open-nomad/nomad/structs/csi.go

1099 lines
28 KiB
Go

package structs
import (
"fmt"
"strings"
"time"
"github.com/hashicorp/nomad/helper"
)
// CSISocketName is the filename that Nomad expects plugins to create inside the
// PluginMountDir.
const CSISocketName = "csi.sock"
// CSIIntermediaryDirname is the name of the directory inside the PluginMountDir
// where Nomad will expect plugins to create intermediary mounts for volumes.
const CSIIntermediaryDirname = "volumes"
// VolumeTypeCSI is the type in the volume stanza of a TaskGroup
const VolumeTypeCSI = "csi"
// CSIPluginType is an enum string that encapsulates the valid options for a
// CSIPlugin stanza's Type. These modes will allow the plugin to be used in
// different ways by the client.
type CSIPluginType string
const (
// CSIPluginTypeNode indicates that Nomad should only use the plugin for
// performing Node RPCs against the provided plugin.
CSIPluginTypeNode CSIPluginType = "node"
// CSIPluginTypeController indicates that Nomad should only use the plugin for
// performing Controller RPCs against the provided plugin.
CSIPluginTypeController CSIPluginType = "controller"
// CSIPluginTypeMonolith indicates that Nomad can use the provided plugin for
// both controller and node rpcs.
CSIPluginTypeMonolith CSIPluginType = "monolith"
)
// CSIPluginTypeIsValid validates the given CSIPluginType string and returns
// true only when a correct plugin type is specified.
func CSIPluginTypeIsValid(pt CSIPluginType) bool {
switch pt {
case CSIPluginTypeNode, CSIPluginTypeController, CSIPluginTypeMonolith:
return true
default:
return false
}
}
// TaskCSIPluginConfig contains the data that is required to setup a task as a
// CSI plugin. This will be used by the csi_plugin_supervisor_hook to configure
// mounts for the plugin and initiate the connection to the plugin catalog.
type TaskCSIPluginConfig struct {
// ID is the identifier of the plugin.
// Ideally this should be the FQDN of the plugin.
ID string
// Type instructs Nomad on how to handle processing a plugin
Type CSIPluginType
// MountDir is the destination that nomad should mount in its CSI
// directory for the plugin. It will then expect a file called CSISocketName
// to be created by the plugin, and will provide references into
// "MountDir/CSIIntermediaryDirname/{VolumeName}/{AllocID} for mounts.
MountDir string
}
func (t *TaskCSIPluginConfig) Copy() *TaskCSIPluginConfig {
if t == nil {
return nil
}
nt := new(TaskCSIPluginConfig)
*nt = *t
return nt
}
// CSIVolumeAttachmentMode chooses the type of storage api that will be used to
// interact with the device.
type CSIVolumeAttachmentMode string
const (
CSIVolumeAttachmentModeUnknown CSIVolumeAttachmentMode = ""
CSIVolumeAttachmentModeBlockDevice CSIVolumeAttachmentMode = "block-device"
CSIVolumeAttachmentModeFilesystem CSIVolumeAttachmentMode = "file-system"
)
func ValidCSIVolumeAttachmentMode(attachmentMode CSIVolumeAttachmentMode) bool {
switch attachmentMode {
case CSIVolumeAttachmentModeBlockDevice, CSIVolumeAttachmentModeFilesystem:
return true
default:
return false
}
}
// CSIVolumeAccessMode indicates how a volume should be used in a storage topology
// e.g whether the provider should make the volume available concurrently.
type CSIVolumeAccessMode string
const (
CSIVolumeAccessModeUnknown CSIVolumeAccessMode = ""
CSIVolumeAccessModeSingleNodeReader CSIVolumeAccessMode = "single-node-reader-only"
CSIVolumeAccessModeSingleNodeWriter CSIVolumeAccessMode = "single-node-writer"
CSIVolumeAccessModeMultiNodeReader CSIVolumeAccessMode = "multi-node-reader-only"
CSIVolumeAccessModeMultiNodeSingleWriter CSIVolumeAccessMode = "multi-node-single-writer"
CSIVolumeAccessModeMultiNodeMultiWriter CSIVolumeAccessMode = "multi-node-multi-writer"
)
// ValidCSIVolumeAccessMode checks to see that the provided access mode is a valid,
// non-empty access mode.
func ValidCSIVolumeAccessMode(accessMode CSIVolumeAccessMode) bool {
switch accessMode {
case CSIVolumeAccessModeSingleNodeReader, CSIVolumeAccessModeSingleNodeWriter,
CSIVolumeAccessModeMultiNodeReader, CSIVolumeAccessModeMultiNodeSingleWriter,
CSIVolumeAccessModeMultiNodeMultiWriter:
return true
default:
return false
}
}
// ValidCSIVolumeAccessMode checks for a writable access mode
func ValidCSIVolumeWriteAccessMode(accessMode CSIVolumeAccessMode) bool {
switch accessMode {
case CSIVolumeAccessModeSingleNodeWriter,
CSIVolumeAccessModeMultiNodeSingleWriter,
CSIVolumeAccessModeMultiNodeMultiWriter:
return true
default:
return false
}
}
// CSIMountOptions contain optional additional configuration that can be used
// when specifying that a Volume should be used with VolumeAccessTypeMount.
type CSIMountOptions struct {
// FSType is an optional field that allows an operator to specify the type
// of the filesystem.
FSType string
// MountFlags contains additional options that may be used when mounting the
// volume by the plugin. This may contain sensitive data and should not be
// leaked.
MountFlags []string
}
func (o *CSIMountOptions) Copy() *CSIMountOptions {
if o == nil {
return nil
}
no := *o
no.MountFlags = helper.CopySliceString(o.MountFlags)
return &no
}
func (o *CSIMountOptions) Merge(p *CSIMountOptions) {
if p == nil {
return
}
if p.FSType != "" {
o.FSType = p.FSType
}
if p.MountFlags != nil {
o.MountFlags = p.MountFlags
}
}
// CSIMountOptions implements the Stringer and GoStringer interfaces to prevent
// accidental leakage of sensitive mount flags via logs.
var _ fmt.Stringer = &CSIMountOptions{}
var _ fmt.GoStringer = &CSIMountOptions{}
func (v *CSIMountOptions) String() string {
mountFlagsString := "nil"
if len(v.MountFlags) != 0 {
mountFlagsString = "[REDACTED]"
}
return fmt.Sprintf("csi.CSIOptions(FSType: %s, MountFlags: %s)", v.FSType, mountFlagsString)
}
func (v *CSIMountOptions) GoString() string {
return v.String()
}
// CSISecrets contain optional additional configuration that can be used
// when specifying that a Volume should be used with VolumeAccessTypeMount.
type CSISecrets map[string]string
// CSISecrets implements the Stringer and GoStringer interfaces to prevent
// accidental leakage of secrets via logs.
var _ fmt.Stringer = &CSISecrets{}
var _ fmt.GoStringer = &CSISecrets{}
func (s *CSISecrets) String() string {
redacted := map[string]string{}
for k := range *s {
redacted[k] = "[REDACTED]"
}
return fmt.Sprintf("csi.CSISecrets(%v)", redacted)
}
func (s *CSISecrets) GoString() string {
return s.String()
}
type CSIVolumeClaim struct {
AllocationID string
NodeID string
ExternalNodeID string
Mode CSIVolumeClaimMode
State CSIVolumeClaimState
}
type CSIVolumeClaimState int
const (
CSIVolumeClaimStateTaken CSIVolumeClaimState = iota
CSIVolumeClaimStateNodeDetached
CSIVolumeClaimStateControllerDetached
CSIVolumeClaimStateReadyToFree
CSIVolumeClaimStateUnpublishing
)
// CSIVolume is the full representation of a CSI Volume
type CSIVolume struct {
// ID is a namespace unique URL safe identifier for the volume
ID string
// Name is a display name for the volume, not required to be unique
Name string
// ExternalID identifies the volume for the CSI interface, may be URL unsafe
ExternalID string
Namespace string
Topologies []*CSITopology
AccessMode CSIVolumeAccessMode
AttachmentMode CSIVolumeAttachmentMode
MountOptions *CSIMountOptions
Secrets CSISecrets
Parameters map[string]string
Context map[string]string
// Allocations, tracking claim status
ReadAllocs map[string]*Allocation // AllocID -> Allocation
WriteAllocs map[string]*Allocation // AllocID -> Allocation
ReadClaims map[string]*CSIVolumeClaim // AllocID -> claim
WriteClaims map[string]*CSIVolumeClaim // AllocID -> claim
PastClaims map[string]*CSIVolumeClaim // AllocID -> claim
// Schedulable is true if all the denormalized plugin health fields are true, and the
// volume has not been marked for garbage collection
Schedulable bool
PluginID string
Provider string
ProviderVersion string
ControllerRequired bool
ControllersHealthy int
ControllersExpected int
NodesHealthy int
NodesExpected int
ResourceExhausted time.Time
CreateIndex uint64
ModifyIndex uint64
}
// CSIVolListStub is partial representation of a CSI Volume for inclusion in lists
type CSIVolListStub struct {
ID string
Namespace string
Name string
ExternalID string
Topologies []*CSITopology
AccessMode CSIVolumeAccessMode
AttachmentMode CSIVolumeAttachmentMode
CurrentReaders int
CurrentWriters int
Schedulable bool
PluginID string
Provider string
ControllersHealthy int
ControllersExpected int
NodesHealthy int
NodesExpected int
CreateIndex uint64
ModifyIndex uint64
}
// NewCSIVolume creates the volume struct. No side-effects
func NewCSIVolume(volumeID string, index uint64) *CSIVolume {
out := &CSIVolume{
ID: volumeID,
CreateIndex: index,
ModifyIndex: index,
}
out.newStructs()
return out
}
func (v *CSIVolume) newStructs() {
v.Topologies = []*CSITopology{}
v.MountOptions = new(CSIMountOptions)
v.Secrets = CSISecrets{}
v.Parameters = map[string]string{}
v.Context = map[string]string{}
v.ReadAllocs = map[string]*Allocation{}
v.WriteAllocs = map[string]*Allocation{}
v.ReadClaims = map[string]*CSIVolumeClaim{}
v.WriteClaims = map[string]*CSIVolumeClaim{}
v.PastClaims = map[string]*CSIVolumeClaim{}
}
func (v *CSIVolume) RemoteID() string {
if v.ExternalID != "" {
return v.ExternalID
}
return v.ID
}
func (v *CSIVolume) Stub() *CSIVolListStub {
stub := CSIVolListStub{
ID: v.ID,
Namespace: v.Namespace,
Name: v.Name,
ExternalID: v.ExternalID,
Topologies: v.Topologies,
AccessMode: v.AccessMode,
AttachmentMode: v.AttachmentMode,
CurrentReaders: len(v.ReadAllocs),
CurrentWriters: len(v.WriteAllocs),
Schedulable: v.Schedulable,
PluginID: v.PluginID,
Provider: v.Provider,
ControllersHealthy: v.ControllersHealthy,
ControllersExpected: v.ControllersExpected,
NodesHealthy: v.NodesHealthy,
NodesExpected: v.NodesExpected,
CreateIndex: v.CreateIndex,
ModifyIndex: v.ModifyIndex,
}
return &stub
}
func (v *CSIVolume) ReadSchedulable() bool {
if !v.Schedulable {
return false
}
return v.ResourceExhausted == time.Time{}
}
// WriteSchedulable determines if the volume is schedulable for writes, considering only
// volume health
func (v *CSIVolume) WriteSchedulable() bool {
if !v.Schedulable {
return false
}
switch v.AccessMode {
case CSIVolumeAccessModeSingleNodeWriter, CSIVolumeAccessModeMultiNodeSingleWriter, CSIVolumeAccessModeMultiNodeMultiWriter:
return v.ResourceExhausted == time.Time{}
default:
return false
}
}
// WriteFreeClaims determines if there are any free write claims available
func (v *CSIVolume) WriteFreeClaims() bool {
switch v.AccessMode {
case CSIVolumeAccessModeSingleNodeWriter, CSIVolumeAccessModeMultiNodeSingleWriter:
return len(v.WriteClaims) == 0
case CSIVolumeAccessModeMultiNodeMultiWriter:
// the CSI spec doesn't allow for setting a max number of writers.
// we track node resource exhaustion through v.ResourceExhausted
// which is checked in WriteSchedulable
return true
default:
return false
}
}
// InUse tests whether any allocations are actively using the volume
func (v *CSIVolume) InUse() bool {
return len(v.ReadAllocs) != 0 ||
len(v.WriteAllocs) != 0
}
// Copy returns a copy of the volume, which shares only the Topologies slice
func (v *CSIVolume) Copy() *CSIVolume {
out := new(CSIVolume)
*out = *v
out.newStructs() // zero-out the non-primitive structs
for _, t := range v.Topologies {
out.Topologies = append(out.Topologies, t.Copy())
}
if v.MountOptions != nil {
*out.MountOptions = *v.MountOptions
}
for k, v := range v.Secrets {
out.Secrets[k] = v
}
for k, v := range v.Parameters {
out.Parameters[k] = v
}
for k, v := range v.Context {
out.Context[k] = v
}
for k, alloc := range v.ReadAllocs {
out.ReadAllocs[k] = alloc.Copy()
}
for k, alloc := range v.WriteAllocs {
out.WriteAllocs[k] = alloc.Copy()
}
for k, v := range v.ReadClaims {
claim := *v
out.ReadClaims[k] = &claim
}
for k, v := range v.WriteClaims {
claim := *v
out.WriteClaims[k] = &claim
}
for k, v := range v.PastClaims {
claim := *v
out.PastClaims[k] = &claim
}
return out
}
// Claim updates the allocations and changes the volume state
func (v *CSIVolume) Claim(claim *CSIVolumeClaim, alloc *Allocation) error {
if claim.State == CSIVolumeClaimStateTaken {
switch claim.Mode {
case CSIVolumeClaimRead:
return v.ClaimRead(claim, alloc)
case CSIVolumeClaimWrite:
return v.ClaimWrite(claim, alloc)
}
}
// either GC or a Unpublish checkpoint
return v.ClaimRelease(claim)
}
// ClaimRead marks an allocation as using a volume read-only
func (v *CSIVolume) ClaimRead(claim *CSIVolumeClaim, alloc *Allocation) error {
if _, ok := v.ReadAllocs[claim.AllocationID]; ok {
return nil
}
if alloc == nil {
return fmt.Errorf("allocation missing: %s", claim.AllocationID)
}
if !v.ReadSchedulable() {
return fmt.Errorf("unschedulable")
}
// Allocations are copy on write, so we want to keep the id but don't need the
// pointer. We'll get it from the db in denormalize.
v.ReadAllocs[claim.AllocationID] = nil
delete(v.WriteAllocs, claim.AllocationID)
v.ReadClaims[claim.AllocationID] = claim
delete(v.WriteClaims, claim.AllocationID)
delete(v.PastClaims, claim.AllocationID)
return nil
}
// ClaimWrite marks an allocation as using a volume as a writer
func (v *CSIVolume) ClaimWrite(claim *CSIVolumeClaim, alloc *Allocation) error {
if _, ok := v.WriteAllocs[claim.AllocationID]; ok {
return nil
}
if alloc == nil {
return fmt.Errorf("allocation missing: %s", claim.AllocationID)
}
if !v.WriteSchedulable() {
return fmt.Errorf("unschedulable")
}
if !v.WriteFreeClaims() {
// Check the blocking allocations to see if they belong to this job
for _, a := range v.WriteAllocs {
if a != nil && (a.Namespace != alloc.Namespace || a.JobID != alloc.JobID) {
return fmt.Errorf("volume max claim reached")
}
}
}
// Allocations are copy on write, so we want to keep the id but don't need the
// pointer. We'll get it from the db in denormalize.
v.WriteAllocs[alloc.ID] = nil
delete(v.ReadAllocs, alloc.ID)
v.WriteClaims[alloc.ID] = claim
delete(v.ReadClaims, alloc.ID)
delete(v.PastClaims, alloc.ID)
return nil
}
// ClaimRelease is called when the allocation has terminated and
// already stopped using the volume
func (v *CSIVolume) ClaimRelease(claim *CSIVolumeClaim) error {
if claim.State == CSIVolumeClaimStateReadyToFree {
delete(v.ReadAllocs, claim.AllocationID)
delete(v.WriteAllocs, claim.AllocationID)
delete(v.ReadClaims, claim.AllocationID)
delete(v.WriteClaims, claim.AllocationID)
delete(v.PastClaims, claim.AllocationID)
} else {
v.PastClaims[claim.AllocationID] = claim
}
return nil
}
// Equality by value
func (v *CSIVolume) Equal(o *CSIVolume) bool {
if v == nil || o == nil {
return v == o
}
// Omit the plugin health fields, their values are controlled by plugin jobs
if v.ID == o.ID &&
v.Namespace == o.Namespace &&
v.AccessMode == o.AccessMode &&
v.AttachmentMode == o.AttachmentMode &&
v.PluginID == o.PluginID {
// Setwise equality of topologies
var ok bool
for _, t := range v.Topologies {
ok = false
for _, u := range o.Topologies {
if t.Equal(u) {
ok = true
break
}
}
if !ok {
return false
}
}
return true
}
return false
}
// Validate validates the volume struct, returning all validation errors at once
func (v *CSIVolume) Validate() error {
errs := []string{}
if v.ID == "" {
errs = append(errs, "missing volume id")
}
if v.PluginID == "" {
errs = append(errs, "missing plugin id")
}
if v.Namespace == "" {
errs = append(errs, "missing namespace")
}
if v.AccessMode == "" {
errs = append(errs, "missing access mode")
}
if v.AttachmentMode == "" {
errs = append(errs, "missing attachment mode")
}
if v.AttachmentMode == CSIVolumeAttachmentModeBlockDevice {
if v.MountOptions != nil {
if v.MountOptions.FSType != "" {
errs = append(errs, "mount options not allowed for block-device")
}
if v.MountOptions.MountFlags != nil && len(v.MountOptions.MountFlags) != 0 {
errs = append(errs, "mount options not allowed for block-device")
}
}
}
// TODO: Volume Topologies are optional - We should check to see if the plugin
// the volume is being registered with requires them.
// var ok bool
// for _, t := range v.Topologies {
// if t != nil && len(t.Segments) > 0 {
// ok = true
// break
// }
// }
// if !ok {
// errs = append(errs, "missing topology")
// }
if len(errs) > 0 {
return fmt.Errorf("validation: %s", strings.Join(errs, ", "))
}
return nil
}
// Request and response wrappers
type CSIVolumeRegisterRequest struct {
Volumes []*CSIVolume
WriteRequest
}
type CSIVolumeRegisterResponse struct {
QueryMeta
}
type CSIVolumeDeregisterRequest struct {
VolumeIDs []string
Force bool
WriteRequest
}
type CSIVolumeDeregisterResponse struct {
QueryMeta
}
type CSIVolumeClaimMode int
const (
CSIVolumeClaimRead CSIVolumeClaimMode = iota
CSIVolumeClaimWrite
// for GC we don't have a specific claim to set the state on, so instead we
// create a new claim for GC in order to bump the ModifyIndex and trigger
// volumewatcher
CSIVolumeClaimGC
)
type CSIVolumeClaimBatchRequest struct {
Claims []CSIVolumeClaimRequest
}
type CSIVolumeClaimRequest struct {
VolumeID string
AllocationID string
NodeID string
ExternalNodeID string
Claim CSIVolumeClaimMode
State CSIVolumeClaimState
WriteRequest
}
func (req *CSIVolumeClaimRequest) ToClaim() *CSIVolumeClaim {
return &CSIVolumeClaim{
AllocationID: req.AllocationID,
NodeID: req.NodeID,
ExternalNodeID: req.ExternalNodeID,
Mode: req.Claim,
State: req.State,
}
}
type CSIVolumeClaimResponse struct {
// Opaque static publish properties of the volume. SP MAY use this
// field to ensure subsequent `NodeStageVolume` or `NodePublishVolume`
// calls calls have contextual information.
// The contents of this field SHALL be opaque to nomad.
// The contents of this field SHALL NOT be mutable.
// The contents of this field SHALL be safe for the nomad to cache.
// The contents of this field SHOULD NOT contain sensitive
// information.
// The contents of this field SHOULD NOT be used for uniquely
// identifying a volume. The `volume_id` alone SHOULD be sufficient to
// identify the volume.
// This field is OPTIONAL and when present MUST be passed to
// `NodeStageVolume` or `NodePublishVolume` calls on the client
PublishContext map[string]string
// Volume contains the expanded CSIVolume for use on the client after a Claim
// has completed.
Volume *CSIVolume
QueryMeta
}
type CSIVolumeListRequest struct {
PluginID string
NodeID string
QueryOptions
}
type CSIVolumeListResponse struct {
Volumes []*CSIVolListStub
QueryMeta
}
type CSIVolumeGetRequest struct {
ID string
QueryOptions
}
type CSIVolumeGetResponse struct {
Volume *CSIVolume
QueryMeta
}
type CSIVolumeUnpublishRequest struct {
VolumeID string
Claim *CSIVolumeClaim
WriteRequest
}
type CSIVolumeUnpublishResponse struct {
QueryMeta
}
// CSIPlugin collects fingerprint info context for the plugin for clients
type CSIPlugin struct {
ID string
Provider string // the vendor name from CSI GetPluginInfoResponse
Version string // the vendor verson from CSI GetPluginInfoResponse
ControllerRequired bool
// Map Node.IDs to fingerprint results, split by type. Monolith type plugins have
// both sets of fingerprinting results.
Controllers map[string]*CSIInfo
Nodes map[string]*CSIInfo
// Allocations are populated by denormalize to show running allocations
Allocations []*AllocListStub
// Jobs are populated to by job update to support expected counts and the UI
ControllerJobs JobDescriptions
NodeJobs JobDescriptions
// Cache the count of healthy plugins
ControllersHealthy int
ControllersExpected int
NodesHealthy int
NodesExpected int
CreateIndex uint64
ModifyIndex uint64
}
// NewCSIPlugin creates the plugin struct. No side-effects
func NewCSIPlugin(id string, index uint64) *CSIPlugin {
out := &CSIPlugin{
ID: id,
CreateIndex: index,
ModifyIndex: index,
}
out.newStructs()
return out
}
func (p *CSIPlugin) newStructs() {
p.Controllers = map[string]*CSIInfo{}
p.Nodes = map[string]*CSIInfo{}
p.ControllerJobs = make(JobDescriptions)
p.NodeJobs = make(JobDescriptions)
}
func (p *CSIPlugin) Copy() *CSIPlugin {
copy := *p
out := &copy
out.newStructs()
for k, v := range p.Controllers {
out.Controllers[k] = v.Copy()
}
for k, v := range p.Nodes {
out.Nodes[k] = v.Copy()
}
for k, v := range p.ControllerJobs {
out.ControllerJobs[k] = v.Copy()
}
for k, v := range p.NodeJobs {
out.NodeJobs[k] = v.Copy()
}
return out
}
// AddPlugin adds a single plugin running on the node. Called from state.NodeUpdate in a
// transaction
func (p *CSIPlugin) AddPlugin(nodeID string, info *CSIInfo) error {
if info.ControllerInfo != nil {
p.ControllerRequired = info.RequiresControllerPlugin &&
(info.ControllerInfo.SupportsAttachDetach ||
info.ControllerInfo.SupportsReadOnlyAttach)
prev, ok := p.Controllers[nodeID]
if ok {
if prev == nil {
return fmt.Errorf("plugin missing controller: %s", nodeID)
}
if prev.Healthy {
p.ControllersHealthy -= 1
}
}
// note: for this to work as expected, only a single
// controller for a given plugin can be on a given Nomad
// client, they also conflict on the client so this should be
// ok
if prev != nil || info.Healthy {
p.Controllers[nodeID] = info
}
if info.Healthy {
p.ControllersHealthy += 1
}
}
if info.NodeInfo != nil {
prev, ok := p.Nodes[nodeID]
if ok {
if prev == nil {
return fmt.Errorf("plugin missing node: %s", nodeID)
}
if prev.Healthy {
p.NodesHealthy -= 1
}
}
if prev != nil || info.Healthy {
p.Nodes[nodeID] = info
}
if info.Healthy {
p.NodesHealthy += 1
}
}
return nil
}
// DeleteNode removes all plugins from the node. Called from state.DeleteNode in a
// transaction
func (p *CSIPlugin) DeleteNode(nodeID string) error {
return p.DeleteNodeForType(nodeID, CSIPluginTypeMonolith)
}
// DeleteNodeForType deletes a client node from the list of controllers or node instance of
// a plugin. Called from deleteJobFromPlugin during job deregistration, in a transaction
func (p *CSIPlugin) DeleteNodeForType(nodeID string, pluginType CSIPluginType) error {
switch pluginType {
case CSIPluginTypeController:
prev, ok := p.Controllers[nodeID]
if ok {
if prev == nil {
return fmt.Errorf("plugin missing controller: %s", nodeID)
}
if prev.Healthy {
p.ControllersHealthy -= 1
}
}
delete(p.Controllers, nodeID)
case CSIPluginTypeNode:
prev, ok := p.Nodes[nodeID]
if ok {
if prev == nil {
return fmt.Errorf("plugin missing node: %s", nodeID)
}
if prev.Healthy {
p.NodesHealthy -= 1
}
}
delete(p.Nodes, nodeID)
case CSIPluginTypeMonolith:
p.DeleteNodeForType(nodeID, CSIPluginTypeController)
p.DeleteNodeForType(nodeID, CSIPluginTypeNode)
}
return nil
}
// DeleteAlloc removes the fingerprint info for the allocation
func (p *CSIPlugin) DeleteAlloc(allocID, nodeID string) error {
prev, ok := p.Controllers[nodeID]
if ok {
if prev == nil {
return fmt.Errorf("plugin missing controller: %s", nodeID)
}
if prev.AllocID == allocID {
if prev.Healthy {
p.ControllersHealthy -= 1
}
delete(p.Controllers, nodeID)
}
}
prev, ok = p.Nodes[nodeID]
if ok {
if prev == nil {
return fmt.Errorf("plugin missing node: %s", nodeID)
}
if prev.AllocID == allocID {
if prev.Healthy {
p.NodesHealthy -= 1
}
delete(p.Nodes, nodeID)
}
}
return nil
}
// AddJob adds a job to the plugin and increments expected
func (p *CSIPlugin) AddJob(job *Job, summary *JobSummary) {
p.UpdateExpectedWithJob(job, summary, false)
}
// DeleteJob removes the job from the plugin and decrements expected
func (p *CSIPlugin) DeleteJob(job *Job, summary *JobSummary) {
p.UpdateExpectedWithJob(job, summary, true)
}
// UpdateExpectedWithJob maintains the expected instance count
// we use the summary to add non-allocation expected counts
func (p *CSIPlugin) UpdateExpectedWithJob(job *Job, summary *JobSummary, terminal bool) {
var count int
for _, tg := range job.TaskGroups {
if job.Type == JobTypeSystem {
if summary == nil {
continue
}
s, ok := summary.Summary[tg.Name]
if !ok {
continue
}
count = s.Running + s.Queued + s.Starting
} else {
count = tg.Count
}
for _, t := range tg.Tasks {
if t.CSIPluginConfig == nil ||
t.CSIPluginConfig.ID != p.ID {
continue
}
// Change the correct plugin expected, monolith should change both
if t.CSIPluginConfig.Type == CSIPluginTypeController ||
t.CSIPluginConfig.Type == CSIPluginTypeMonolith {
if terminal {
p.ControllerJobs.Delete(job)
} else {
p.ControllerJobs.Add(job, count)
}
}
if t.CSIPluginConfig.Type == CSIPluginTypeNode ||
t.CSIPluginConfig.Type == CSIPluginTypeMonolith {
if terminal {
p.NodeJobs.Delete(job)
} else {
p.NodeJobs.Add(job, count)
}
}
}
}
p.ControllersExpected = p.ControllerJobs.Count()
p.NodesExpected = p.NodeJobs.Count()
}
// JobDescription records Job identification and the count of expected plugin instances
type JobDescription struct {
Namespace string
ID string
Expected int
}
// JobNamespacedDescriptions maps Job.ID to JobDescription
type JobNamespacedDescriptions map[string]JobDescription
func (j JobNamespacedDescriptions) Copy() JobNamespacedDescriptions {
copy := JobNamespacedDescriptions{}
for k, v := range j {
copy[k] = v
}
return copy
}
// JobDescriptions maps Namespace to a mapping of Job.ID to JobDescription
type JobDescriptions map[string]JobNamespacedDescriptions
// Add the Job to the JobDescriptions, creating maps as necessary
func (j JobDescriptions) Add(job *Job, expected int) {
if j == nil {
j = make(JobDescriptions)
}
if j[job.Namespace] == nil {
j[job.Namespace] = make(JobNamespacedDescriptions)
}
j[job.Namespace][job.ID] = JobDescription{
Namespace: job.Namespace,
ID: job.ID,
Expected: expected,
}
}
// Count the Expected instances for all JobDescriptions
func (j JobDescriptions) Count() int {
if j == nil {
return 0
}
count := 0
for _, jnd := range j {
for _, jd := range jnd {
count += jd.Expected
}
}
return count
}
// Delete the Job from the JobDescriptions
func (j JobDescriptions) Delete(job *Job) {
if j != nil &&
j[job.Namespace] != nil {
delete(j[job.Namespace], job.ID)
}
}
type CSIPluginListStub struct {
ID string
Provider string
ControllerRequired bool
ControllersHealthy int
ControllersExpected int
NodesHealthy int
NodesExpected int
CreateIndex uint64
ModifyIndex uint64
}
func (p *CSIPlugin) Stub() *CSIPluginListStub {
return &CSIPluginListStub{
ID: p.ID,
Provider: p.Provider,
ControllerRequired: p.ControllerRequired,
ControllersHealthy: p.ControllersHealthy,
ControllersExpected: p.ControllersExpected,
NodesHealthy: p.NodesHealthy,
NodesExpected: p.NodesExpected,
CreateIndex: p.CreateIndex,
ModifyIndex: p.ModifyIndex,
}
}
func (p *CSIPlugin) IsEmpty() bool {
return p == nil ||
len(p.Controllers) == 0 &&
len(p.Nodes) == 0 &&
p.ControllerJobs.Count() == 0 &&
p.NodeJobs.Count() == 0
}
type CSIPluginListRequest struct {
QueryOptions
}
type CSIPluginListResponse struct {
Plugins []*CSIPluginListStub
QueryMeta
}
type CSIPluginGetRequest struct {
ID string
QueryOptions
}
type CSIPluginGetResponse struct {
Plugin *CSIPlugin
QueryMeta
}
type CSIPluginDeleteRequest struct {
ID string
QueryOptions
}
type CSIPluginDeleteResponse struct {
QueryMeta
}