple drivers, so each instance of a vendor
  // configuration applies to exactly one driver.
  //
  // They are passed to the driver, but are not considered while allocating the claim.
  //
  // +optional
  // +listType=atomic
  repeated DeviceClassConfiguration config = 2;

  // Only nodes matching the selector will be considered by the scheduler
  // when trying to find a Node that fits a Pod when that Pod uses
  // a claim that has not been allocated yet *and* that claim
  // gets allocated through a control plane controller. It is ignored
  // when the claim does not use a control plane controller
  // for allocation.
  //
  // Setting this field is optional. If unset, all Nodes are candidates.
  //
  // This is an alpha field and requires enabling the DRAControlPlaneController
  // feature gate.
  //
  // +optional
  // +featureGate=DRAControlPlaneController
  optional .k8s.io.api.core.v1.NodeSelector suitableNodes = 3;
}

// DeviceConfiguration must have exactly one field set. It gets embedded
// inline in some other structs which have other fields, so field names must
// not conflict with those.
message DeviceConfiguration {
  // Opaque provides driver-specific configuration parameters.
  //
  // +optional
  // +oneOf=ConfigurationType
  optional OpaqueDeviceConfiguration opaque = 1;
}

// DeviceConstraint must have exactly one field set besides Requests.
message DeviceConstraint {
  // Requests is a list of the one or more requests in this claim which
  // must co-satisfy this constraint. If a request is fulfilled by
  // multiple devices, then all of the devices must satisfy the
  // constraint. If this is not specified, this constraint applies to all
  // requests in this claim.
  //
  // +optional
  // +listType=atomic
  repeated string requests = 1;

  // MatchAttribute requires that all devices in question have this
  // attribute and that its type and value are the same across those
  // devices.
  //
  // For example, if you specified "dra.example.com/numa" (a hypothetical example!),
  // then only devices in the same NUMA node will be chosen. A device which
  // does not have that attribute will not be chosen. All devices should
  // use a value of the same type for this attribute because that is part of
  // its specification, but if one device doesn't, then it also will not be
  // chosen.
  //
  // Must include the domain qualifier.
  //
  // +optional
  // +oneOf=ConstraintType
  optional string matchAttribute = 2;
}

// DeviceRequest is a request for devices required for a claim.
// This is typically a request for a single resource like a device, but can
// also ask for several identical devices.
//
// A DeviceClassName is currently required. Clients must check that it is
// indeed set. It's absence indicates that something changed in a way that
// is not supported by the client yet, in which case it must refuse to
// handle the request.
message DeviceRequest {
  // Name can be used to reference this request in a pod.spec.containers[].resources.claims
  // entry and in a constraint of the claim.
  //
  // Must be a DNS label.
  //
  // +required
  optional string name = 1;

  // DeviceClassName references a specific DeviceClass, which can define
  // additional configuration and selectors to be inherited by this
  // request.
  //
  // A class is required. Which classes are available depends on the cluster.
  //
  // Administrators may use this to restrict which devices may get
  // requested by only installing classes with selectors for permitted
  // devices. If users are free to request anything without restrictions,
  // then administrators can create an empty DeviceClass for users
  // to reference.
  //
  // +required
  optional string deviceClassName = 2;

  // Selectors define criteria which must be satisfied by a specific
  // device in order for that device to be considered for this
  // request. All selectors must be satisfied for a device to be
  // considered.
  //
  // +optional
  // +listType=atomic
  repeated DeviceSelector selectors = 3;

  // AllocationMode and its related fields define how devices are allocated
  // to satisfy this request. Supported values are:
  //
  // - ExactCount: This request is for a specific number of devices.
  //   This is the default. The exact number is provided in the
  //   count field.
  //
  // - All: This request is for all of the matching devices in a pool.
  //   Allocation will fail if some devices are already allocated,
  //   unless adminAccess is requested.
  //
  // If AlloctionMode is not specified, the default mode is ExactCount. If
  // the mode is ExactCount and count is not specified, the default count is
  // one. Any other requests must specify this field.
  //
  // More modes may get added in the future. Clients must refuse to handle
  // requests with unknown modes.
  //
  // +optional
  optional string allocationMode = 4;

  // Count is used only when the count mode is "ExactCount". Must be greater than zero.
  // If AllocationMode is ExactCount and this field is not specified, the default is one.
  //
  // +optional
  // +oneOf=AllocationMode
  optional int64 count = 5;

  // AdminAccess indicates that this is a claim for administrative access
  // to the device(s). Claims with AdminAccess are expected to be used for
  // monitoring or other management services for a device.  They ignore
  // all ordinary claims to the device with respect to access modes and
  // any resource allocations.
  //
  // +optional
  // +default=false
  optional bool adminAccess = 6;
}

// DeviceRequestAllocationResult contains the allocation result for one request.
message DeviceRequestAllocationResult {
  // Request is the name of the request in the claim which caused this
  // device to be allocated. Multiple devices may have been allocated
  // per request.
  //
  // +required
  optional string request = 1;

  // Driver specifies the name of the DRA driver whose kubelet
  // plugin should be invoked to process the allocation once the claim is
  // needed on a node.
  //
  // Must be a DNS subdomain and should end with a DNS domain owned by the
  // vendor of the driver.
  //
  // +required
  optional string driver = 2;

  // This name together with the driver name and the device name field
  // identify which device was allocated (`<driver name>/<pool name>/<device name>`).
  //
  // Must not be longer than 253 characters and may contain one or more
  // DNS sub-domains separated by slashes.
  //
  // +required
  optional string pool = 3;

  // Device references one device instance via its name in the driver's
  // resource pool. It must be a DNS label.
  //
  // +required
  optional string device = 4;
}

// DeviceSelector must have exactly one field set.
message DeviceSelector {
  // CEL contains a CEL expression for selecting a device.
  //
  // +optional
  // +oneOf=SelectorType
  optional CELDeviceSelector cel = 1;
}

// OpaqueDeviceConfiguration contains configuration parameters for a driver
// in a format defined by the driver vendor.
message OpaqueDeviceConfiguration {
  // Driver is used to determine which kubelet plugin needs
  // to be passed these configuration parameters.
  //
  // An admission policy provided by the driver developer could use this
  // to decide whether it needs to validate them.
  //
  // Must be a DNS subdomain and should end with a DNS domain owned by the
  // vendor of the driver.
  //
  // +required
  optional string driver = 1;

  // Parameters can contain arbitrary data. It is the responsibility of
  // the driver developer to handle validation and versioning. Typically this
  // includes self-identification and a version ("kind" + "apiVersion" for
  // Kubernetes types), with conversion between different versions.
  //
  // +required
  optional .k8s.io.apimachinery.pkg.runtime.RawExtension parameters = 2;
}

// PodSchedulingContext objects hold information that is needed to schedule
// a Pod with ResourceClaims that use "WaitForFirstConsumer" allocation
// mode.
//
// This is an alpha type and requires enabling the DRAControlPlaneController
// feature gate.
message PodSchedulingContext {
  // Standard object metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ObjectMeta metadata = 1;

  // Spec describes where resources for the Pod are needed.
  optional PodSchedulingContextSpec spec = 2;

  // Status describes where resources for the Pod can be allocated.
  //
  // +optional
  optional PodSchedulingContextStatus status = 3;
}

// PodSchedulingContextList is a collection of Pod scheduling objects.
message PodSchedulingContextList {
  // Standard list metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ListMeta metadata = 1;

  // Items is the list of PodSchedulingContext objects.
  repeated PodSchedulingContext items = 2;
}

// PodSchedulingContextSpec describes where resources for the Pod are needed.
message PodSchedulingContextSpec {
  // SelectedNode is the node for which allocation of ResourceClaims that
  // are referenced by the Pod and that use "WaitForFirstConsumer"
  // allocation is to be attempted.
  //
  // +optional
  optional string selectedNode = 1;

  // PotentialNodes lists nodes where the Pod might be able to run.
  //
  // The size of this field is limited to 128. This is large enough for
  // many clusters. Larger clusters may need more attempts to find a node
  // that suits all pending resources. This may get increased in the
  // future, but not reduced.
  //
  // +optional
  // +listType=atomic
  repeated string potentialNodes = 2;
}

// PodSchedulingContextStatus describes where resources for the Pod can be allocated.
message PodSchedulingContextStatus {
  // ResourceClaims describes resource availability for each
  // pod.spec.resourceClaim entry where the corresponding ResourceClaim
  // uses "WaitForFirstConsumer" allocation mode.
  //
  // +listType=map
  // +listMapKey=name
  // +optional
  repeated ResourceClaimSchedulingStatus resourceClaims = 1;
}

// ResourceClaim describes a request for access to resources in the cluster,
// for use by workloads. For example, if a workload needs an accelerator device
// with specific properties, this is how that request is expressed. The status
// stanza tracks whether this claim has been satisfied and what specific
// resources have been allocated.
//
// This is an alpha type and requires enabling the DynamicResourceAllocation
// feature gate.
message ResourceClaim {
  // Standard object metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ObjectMeta metadata = 1;

  // Spec describes what is being requested and how to configure it.
  // The spec is immutable.
  optional ResourceClaimSpec spec = 2;

  // Status describes whether the claim is ready to use and what has been allocated.
  // +optional
  optional ResourceClaimStatus status = 3;
}

// ResourceClaimConsumerReference contains enough information to let you
// locate the consumer of a ResourceClaim. The user must be a resource in the same
// namespace as the ResourceClaim.
message ResourceClaimConsumerReference {
  // APIGroup is the group for the resource being referenced. It is
  // empty for the core API. This matches the group in the APIVersion
  // that is used when creating the resources.
  // +optional
  optional string apiGroup = 1;

  // Resource is the type of resource being referenced, for example "pods".
  // +required
  optional string resource = 3;

  // Name is the name of resource being referenced.
  // +required
  optional string name = 4;

  // UID identifies exactly one incarnation of the resource.
  // +required
  optional string uid = 5;
}

// ResourceClaimList is a collection of claims.
message ResourceClaimList {
  // Standard list metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ListMeta metadata = 1;

  // Items is the list of resource claims.
  repeated ResourceClaim items = 2;
}

// ResourceClaimSchedulingStatus contains information about one particular
// ResourceClaim with "WaitForFirstConsumer" allocation mode.
message ResourceClaimSchedulingStatus {
  // Name matches the pod.spec.resourceClaims[*].Name field.
  //
  // +required
  optional string name = 1;

  // UnsuitableNodes lists nodes that the ResourceClaim cannot be
  // allocated for.
  //
  // The size of this field is limited to 128, the same as for
  // PodSchedulingSpec.PotentialNodes. This may get increased in the
  // future, but not reduced.
  //
  // +optional
  // +listType=atomic
  repeated string unsuitableNodes = 2;
}

// ResourceClaimSpec defines what is being requested in a ResourceClaim and how to configure it.
message ResourceClaimSpec {
  // Devices defines how to request devices.
  //
  // +optional
  optional DeviceClaim devices = 1;

  // Controller is the name of the DRA driver that is meant
  // to handle allocation of this claim. If empty, allocation is handled
  // by the scheduler while scheduling a pod.
  //
  // Must be a DNS subdomain and should end with a DNS domain owned by the
  // vendor of the driver.
  //
  // This is an alpha field and requires enabling the DRAControlPlaneController
  // feature gate.
  //
  // +optional
  // +featureGate=DRAControlPlaneController
  optional string controller = 2;
}

// ResourceClaimStatus tracks whether the resource has been allocated and what
// the result of that was.
message ResourceClaimStatus {
  // Allocation is set once the claim has been allocated successfully.
  //
  // +optional
  optional AllocationResult allocation = 1;

  // ReservedFor indicates which entities are currently allowed to use
  // the claim. A Pod which references a ResourceClaim which is not
  // reserved for that Pod will not be started. A claim that is in
  // use or might be in use because it has been reserved must not get
  // deallocated.
  //
  // In a cluster with multiple scheduler instances, two pods might get
  // scheduled concurrently by different schedulers. When they reference
  // the same ResourceClaim which already has reached its maximum number
  // of consumers, only one pod can be scheduled.
  //
  // Both schedulers try to add their pod to the claim.status.reservedFor
  // field, but only the update that reaches the API server first gets
  // stored. The other one fails with an error and the scheduler
  // which issued it knows that it must put the pod back into the queue,
  // waiting for the ResourceClaim to become usable again.
  //
  // There can be at most 32 such reservations. This may get increased in
  // the future, but not reduced.
  //
  // +optional
  // +listType=map
  // +listMapKey=uid
  // +patchStrategy=merge
  // +patchMergeKey=uid
  repeated ResourceClaimConsumerReference reservedFor = 2;

  // Indicates that a claim is to be deallocated. While this is set,
  // no new consumers may be added to ReservedFor.
  //
  // This is only used if the claim needs to be deallocated by a DRA driver.
  // That driver then must deallocate this claim and reset the field
  // together with clearing the Allocation field.
  //
  // This is an alpha field and requires enabling the DRAControlPlaneController
  // feature gate.
  //
  // +optional
  // +featureGate=DRAControlPlaneController
  optional bool deallocationRequested = 3;
}

// ResourceClaimTemplate is used to produce ResourceClaim objects.
//
// This is an alpha type and requires enabling the DynamicResourceAllocation
// feature gate.
message ResourceClaimTemplate {
  // Standard object metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ObjectMeta metadata = 1;

  // Describes the ResourceClaim that is to be generated.
  //
  // This field is immutable. A ResourceClaim will get created by the
  // control plane for a Pod when needed and then not get updated
  // anymore.
  optional ResourceClaimTemplateSpec spec = 2;
}

// ResourceClaimTemplateList is a collection of claim templates.
message ResourceClaimTemplateList {
  // Standard list metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ListMeta metadata = 1;

  // Items is the list of resource claim templates.
  repeated ResourceClaimTemplate items = 2;
}

// ResourceClaimTemplateSpec contains the metadata and fields for a ResourceClaim.
message ResourceClaimTemplateSpec {
  // ObjectMeta may contain labels and annotations that will be copied into the PVC
  // when creating it. No other fields are allowed and will be rejected during
  // validation.
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ObjectMeta metadata = 1;

  // Spec for the ResourceClaim. The entire content is copied unchanged
  // into the ResourceClaim that gets created from this template. The
  // same fields as in a ResourceClaim are also valid here.
  optional ResourceClaimSpec spec = 2;
}

// ResourcePool describes the pool that ResourceSlices belong to.
message ResourcePool {
  // Name is used to identify the pool. For node-local devices, this
  // is often the node name, but this is not required.
  //
  // It must not be longer than 253 characters and must consist of one or more DNS sub-domains
  // separated by slashes. This field is immutable.
  //
  // +required
  optional string name = 1;

  // Generation tracks the change in a pool over time. Whenever a driver
  // changes something about one or more of the resources in a pool, it
  // must change the generation in all ResourceSlices which are part of
  // that pool. Consumers of ResourceSlices should only consider
  // resources from the pool with the highest generation number. The
  // generation may be reset by drivers, which should be fine for
  // consumers, assuming that all ResourceSlices in a pool are updated to
  // match or deleted.
  //
  // Combined with ResourceSliceCount, this mechanism enables consumers to
  // detect pools which are comprised of multiple ResourceSlices and are
  // in an incomplete state.
  //
  // +required
  optional int64 generation = 2;

  // ResourceSliceCount is the total number of ResourceSlices in the pool at this
  // generation number. Must be greater than zero.
  //
  // Consumers can use this to check whether they have seen all ResourceSlices
  // belonging to the same pool.
  //
  // +required
  optional int64 resourceSliceCount = 3;
}

// ResourceSlice represents one or more resources in a pool of similar resources,
// managed by a common driver. A pool may span more than one ResourceSlice, and exactly how many
// ResourceSlices comprise a pool is determined by the driver.
//
// At the moment, the only supported resources are devices with attributes and capacities.
// Each device in a given pool, regardless of how many ResourceSlices, must have a unique name.
// The ResourceSlice in which a device gets published may change over time. The unique identifier
// for a device is the tuple <driver name>, <pool name>, <device name>.
//
// Whenever a driver needs to update a pool, it increments the pool.Spec.Pool.Generation number
// and updates all ResourceSlices with that new number and new resource definitions. A consumer
// must only use ResourceSlices with the highest generation number and ignore all others.
//
// When allocating all resources in a pool matching certain criteria or when
// looking for the best solution among several different alternatives, a
// consumer should check the number of ResourceSlices in a pool (included in
// each ResourceSlice) to determine whether its view of a pool is complete and
// if not, should wait until the driver has completed updating the pool.
//
// For resources that are not local to a node, the node name is not set. Instead,
// the driver may use a node selector to specify where the devices are available.
//
// This is an alpha type and requires enabling the DynamicResourceAllocation
// feature gate.
message ResourceSlice {
  // Standard object metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ObjectMeta metadata = 1;

  // Contains the information published by the driver.
  //
  // Changing the spec automatically increments the metadata.generation number.
  optional ResourceSliceSpec spec = 2;
}

// ResourceSliceList is a collection of ResourceSlices.
message ResourceSliceList {
  // Standard list metadata
  // +optional
  optional .k8s.io.apimachinery.pkg.apis.meta.v1.ListMeta listMeta = 1;

  // Items is the list of resource ResourceSlices.
  repeated ResourceSlice items = 2;
}

// ResourceSliceSpec contains the information published by the driver in one ResourceSlice.
message ResourceSliceSpec {
  // Driver identifies the DRA driver providing the capacity information.
  // A field selector can be used to list only ResourceSlice
  // objects with a certain driver name.
  //
  // Must be a DNS subdomain and should end with a DNS domain owned by the
  // vendor of the driver. This field is immutable.
  //
  // +required
  optional string driver = 1;

  // Pool describes the pool that this ResourceSlice belongs to.
  //
  // +required
  optional ResourcePool pool = 2;

  // NodeName identifies the node which provides the resources in this pool.
  // A field selector can be used to list only ResourceSlice
  // objects belonging to a certain node.
  //
  // This field can be used to limit access from nodes to ResourceSlices with
  // the same node name. It also indicates to autoscalers that adding
  // new nodes of the same type as some old node might also make new
  // resources available.
  //
  // Exactly one of NodeName, NodeSelector and AllNodes must be set.
  // This field is immutable.
  //
  // +optional
  // +oneOf=NodeSelection
  optional string nodeName = 3;

  // NodeSelector defines which nodes have access to the resources in the pool,
  // when that pool is not limited to a single node.
  //
  // Must use exactly one term.
  //
  // Exactly one of NodeName, NodeSelector and AllNodes must be set.
  //
  // +optional
  // +oneOf=NodeSelection
  optional .k8s.io.api.core.v1.NodeSelector nodeSelector = 4;

  // AllNodes indicates that all nodes have access to the resources in the pool.
  //
  // Exactly one of NodeName, NodeSelector and AllNodes must be set.
  //
  // +optional
  // +oneOf=NodeSelection
  optional bool allNodes = 5;

  // Devices lists some or all of the devices in this pool.
  //
  // Must not have more than 128 entries.
  //
  // +optional
  // +listType=atomic
  repeated Device devices = 6;
}