open-nomad/api/nodes.go

961 lines
25 KiB
Go
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

package api
import (
"context"
"fmt"
"sort"
"strconv"
"time"
)
const (
NodeStatusInit = "initializing"
NodeStatusReady = "ready"
NodeStatusDown = "down"
NodeStatusDisconnected = "disconnected"
// NodeSchedulingEligible and Ineligible marks the node as eligible or not,
// respectively, for receiving allocations. This is orthogonal to the node
// status being ready.
NodeSchedulingEligible = "eligible"
NodeSchedulingIneligible = "ineligible"
DrainStatusDraining DrainStatus = "draining"
DrainStatusComplete DrainStatus = "complete"
DrainStatusCanceled DrainStatus = "canceled"
)
// Nodes is used to query node-related API endpoints
type Nodes struct {
client *Client
}
// Nodes returns a handle on the node endpoints.
func (c *Client) Nodes() *Nodes {
return &Nodes{client: c}
}
// List is used to list out all the nodes
func (n *Nodes) List(q *QueryOptions) ([]*NodeListStub, *QueryMeta, error) {
var resp NodeIndexSort
qm, err := n.client.query("/v1/nodes", &resp, q)
if err != nil {
return nil, nil, err
}
sort.Sort(resp)
return resp, qm, nil
}
func (n *Nodes) PrefixList(prefix string) ([]*NodeListStub, *QueryMeta, error) {
return n.List(&QueryOptions{Prefix: prefix})
}
func (n *Nodes) PrefixListOpts(prefix string, opts *QueryOptions) ([]*NodeListStub, *QueryMeta, error) {
if opts == nil {
opts = &QueryOptions{Prefix: prefix}
} else {
opts.Prefix = prefix
}
return n.List(opts)
}
// Info is used to query a specific node by its ID.
func (n *Nodes) Info(nodeID string, q *QueryOptions) (*Node, *QueryMeta, error) {
var resp Node
qm, err := n.client.query("/v1/node/"+nodeID, &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, qm, nil
}
// NodeUpdateDrainRequest is used to update the drain specification for a node.
type NodeUpdateDrainRequest struct {
// NodeID is the node to update the drain specification for.
NodeID string
// DrainSpec is the drain specification to set for the node. A nil DrainSpec
// will disable draining.
DrainSpec *DrainSpec
// MarkEligible marks the node as eligible for scheduling if removing
// the drain strategy.
MarkEligible bool
// Meta allows operators to specify metadata related to the drain operation
Meta map[string]string
}
// NodeDrainUpdateResponse is used to respond to a node drain update
type NodeDrainUpdateResponse struct {
NodeModifyIndex uint64
EvalIDs []string
EvalCreateIndex uint64
WriteMeta
}
// DrainOptions is used to pass through node drain parameters
type DrainOptions struct {
// DrainSpec contains the drain specification for the node. If non-nil,
// the node will be marked ineligible and begin/continue draining according
// to the provided drain spec.
// If nil, any existing drain operation will be canceled.
DrainSpec *DrainSpec
// MarkEligible indicates whether the node should be marked as eligible when
// canceling a drain operation.
MarkEligible bool
// Meta is metadata that is persisted in Node.LastDrain about this
// drain update.
Meta map[string]string
}
// UpdateDrain is used to update the drain strategy for a given node. If
// markEligible is true and the drain is being removed, the node will be marked
// as having its scheduling being eligible
func (n *Nodes) UpdateDrain(nodeID string, spec *DrainSpec, markEligible bool, q *WriteOptions) (*NodeDrainUpdateResponse, error) {
resp, err := n.UpdateDrainOpts(nodeID, &DrainOptions{
DrainSpec: spec,
MarkEligible: markEligible,
Meta: nil,
}, q)
return resp, err
}
// UpdateDrainWithMeta is used to update the drain strategy for a given node. If
// markEligible is true and the drain is being removed, the node will be marked
// as having its scheduling being eligible
func (n *Nodes) UpdateDrainOpts(nodeID string, opts *DrainOptions, q *WriteOptions) (*NodeDrainUpdateResponse,
error) {
req := &NodeUpdateDrainRequest{
NodeID: nodeID,
DrainSpec: opts.DrainSpec,
MarkEligible: opts.MarkEligible,
Meta: opts.Meta,
}
var resp NodeDrainUpdateResponse
wm, err := n.client.put("/v1/node/"+nodeID+"/drain", req, &resp, q)
if err != nil {
return nil, err
}
resp.WriteMeta = *wm
return &resp, nil
}
// MonitorMsgLevels represents the severity log level of a MonitorMessage.
type MonitorMsgLevel int
const (
MonitorMsgLevelNormal MonitorMsgLevel = 0
MonitorMsgLevelInfo MonitorMsgLevel = 1
MonitorMsgLevelWarn MonitorMsgLevel = 2
MonitorMsgLevelError MonitorMsgLevel = 3
)
// MonitorMessage contains a message and log level.
type MonitorMessage struct {
Level MonitorMsgLevel
Message string
}
// Messagef formats a new MonitorMessage.
func Messagef(lvl MonitorMsgLevel, msg string, args ...interface{}) *MonitorMessage {
return &MonitorMessage{
Level: lvl,
Message: fmt.Sprintf(msg, args...),
}
}
func (m *MonitorMessage) String() string {
return m.Message
}
// MonitorDrain emits drain related events on the returned string channel. The
// channel will be closed when all allocations on the draining node have
// stopped, when an error occurs, or if the context is canceled.
func (n *Nodes) MonitorDrain(ctx context.Context, nodeID string, index uint64, ignoreSys bool) <-chan *MonitorMessage {
outCh := make(chan *MonitorMessage, 8)
nodeCh := make(chan *MonitorMessage, 1)
allocCh := make(chan *MonitorMessage, 8)
// Multiplex node and alloc chans onto outCh. This goroutine closes
// outCh when other chans have been closed.
multiplexCtx, cancel := context.WithCancel(ctx)
go n.monitorDrainMultiplex(multiplexCtx, cancel, outCh, nodeCh, allocCh)
// Monitor node for updates
go n.monitorDrainNode(multiplexCtx, nodeID, index, nodeCh)
// Monitor allocs on node for updates
go n.monitorDrainAllocs(multiplexCtx, nodeID, ignoreSys, allocCh)
return outCh
}
// monitorDrainMultiplex multiplexes node and alloc updates onto the out chan.
// Closes out chan when either the context is canceled, both update chans are
// closed, or an error occurs.
func (n *Nodes) monitorDrainMultiplex(ctx context.Context, cancel func(),
outCh chan<- *MonitorMessage, nodeCh, allocCh <-chan *MonitorMessage) {
defer cancel()
defer close(outCh)
nodeOk := true
allocOk := true
var msg *MonitorMessage
for {
// If both chans have been closed, close the output chan
if !nodeOk && !allocOk {
return
}
select {
case msg, nodeOk = <-nodeCh:
if !nodeOk {
// nil chan to prevent further recvs
nodeCh = nil
continue
}
case msg, allocOk = <-allocCh:
if !allocOk {
// nil chan to prevent further recvs
allocCh = nil
continue
}
case <-ctx.Done():
return
}
if msg == nil {
continue
}
select {
case outCh <- msg:
case <-ctx.Done():
return
}
// Abort on error messages
if msg.Level == MonitorMsgLevelError {
return
}
}
}
// monitorDrainNode emits node updates on nodeCh and closes the channel when
// the node has finished draining.
func (n *Nodes) monitorDrainNode(ctx context.Context, nodeID string,
index uint64, nodeCh chan<- *MonitorMessage) {
defer close(nodeCh)
var lastStrategy *DrainStrategy
q := QueryOptions{
AllowStale: true,
WaitIndex: index,
}
for {
node, meta, err := n.Info(nodeID, &q)
if err != nil {
msg := Messagef(MonitorMsgLevelError, "Error monitoring node: %v", err)
select {
case nodeCh <- msg:
case <-ctx.Done():
}
return
}
if node.DrainStrategy == nil {
msg := Messagef(MonitorMsgLevelInfo, "Drain complete for node %s", nodeID)
select {
case nodeCh <- msg:
case <-ctx.Done():
}
return
}
if node.Status == NodeStatusDown {
msg := Messagef(MonitorMsgLevelWarn, "Node %q down", nodeID)
select {
case nodeCh <- msg:
case <-ctx.Done():
}
}
// DrainStrategy changed
if lastStrategy != nil && !node.DrainStrategy.Equal(lastStrategy) {
msg := Messagef(MonitorMsgLevelInfo, "Node %q drain updated: %s", nodeID, node.DrainStrategy)
select {
case nodeCh <- msg:
case <-ctx.Done():
return
}
}
lastStrategy = node.DrainStrategy
// Drain still ongoing, update index and block for updates
q.WaitIndex = meta.LastIndex
}
}
// monitorDrainAllocs emits alloc updates on allocCh and closes the channel
// when the node has finished draining.
func (n *Nodes) monitorDrainAllocs(ctx context.Context, nodeID string, ignoreSys bool, allocCh chan<- *MonitorMessage) {
defer close(allocCh)
q := QueryOptions{AllowStale: true}
initial := make(map[string]*Allocation, 4)
for {
allocs, meta, err := n.Allocations(nodeID, &q)
if err != nil {
msg := Messagef(MonitorMsgLevelError, "Error monitoring allocations: %v", err)
select {
case allocCh <- msg:
case <-ctx.Done():
}
return
}
q.WaitIndex = meta.LastIndex
runningAllocs := 0
for _, a := range allocs {
// Get previous version of alloc
orig, existing := initial[a.ID]
// Update local alloc state
initial[a.ID] = a
migrating := a.DesiredTransition.ShouldMigrate()
var msg string
switch {
case !existing:
// Should only be possible if response
// from initial Allocations call was
// stale. No need to output
case orig.ClientStatus != a.ClientStatus:
// Alloc status has changed; output
msg = fmt.Sprintf("status %s -> %s", orig.ClientStatus, a.ClientStatus)
case migrating && !orig.DesiredTransition.ShouldMigrate():
// Alloc was marked for migration
msg = "marked for migration"
case migrating && (orig.DesiredStatus != a.DesiredStatus) && a.DesiredStatus == AllocDesiredStatusStop:
// Alloc has already been marked for migration and is now being stopped
msg = "draining"
}
if msg != "" {
select {
case allocCh <- Messagef(MonitorMsgLevelNormal, "Alloc %q %s", a.ID, msg):
case <-ctx.Done():
return
}
}
// Ignore malformed allocs
if a.Job == nil || a.Job.Type == nil {
continue
}
// Track how many allocs are still running
if ignoreSys && a.Job.Type != nil && *a.Job.Type == JobTypeSystem {
continue
}
switch a.ClientStatus {
case AllocClientStatusPending, AllocClientStatusRunning:
runningAllocs++
}
}
// Exit if all allocs are terminal
if runningAllocs == 0 {
msg := Messagef(MonitorMsgLevelInfo, "All allocations on node %q have stopped", nodeID)
select {
case allocCh <- msg:
case <-ctx.Done():
}
return
}
}
}
// NodeUpdateEligibilityRequest is used to update the drain specification for a node.
type NodeUpdateEligibilityRequest struct {
// NodeID is the node to update the drain specification for.
NodeID string
Eligibility string
}
// NodeEligibilityUpdateResponse is used to respond to a node eligibility update
type NodeEligibilityUpdateResponse struct {
NodeModifyIndex uint64
EvalIDs []string
EvalCreateIndex uint64
WriteMeta
}
// ToggleEligibility is used to update the scheduling eligibility of the node
func (n *Nodes) ToggleEligibility(nodeID string, eligible bool, q *WriteOptions) (*NodeEligibilityUpdateResponse, error) {
e := NodeSchedulingEligible
if !eligible {
e = NodeSchedulingIneligible
}
req := &NodeUpdateEligibilityRequest{
NodeID: nodeID,
Eligibility: e,
}
var resp NodeEligibilityUpdateResponse
wm, err := n.client.put("/v1/node/"+nodeID+"/eligibility", req, &resp, q)
if err != nil {
return nil, err
}
resp.WriteMeta = *wm
return &resp, nil
}
// Allocations is used to return the allocations associated with a node.
func (n *Nodes) Allocations(nodeID string, q *QueryOptions) ([]*Allocation, *QueryMeta, error) {
var resp []*Allocation
qm, err := n.client.query("/v1/node/"+nodeID+"/allocations", &resp, q)
if err != nil {
return nil, nil, err
}
sort.Sort(AllocationSort(resp))
return resp, qm, nil
}
func (n *Nodes) CSIVolumes(nodeID string, q *QueryOptions) ([]*CSIVolumeListStub, error) {
var resp []*CSIVolumeListStub
path := fmt.Sprintf("/v1/volumes?type=csi&node_id=%s", nodeID)
if _, err := n.client.query(path, &resp, q); err != nil {
return nil, err
}
return resp, nil
}
// ForceEvaluate is used to force-evaluate an existing node.
func (n *Nodes) ForceEvaluate(nodeID string, q *WriteOptions) (string, *WriteMeta, error) {
var resp nodeEvalResponse
wm, err := n.client.put("/v1/node/"+nodeID+"/evaluate", nil, &resp, q)
if err != nil {
return "", nil, err
}
return resp.EvalID, wm, nil
}
func (n *Nodes) Stats(nodeID string, q *QueryOptions) (*HostStats, error) {
var resp HostStats
path := fmt.Sprintf("/v1/client/stats?node_id=%s", nodeID)
if _, err := n.client.query(path, &resp, q); err != nil {
return nil, err
}
return &resp, nil
}
func (n *Nodes) GC(nodeID string, q *QueryOptions) error {
path := fmt.Sprintf("/v1/client/gc?node_id=%s", nodeID)
_, err := n.client.query(path, nil, q)
return err
}
// TODO Add tests
func (n *Nodes) GcAlloc(allocID string, q *QueryOptions) error {
path := fmt.Sprintf("/v1/client/allocation/%s/gc", allocID)
_, err := n.client.query(path, nil, q)
return err
}
// Purge removes a node from the system. Nodes can still re-join the cluster if
// they are alive.
func (n *Nodes) Purge(nodeID string, q *QueryOptions) (*NodePurgeResponse, *QueryMeta, error) {
var resp NodePurgeResponse
path := fmt.Sprintf("/v1/node/%s/purge", nodeID)
qm, err := n.client.putQuery(path, nil, &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, qm, nil
}
// NodePurgeResponse is used to deserialize a Purge response.
type NodePurgeResponse struct {
EvalIDs []string
EvalCreateIndex uint64
NodeModifyIndex uint64
}
// DriverInfo is used to deserialize a DriverInfo entry
type DriverInfo struct {
Attributes map[string]string
Detected bool
Healthy bool
HealthDescription string
UpdateTime time.Time
}
// HostVolumeInfo is used to return metadata about a given HostVolume.
type HostVolumeInfo struct {
Path string
ReadOnly bool
}
// HostNetworkInfo is used to return metadata about a given HostNetwork
type HostNetworkInfo struct {
Name string
CIDR string
Interface string
ReservedPorts string
}
type DrainStatus string
// DrainMetadata contains information about the most recent drain operation for a given Node.
type DrainMetadata struct {
StartedAt time.Time
UpdatedAt time.Time
Status DrainStatus
AccessorID string
Meta map[string]string
}
// Node is used to deserialize a node entry.
type Node struct {
ID string
Datacenter string
Name string
HTTPAddr string
TLSEnabled bool
Attributes map[string]string
Resources *Resources
Reserved *Resources
NodeResources *NodeResources
ReservedResources *NodeReservedResources
Links map[string]string
Meta map[string]string
NodeClass string
CgroupParent string
Drain bool
DrainStrategy *DrainStrategy
SchedulingEligibility string
Status string
StatusDescription string
StatusUpdatedAt int64
Events []*NodeEvent
Drivers map[string]*DriverInfo
HostVolumes map[string]*HostVolumeInfo
HostNetworks map[string]*HostNetworkInfo
CSIControllerPlugins map[string]*CSIInfo
CSINodePlugins map[string]*CSIInfo
LastDrain *DrainMetadata
CreateIndex uint64
ModifyIndex uint64
}
type NodeResources struct {
Cpu NodeCpuResources
Memory NodeMemoryResources
Disk NodeDiskResources
Networks []*NetworkResource
Devices []*NodeDeviceResource
MinDynamicPort int
MaxDynamicPort int
}
type NodeCpuResources struct {
CpuShares int64
TotalCpuCores uint16
ReservableCpuCores []uint16
}
type NodeMemoryResources struct {
MemoryMB int64
}
type NodeDiskResources struct {
DiskMB int64
}
type NodeReservedResources struct {
Cpu NodeReservedCpuResources
Memory NodeReservedMemoryResources
Disk NodeReservedDiskResources
Networks NodeReservedNetworkResources
}
type NodeReservedCpuResources struct {
CpuShares uint64
}
type NodeReservedMemoryResources struct {
MemoryMB uint64
}
type NodeReservedDiskResources struct {
DiskMB uint64
}
type NodeReservedNetworkResources struct {
ReservedHostPorts string
}
type CSITopologyRequest struct {
Required []*CSITopology `hcl:"required"`
Preferred []*CSITopology `hcl:"preferred"`
}
type CSITopology struct {
Segments map[string]string `hcl:"segments"`
}
// CSINodeInfo is the fingerprinted data from a CSI Plugin that is specific to
// the Node API.
type CSINodeInfo struct {
ID string
MaxVolumes int64
AccessibleTopology *CSITopology
// RequiresNodeStageVolume indicates whether the client should Stage/Unstage
// volumes on this node.
RequiresNodeStageVolume bool
// SupportsStats indicates plugin support for GET_VOLUME_STATS
SupportsStats bool
// SupportsExpand indicates plugin support for EXPAND_VOLUME
SupportsExpand bool
// SupportsCondition indicates plugin support for VOLUME_CONDITION
SupportsCondition bool
}
// CSIControllerInfo is the fingerprinted data from a CSI Plugin that is specific to
// the Controller API.
type CSIControllerInfo struct {
// SupportsCreateDelete indicates plugin support for CREATE_DELETE_VOLUME
SupportsCreateDelete bool
// SupportsPublishVolume is true when the controller implements the
// methods required to attach and detach volumes. If this is false Nomad
// should skip the controller attachment flow.
SupportsAttachDetach bool
// SupportsListVolumes is true when the controller implements the
// ListVolumes RPC. NOTE: This does not guarantee that attached nodes will
// be returned unless SupportsListVolumesAttachedNodes is also true.
SupportsListVolumes bool
// SupportsGetCapacity indicates plugin support for GET_CAPACITY
SupportsGetCapacity bool
// SupportsCreateDeleteSnapshot indicates plugin support for
// CREATE_DELETE_SNAPSHOT
SupportsCreateDeleteSnapshot bool
// SupportsListSnapshots indicates plugin support for LIST_SNAPSHOTS
SupportsListSnapshots bool
// SupportsClone indicates plugin support for CLONE_VOLUME
SupportsClone bool
// SupportsReadOnlyAttach is set to true when the controller returns the
// ATTACH_READONLY capability.
SupportsReadOnlyAttach bool
// SupportsExpand indicates plugin support for EXPAND_VOLUME
SupportsExpand bool
// SupportsListVolumesAttachedNodes indicates whether the plugin will
// return attached nodes data when making ListVolume RPCs (plugin support
// for LIST_VOLUMES_PUBLISHED_NODES)
SupportsListVolumesAttachedNodes bool
// SupportsCondition indicates plugin support for VOLUME_CONDITION
SupportsCondition bool
// SupportsGet indicates plugin support for GET_VOLUME
SupportsGet bool
}
// CSIInfo is the current state of a single CSI Plugin. This is updated regularly
// as plugin health changes on the node.
type CSIInfo struct {
PluginID string
AllocID string
Healthy bool
HealthDescription string
UpdateTime time.Time
RequiresControllerPlugin bool
RequiresTopologies bool
ControllerInfo *CSIControllerInfo `json:",omitempty"`
NodeInfo *CSINodeInfo `json:",omitempty"`
}
// DrainStrategy describes a Node's drain behavior.
type DrainStrategy struct {
// DrainSpec is the user declared drain specification
DrainSpec
// ForceDeadline is the deadline time for the drain after which drains will
// be forced
ForceDeadline time.Time
// StartedAt is the time the drain process started
StartedAt time.Time
}
// DrainSpec describes a Node's drain behavior.
type DrainSpec struct {
// Deadline is the duration after StartTime when the remaining
// allocations on a draining Node should be told to stop.
Deadline time.Duration
// IgnoreSystemJobs allows systems jobs to remain on the node even though it
// has been marked for draining.
IgnoreSystemJobs bool
}
func (d *DrainStrategy) Equal(o *DrainStrategy) bool {
if d == nil || o == nil {
return d == o
}
if d.ForceDeadline != o.ForceDeadline {
return false
}
if d.Deadline != o.Deadline {
return false
}
if d.IgnoreSystemJobs != o.IgnoreSystemJobs {
return false
}
return true
}
// String returns a human readable version of the drain strategy.
func (d *DrainStrategy) String() string {
if d.IgnoreSystemJobs {
return fmt.Sprintf("drain ignoring system jobs and deadline at %s", d.ForceDeadline)
}
return fmt.Sprintf("drain with deadline at %s", d.ForceDeadline)
}
const (
NodeEventSubsystemDrain = "Drain"
NodeEventSubsystemDriver = "Driver"
NodeEventSubsystemHeartbeat = "Heartbeat"
NodeEventSubsystemCluster = "Cluster"
)
// NodeEvent is a single unit representing a nodes state change
type NodeEvent struct {
Message string
Subsystem string
Details map[string]string
Timestamp time.Time
CreateIndex uint64
}
// HostStats represents resource usage stats of the host running a Nomad client
type HostStats struct {
Memory *HostMemoryStats
CPU []*HostCPUStats
DiskStats []*HostDiskStats
DeviceStats []*DeviceGroupStats
Uptime uint64
CPUTicksConsumed float64
}
type HostMemoryStats struct {
Total uint64
Available uint64
Used uint64
Free uint64
}
type HostCPUStats struct {
CPU string
User float64
System float64
Idle float64
}
type HostDiskStats struct {
Device string
Mountpoint string
Size uint64
Used uint64
Available uint64
UsedPercent float64
InodesUsedPercent float64
}
// DeviceGroupStats contains statistics for each device of a particular
// device group, identified by the vendor, type and name of the device.
type DeviceGroupStats struct {
Vendor string
Type string
Name string
// InstanceStats is a mapping of each device ID to its statistics.
InstanceStats map[string]*DeviceStats
}
// DeviceStats is the statistics for an individual device
type DeviceStats struct {
// Summary exposes a single summary metric that should be the most
// informative to users.
Summary *StatValue
// Stats contains the verbose statistics for the device.
Stats *StatObject
// Timestamp is the time the statistics were collected.
Timestamp time.Time
}
// StatObject is a collection of statistics either exposed at the top
// level or via nested StatObjects.
type StatObject struct {
// Nested is a mapping of object name to a nested stats object.
Nested map[string]*StatObject
// Attributes is a mapping of statistic name to its value.
Attributes map[string]*StatValue
}
// StatValue exposes the values of a particular statistic. The value may be of
// type float, integer, string or boolean. Numeric types can be exposed as a
// single value or as a fraction.
type StatValue struct {
// FloatNumeratorVal exposes a floating point value. If denominator is set
// it is assumed to be a fractional value, otherwise it is a scalar.
FloatNumeratorVal *float64 `json:",omitempty"`
FloatDenominatorVal *float64 `json:",omitempty"`
// IntNumeratorVal exposes a int value. If denominator is set it is assumed
// to be a fractional value, otherwise it is a scalar.
IntNumeratorVal *int64 `json:",omitempty"`
IntDenominatorVal *int64 `json:",omitempty"`
// StringVal exposes a string value. These are likely annotations.
StringVal *string `json:",omitempty"`
// BoolVal exposes a boolean statistic.
BoolVal *bool `json:",omitempty"`
// Unit gives the unit type: °F, %, MHz, MB, etc.
Unit string `json:",omitempty"`
// Desc provides a human readable description of the statistic.
Desc string `json:",omitempty"`
}
func (v *StatValue) String() string {
switch {
case v == nil:
return "<none>"
case v.BoolVal != nil:
return strconv.FormatBool(*v.BoolVal)
case v.StringVal != nil:
return *v.StringVal
case v.FloatNumeratorVal != nil:
str := formatFloat(*v.FloatNumeratorVal, 3)
if v.FloatDenominatorVal != nil {
str += " / " + formatFloat(*v.FloatDenominatorVal, 3)
}
if v.Unit != "" {
str += " " + v.Unit
}
return str
case v.IntNumeratorVal != nil:
str := strconv.FormatInt(*v.IntNumeratorVal, 10)
if v.IntDenominatorVal != nil {
str += " / " + strconv.FormatInt(*v.IntDenominatorVal, 10)
}
if v.Unit != "" {
str += " " + v.Unit
}
return str
default:
return "<unknown>"
}
}
// NodeListStub is a subset of information returned during
// node list operations.
type NodeListStub struct {
Address string
ID string
Attributes map[string]string `json:",omitempty"`
Datacenter string
Name string
NodeClass string
Version string
Drain bool
SchedulingEligibility string
Status string
StatusDescription string
Drivers map[string]*DriverInfo
NodeResources *NodeResources `json:",omitempty"`
ReservedResources *NodeReservedResources `json:",omitempty"`
LastDrain *DrainMetadata
CreateIndex uint64
ModifyIndex uint64
}
// NodeIndexSort reverse sorts nodes by CreateIndex
type NodeIndexSort []*NodeListStub
func (n NodeIndexSort) Len() int {
return len(n)
}
func (n NodeIndexSort) Less(i, j int) bool {
return n[i].CreateIndex > n[j].CreateIndex
}
func (n NodeIndexSort) Swap(i, j int) {
n[i], n[j] = n[j], n[i]
}
// nodeEvalResponse is used to decode a force-eval.
type nodeEvalResponse struct {
EvalID string
}
// AllocationSort reverse sorts allocs by CreateIndex.
type AllocationSort []*Allocation
func (a AllocationSort) Len() int {
return len(a)
}
func (a AllocationSort) Less(i, j int) bool {
return a[i].CreateIndex > a[j].CreateIndex
}
func (a AllocationSort) Swap(i, j int) {
a[i], a[j] = a[j], a[i]
}