open-nomad/api/jobs.go
Tim Gross b77fe023b5
MRD: move 'job stop -global' handling into RPC (#8776)
The initial implementation of global job stop for MRD looped over all the
regions in the CLI for expedience. This changeset includes the OSS parts of
moving this into the RPC layer so that API consumers don't have to implement
this logic themselves.
2020-08-28 14:28:13 -04:00

1303 lines
33 KiB
Go

package api
import (
"fmt"
"net/url"
"sort"
"strconv"
"time"
"github.com/hashicorp/cronexpr"
)
const (
// JobTypeService indicates a long-running processes
JobTypeService = "service"
// JobTypeBatch indicates a short-lived process
JobTypeBatch = "batch"
// JobTypeSystem indicates a system process that should run on all clients
JobTypeSystem = "system"
// PeriodicSpecCron is used for a cron spec.
PeriodicSpecCron = "cron"
// DefaultNamespace is the default namespace.
DefaultNamespace = "default"
// For Job configuration, GlobalRegion is a sentinel region value
// that users may specify to indicate the job should be run on
// the region of the node that the job was submitted to.
// For Client configuration, if no region information is given,
// the client node will default to be part of the GlobalRegion.
GlobalRegion = "global"
)
const (
// RegisterEnforceIndexErrPrefix is the prefix to use in errors caused by
// enforcing the job modify index during registers.
RegisterEnforceIndexErrPrefix = "Enforcing job modify index"
)
// Jobs is used to access the job-specific endpoints.
type Jobs struct {
client *Client
}
// JobsParseRequest is used for arguments of the /v1/jobs/parse endpoint
type JobsParseRequest struct {
// JobHCL is an hcl jobspec
JobHCL string
// Canonicalize is a flag as to if the server should return default values
// for unset fields
Canonicalize bool
}
// Jobs returns a handle on the jobs endpoints.
func (c *Client) Jobs() *Jobs {
return &Jobs{client: c}
}
// ParseHCL is used to convert the HCL repesentation of a Job to JSON server side.
// To parse the HCL client side see package github.com/hashicorp/nomad/jobspec
func (j *Jobs) ParseHCL(jobHCL string, canonicalize bool) (*Job, error) {
var job Job
req := &JobsParseRequest{
JobHCL: jobHCL,
Canonicalize: canonicalize,
}
_, err := j.client.write("/v1/jobs/parse", req, &job, nil)
return &job, err
}
func (j *Jobs) Validate(job *Job, q *WriteOptions) (*JobValidateResponse, *WriteMeta, error) {
var resp JobValidateResponse
req := &JobValidateRequest{Job: job}
if q != nil {
req.WriteRequest = WriteRequest{Region: q.Region}
}
wm, err := j.client.write("/v1/validate/job", req, &resp, q)
return &resp, wm, err
}
// RegisterOptions is used to pass through job registration parameters
type RegisterOptions struct {
EnforceIndex bool
ModifyIndex uint64
PolicyOverride bool
PreserveCounts bool
}
// Register is used to register a new job. It returns the ID
// of the evaluation, along with any errors encountered.
func (j *Jobs) Register(job *Job, q *WriteOptions) (*JobRegisterResponse, *WriteMeta, error) {
return j.RegisterOpts(job, nil, q)
}
// EnforceRegister is used to register a job enforcing its job modify index.
func (j *Jobs) EnforceRegister(job *Job, modifyIndex uint64, q *WriteOptions) (*JobRegisterResponse, *WriteMeta, error) {
opts := RegisterOptions{EnforceIndex: true, ModifyIndex: modifyIndex}
return j.RegisterOpts(job, &opts, q)
}
// Register is used to register a new job. It returns the ID
// of the evaluation, along with any errors encountered.
func (j *Jobs) RegisterOpts(job *Job, opts *RegisterOptions, q *WriteOptions) (*JobRegisterResponse, *WriteMeta, error) {
// Format the request
req := &JobRegisterRequest{
Job: job,
}
if opts != nil {
if opts.EnforceIndex {
req.EnforceIndex = true
req.JobModifyIndex = opts.ModifyIndex
}
req.PolicyOverride = opts.PolicyOverride
req.PreserveCounts = opts.PreserveCounts
}
var resp JobRegisterResponse
wm, err := j.client.write("/v1/jobs", req, &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, wm, nil
}
// List is used to list all of the existing jobs.
func (j *Jobs) List(q *QueryOptions) ([]*JobListStub, *QueryMeta, error) {
var resp []*JobListStub
qm, err := j.client.query("/v1/jobs", &resp, q)
if err != nil {
return nil, qm, err
}
sort.Sort(JobIDSort(resp))
return resp, qm, nil
}
// PrefixList is used to list all existing jobs that match the prefix.
func (j *Jobs) PrefixList(prefix string) ([]*JobListStub, *QueryMeta, error) {
return j.List(&QueryOptions{Prefix: prefix})
}
// Info is used to retrieve information about a particular
// job given its unique ID.
func (j *Jobs) Info(jobID string, q *QueryOptions) (*Job, *QueryMeta, error) {
var resp Job
qm, err := j.client.query("/v1/job/"+url.PathEscape(jobID), &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, qm, nil
}
// Scale is used to retrieve information about a particular
// job given its unique ID.
func (j *Jobs) Scale(jobID, group string, count *int, message string, error bool, meta map[string]interface{},
q *WriteOptions) (*JobRegisterResponse, *WriteMeta, error) {
var count64 *int64
if count != nil {
count64 = int64ToPtr(int64(*count))
}
req := &ScalingRequest{
Count: count64,
Target: map[string]string{
"Job": jobID,
"Group": group,
},
Error: error,
Message: message,
Meta: meta,
}
var resp JobRegisterResponse
qm, err := j.client.write(fmt.Sprintf("/v1/job/%s/scale", url.PathEscape(jobID)), req, &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, qm, nil
}
// ScaleStatus is used to retrieve information about a particular
// job given its unique ID.
func (j *Jobs) ScaleStatus(jobID string, q *QueryOptions) (*JobScaleStatusResponse, *QueryMeta, error) {
var resp JobScaleStatusResponse
qm, err := j.client.query(fmt.Sprintf("/v1/job/%s/scale", url.PathEscape(jobID)), &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, qm, nil
}
// Versions is used to retrieve all versions of a particular job given its
// unique ID.
func (j *Jobs) Versions(jobID string, diffs bool, q *QueryOptions) ([]*Job, []*JobDiff, *QueryMeta, error) {
var resp JobVersionsResponse
qm, err := j.client.query(fmt.Sprintf("/v1/job/%s/versions?diffs=%v", url.PathEscape(jobID), diffs), &resp, q)
if err != nil {
return nil, nil, nil, err
}
return resp.Versions, resp.Diffs, qm, nil
}
// Allocations is used to return the allocs for a given job ID.
func (j *Jobs) Allocations(jobID string, allAllocs bool, q *QueryOptions) ([]*AllocationListStub, *QueryMeta, error) {
var resp []*AllocationListStub
u, err := url.Parse("/v1/job/" + url.PathEscape(jobID) + "/allocations")
if err != nil {
return nil, nil, err
}
v := u.Query()
v.Add("all", strconv.FormatBool(allAllocs))
u.RawQuery = v.Encode()
qm, err := j.client.query(u.String(), &resp, q)
if err != nil {
return nil, nil, err
}
sort.Sort(AllocIndexSort(resp))
return resp, qm, nil
}
// Deployments is used to query the deployments associated with the given job
// ID.
func (j *Jobs) Deployments(jobID string, all bool, q *QueryOptions) ([]*Deployment, *QueryMeta, error) {
var resp []*Deployment
u, err := url.Parse("/v1/job/" + url.PathEscape(jobID) + "/deployments")
if err != nil {
return nil, nil, err
}
v := u.Query()
v.Add("all", strconv.FormatBool(all))
u.RawQuery = v.Encode()
qm, err := j.client.query(u.String(), &resp, q)
if err != nil {
return nil, nil, err
}
sort.Sort(DeploymentIndexSort(resp))
return resp, qm, nil
}
// LatestDeployment is used to query for the latest deployment associated with
// the given job ID.
func (j *Jobs) LatestDeployment(jobID string, q *QueryOptions) (*Deployment, *QueryMeta, error) {
var resp *Deployment
qm, err := j.client.query("/v1/job/"+url.PathEscape(jobID)+"/deployment", &resp, q)
if err != nil {
return nil, nil, err
}
return resp, qm, nil
}
// Evaluations is used to query the evaluations associated with the given job
// ID.
func (j *Jobs) Evaluations(jobID string, q *QueryOptions) ([]*Evaluation, *QueryMeta, error) {
var resp []*Evaluation
qm, err := j.client.query("/v1/job/"+url.PathEscape(jobID)+"/evaluations", &resp, q)
if err != nil {
return nil, nil, err
}
sort.Sort(EvalIndexSort(resp))
return resp, qm, nil
}
// Deregister is used to remove an existing job. If purge is set to true, the job
// is deregistered and purged from the system versus still being queryable and
// eventually GC'ed from the system. Most callers should not specify purge.
func (j *Jobs) Deregister(jobID string, purge bool, q *WriteOptions) (string, *WriteMeta, error) {
var resp JobDeregisterResponse
wm, err := j.client.delete(fmt.Sprintf("/v1/job/%v?purge=%t", url.PathEscape(jobID), purge), &resp, q)
if err != nil {
return "", nil, err
}
return resp.EvalID, wm, nil
}
// DeregisterOptions is used to pass through job deregistration parameters
type DeregisterOptions struct {
// If Purge is set to true, the job is deregistered and purged from the
// system versus still being queryable and eventually GC'ed from the
// system. Most callers should not specify purge.
Purge bool
// If Global is set to true, all regions of a multiregion job will be
// stopped.
Global bool
}
// DeregisterOpts is used to remove an existing job. See DeregisterOptions
// for parameters.
func (j *Jobs) DeregisterOpts(jobID string, opts *DeregisterOptions, q *WriteOptions) (string, *WriteMeta, error) {
var resp JobDeregisterResponse
wm, err := j.client.delete(fmt.Sprintf("/v1/job/%v?purge=%t&global=%t",
url.PathEscape(jobID), opts.Purge, opts.Global), &resp, q)
if err != nil {
return "", nil, err
}
return resp.EvalID, wm, nil
}
// ForceEvaluate is used to force-evaluate an existing job.
func (j *Jobs) ForceEvaluate(jobID string, q *WriteOptions) (string, *WriteMeta, error) {
var resp JobRegisterResponse
wm, err := j.client.write("/v1/job/"+url.PathEscape(jobID)+"/evaluate", nil, &resp, q)
if err != nil {
return "", nil, err
}
return resp.EvalID, wm, nil
}
// EvaluateWithOpts is used to force-evaluate an existing job and takes additional options
// for whether to force reschedule failed allocations
func (j *Jobs) EvaluateWithOpts(jobID string, opts EvalOptions, q *WriteOptions) (string, *WriteMeta, error) {
req := &JobEvaluateRequest{
JobID: jobID,
EvalOptions: opts,
}
var resp JobRegisterResponse
wm, err := j.client.write("/v1/job/"+url.PathEscape(jobID)+"/evaluate", req, &resp, q)
if err != nil {
return "", nil, err
}
return resp.EvalID, wm, nil
}
// PeriodicForce spawns a new instance of the periodic job and returns the eval ID
func (j *Jobs) PeriodicForce(jobID string, q *WriteOptions) (string, *WriteMeta, error) {
var resp periodicForceResponse
wm, err := j.client.write("/v1/job/"+url.PathEscape(jobID)+"/periodic/force", nil, &resp, q)
if err != nil {
return "", nil, err
}
return resp.EvalID, wm, nil
}
// PlanOptions is used to pass through job planning parameters
type PlanOptions struct {
Diff bool
PolicyOverride bool
}
func (j *Jobs) Plan(job *Job, diff bool, q *WriteOptions) (*JobPlanResponse, *WriteMeta, error) {
opts := PlanOptions{Diff: diff}
return j.PlanOpts(job, &opts, q)
}
func (j *Jobs) PlanOpts(job *Job, opts *PlanOptions, q *WriteOptions) (*JobPlanResponse, *WriteMeta, error) {
if job == nil {
return nil, nil, fmt.Errorf("must pass non-nil job")
}
// Setup the request
req := &JobPlanRequest{
Job: job,
}
if opts != nil {
req.Diff = opts.Diff
req.PolicyOverride = opts.PolicyOverride
}
var resp JobPlanResponse
wm, err := j.client.write("/v1/job/"+url.PathEscape(*job.ID)+"/plan", req, &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, wm, nil
}
func (j *Jobs) Summary(jobID string, q *QueryOptions) (*JobSummary, *QueryMeta, error) {
var resp JobSummary
qm, err := j.client.query("/v1/job/"+url.PathEscape(jobID)+"/summary", &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, qm, nil
}
func (j *Jobs) Dispatch(jobID string, meta map[string]string,
payload []byte, q *WriteOptions) (*JobDispatchResponse, *WriteMeta, error) {
var resp JobDispatchResponse
req := &JobDispatchRequest{
JobID: jobID,
Meta: meta,
Payload: payload,
}
wm, err := j.client.write("/v1/job/"+url.PathEscape(jobID)+"/dispatch", req, &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, wm, nil
}
// Revert is used to revert the given job to the passed version. If
// enforceVersion is set, the job is only reverted if the current version is at
// the passed version.
func (j *Jobs) Revert(jobID string, version uint64, enforcePriorVersion *uint64,
q *WriteOptions, consulToken, vaultToken string) (*JobRegisterResponse, *WriteMeta, error) {
var resp JobRegisterResponse
req := &JobRevertRequest{
JobID: jobID,
JobVersion: version,
EnforcePriorVersion: enforcePriorVersion,
// ConsulToken: consulToken, // TODO(shoenig) enable!
VaultToken: vaultToken,
}
wm, err := j.client.write("/v1/job/"+url.PathEscape(jobID)+"/revert", req, &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, wm, nil
}
// Stable is used to mark a job version's stability.
func (j *Jobs) Stable(jobID string, version uint64, stable bool,
q *WriteOptions) (*JobStabilityResponse, *WriteMeta, error) {
var resp JobStabilityResponse
req := &JobStabilityRequest{
JobID: jobID,
JobVersion: version,
Stable: stable,
}
wm, err := j.client.write("/v1/job/"+url.PathEscape(jobID)+"/stable", req, &resp, q)
if err != nil {
return nil, nil, err
}
return &resp, wm, nil
}
// periodicForceResponse is used to deserialize a force response
type periodicForceResponse struct {
EvalID string
}
// UpdateStrategy defines a task groups update strategy.
type UpdateStrategy struct {
Stagger *time.Duration `mapstructure:"stagger"`
MaxParallel *int `mapstructure:"max_parallel"`
HealthCheck *string `mapstructure:"health_check"`
MinHealthyTime *time.Duration `mapstructure:"min_healthy_time"`
HealthyDeadline *time.Duration `mapstructure:"healthy_deadline"`
ProgressDeadline *time.Duration `mapstructure:"progress_deadline"`
Canary *int `mapstructure:"canary"`
AutoRevert *bool `mapstructure:"auto_revert"`
AutoPromote *bool `mapstructure:"auto_promote"`
}
// DefaultUpdateStrategy provides a baseline that can be used to upgrade
// jobs with the old policy or for populating field defaults.
func DefaultUpdateStrategy() *UpdateStrategy {
return &UpdateStrategy{
Stagger: timeToPtr(30 * time.Second),
MaxParallel: intToPtr(1),
HealthCheck: stringToPtr("checks"),
MinHealthyTime: timeToPtr(10 * time.Second),
HealthyDeadline: timeToPtr(5 * time.Minute),
ProgressDeadline: timeToPtr(10 * time.Minute),
AutoRevert: boolToPtr(false),
Canary: intToPtr(0),
AutoPromote: boolToPtr(false),
}
}
func (u *UpdateStrategy) Copy() *UpdateStrategy {
if u == nil {
return nil
}
copy := new(UpdateStrategy)
if u.Stagger != nil {
copy.Stagger = timeToPtr(*u.Stagger)
}
if u.MaxParallel != nil {
copy.MaxParallel = intToPtr(*u.MaxParallel)
}
if u.HealthCheck != nil {
copy.HealthCheck = stringToPtr(*u.HealthCheck)
}
if u.MinHealthyTime != nil {
copy.MinHealthyTime = timeToPtr(*u.MinHealthyTime)
}
if u.HealthyDeadline != nil {
copy.HealthyDeadline = timeToPtr(*u.HealthyDeadline)
}
if u.ProgressDeadline != nil {
copy.ProgressDeadline = timeToPtr(*u.ProgressDeadline)
}
if u.AutoRevert != nil {
copy.AutoRevert = boolToPtr(*u.AutoRevert)
}
if u.Canary != nil {
copy.Canary = intToPtr(*u.Canary)
}
if u.AutoPromote != nil {
copy.AutoPromote = boolToPtr(*u.AutoPromote)
}
return copy
}
func (u *UpdateStrategy) Merge(o *UpdateStrategy) {
if o == nil {
return
}
if o.Stagger != nil {
u.Stagger = timeToPtr(*o.Stagger)
}
if o.MaxParallel != nil {
u.MaxParallel = intToPtr(*o.MaxParallel)
}
if o.HealthCheck != nil {
u.HealthCheck = stringToPtr(*o.HealthCheck)
}
if o.MinHealthyTime != nil {
u.MinHealthyTime = timeToPtr(*o.MinHealthyTime)
}
if o.HealthyDeadline != nil {
u.HealthyDeadline = timeToPtr(*o.HealthyDeadline)
}
if o.ProgressDeadline != nil {
u.ProgressDeadline = timeToPtr(*o.ProgressDeadline)
}
if o.AutoRevert != nil {
u.AutoRevert = boolToPtr(*o.AutoRevert)
}
if o.Canary != nil {
u.Canary = intToPtr(*o.Canary)
}
if o.AutoPromote != nil {
u.AutoPromote = boolToPtr(*o.AutoPromote)
}
}
func (u *UpdateStrategy) Canonicalize() {
d := DefaultUpdateStrategy()
if u.MaxParallel == nil {
u.MaxParallel = d.MaxParallel
}
if u.Stagger == nil {
u.Stagger = d.Stagger
}
if u.HealthCheck == nil {
u.HealthCheck = d.HealthCheck
}
if u.HealthyDeadline == nil {
u.HealthyDeadline = d.HealthyDeadline
}
if u.ProgressDeadline == nil {
u.ProgressDeadline = d.ProgressDeadline
}
if u.MinHealthyTime == nil {
u.MinHealthyTime = d.MinHealthyTime
}
if u.AutoRevert == nil {
u.AutoRevert = d.AutoRevert
}
if u.Canary == nil {
u.Canary = d.Canary
}
if u.AutoPromote == nil {
u.AutoPromote = d.AutoPromote
}
}
// Empty returns whether the UpdateStrategy is empty or has user defined values.
func (u *UpdateStrategy) Empty() bool {
if u == nil {
return true
}
if u.Stagger != nil && *u.Stagger != 0 {
return false
}
if u.MaxParallel != nil && *u.MaxParallel != 0 {
return false
}
if u.HealthCheck != nil && *u.HealthCheck != "" {
return false
}
if u.MinHealthyTime != nil && *u.MinHealthyTime != 0 {
return false
}
if u.HealthyDeadline != nil && *u.HealthyDeadline != 0 {
return false
}
if u.ProgressDeadline != nil && *u.ProgressDeadline != 0 {
return false
}
if u.AutoRevert != nil && *u.AutoRevert {
return false
}
if u.AutoPromote != nil && *u.AutoPromote {
return false
}
if u.Canary != nil && *u.Canary != 0 {
return false
}
return true
}
type Multiregion struct {
Strategy *MultiregionStrategy
Regions []*MultiregionRegion
}
func (m *Multiregion) Canonicalize() {
if m.Strategy == nil {
m.Strategy = &MultiregionStrategy{
MaxParallel: intToPtr(0),
OnFailure: stringToPtr(""),
}
} else {
if m.Strategy.MaxParallel == nil {
m.Strategy.MaxParallel = intToPtr(0)
}
if m.Strategy.OnFailure == nil {
m.Strategy.OnFailure = stringToPtr("")
}
}
if m.Regions == nil {
m.Regions = []*MultiregionRegion{}
}
for _, region := range m.Regions {
if region.Count == nil {
region.Count = intToPtr(1)
}
if region.Datacenters == nil {
region.Datacenters = []string{}
}
if region.Meta == nil {
region.Meta = map[string]string{}
}
}
}
func (m *Multiregion) Copy() *Multiregion {
if m == nil {
return nil
}
copy := new(Multiregion)
if m.Strategy != nil {
copy.Strategy = new(MultiregionStrategy)
copy.Strategy.MaxParallel = intToPtr(*m.Strategy.MaxParallel)
copy.Strategy.OnFailure = stringToPtr(*m.Strategy.OnFailure)
}
for _, region := range m.Regions {
copyRegion := new(MultiregionRegion)
copyRegion.Name = region.Name
copyRegion.Count = intToPtr(*region.Count)
for _, dc := range region.Datacenters {
copyRegion.Datacenters = append(copyRegion.Datacenters, dc)
}
for k, v := range region.Meta {
copyRegion.Meta[k] = v
}
copy.Regions = append(copy.Regions, copyRegion)
}
return copy
}
type MultiregionStrategy struct {
MaxParallel *int `mapstructure:"max_parallel"`
OnFailure *string `mapstructure:"on_failure"`
}
type MultiregionRegion struct {
Name string
Count *int
Datacenters []string
Meta map[string]string
}
// PeriodicConfig is for serializing periodic config for a job.
type PeriodicConfig struct {
Enabled *bool
Spec *string
SpecType *string
ProhibitOverlap *bool `mapstructure:"prohibit_overlap"`
TimeZone *string `mapstructure:"time_zone"`
}
func (p *PeriodicConfig) Canonicalize() {
if p.Enabled == nil {
p.Enabled = boolToPtr(true)
}
if p.Spec == nil {
p.Spec = stringToPtr("")
}
if p.SpecType == nil {
p.SpecType = stringToPtr(PeriodicSpecCron)
}
if p.ProhibitOverlap == nil {
p.ProhibitOverlap = boolToPtr(false)
}
if p.TimeZone == nil || *p.TimeZone == "" {
p.TimeZone = stringToPtr("UTC")
}
}
// Next returns the closest time instant matching the spec that is after the
// passed time. If no matching instance exists, the zero value of time.Time is
// returned. The `time.Location` of the returned value matches that of the
// passed time.
func (p *PeriodicConfig) Next(fromTime time.Time) (time.Time, error) {
if *p.SpecType == PeriodicSpecCron {
e, err := cronexpr.Parse(*p.Spec)
if err != nil {
return time.Time{}, fmt.Errorf("failed parsing cron expression %q: %v", *p.Spec, err)
}
return cronParseNext(e, fromTime, *p.Spec)
}
return time.Time{}, nil
}
// cronParseNext is a helper that parses the next time for the given expression
// but captures any panic that may occur in the underlying library.
// --- THIS FUNCTION IS REPLICATED IN nomad/structs/structs.go
// and should be kept in sync.
func cronParseNext(e *cronexpr.Expression, fromTime time.Time, spec string) (t time.Time, err error) {
defer func() {
if recover() != nil {
t = time.Time{}
err = fmt.Errorf("failed parsing cron expression: %q", spec)
}
}()
return e.Next(fromTime), nil
}
func (p *PeriodicConfig) GetLocation() (*time.Location, error) {
if p.TimeZone == nil || *p.TimeZone == "" {
return time.UTC, nil
}
return time.LoadLocation(*p.TimeZone)
}
// ParameterizedJobConfig is used to configure the parameterized job.
type ParameterizedJobConfig struct {
Payload string
MetaRequired []string `mapstructure:"meta_required"`
MetaOptional []string `mapstructure:"meta_optional"`
}
// Job is used to serialize a job.
type Job struct {
Stop *bool
Region *string
Namespace *string
ID *string
ParentID *string
Name *string
Type *string
Priority *int
AllAtOnce *bool `mapstructure:"all_at_once"`
Datacenters []string
Constraints []*Constraint
Affinities []*Affinity
TaskGroups []*TaskGroup
Update *UpdateStrategy
Multiregion *Multiregion
Spreads []*Spread
Periodic *PeriodicConfig
ParameterizedJob *ParameterizedJobConfig
Dispatched bool
Payload []byte
Reschedule *ReschedulePolicy
Migrate *MigrateStrategy
Meta map[string]string
ConsulToken *string `mapstructure:"consul_token"`
VaultToken *string `mapstructure:"vault_token"`
VaultNamespace *string `mapstructure:"vault_namespace"`
NomadTokenID *string `mapstructure:"nomad_token_id"`
Status *string
StatusDescription *string
Stable *bool
Version *uint64
SubmitTime *int64
CreateIndex *uint64
ModifyIndex *uint64
JobModifyIndex *uint64
}
// IsPeriodic returns whether a job is periodic.
func (j *Job) IsPeriodic() bool {
return j.Periodic != nil
}
// IsParameterized returns whether a job is parameterized job.
func (j *Job) IsParameterized() bool {
return j.ParameterizedJob != nil && !j.Dispatched
}
// IsMultiregion returns whether a job is a multiregion job
func (j *Job) IsMultiregion() bool {
return j.Multiregion != nil && j.Multiregion.Regions != nil && len(j.Multiregion.Regions) > 0
}
func (j *Job) Canonicalize() {
if j.ID == nil {
j.ID = stringToPtr("")
}
if j.Name == nil {
j.Name = stringToPtr(*j.ID)
}
if j.ParentID == nil {
j.ParentID = stringToPtr("")
}
if j.Namespace == nil {
j.Namespace = stringToPtr(DefaultNamespace)
}
if j.Priority == nil {
j.Priority = intToPtr(50)
}
if j.Stop == nil {
j.Stop = boolToPtr(false)
}
if j.Region == nil {
j.Region = stringToPtr(GlobalRegion)
}
if j.Namespace == nil {
j.Namespace = stringToPtr("default")
}
if j.Type == nil {
j.Type = stringToPtr("service")
}
if j.AllAtOnce == nil {
j.AllAtOnce = boolToPtr(false)
}
if j.ConsulToken == nil {
j.ConsulToken = stringToPtr("")
}
if j.VaultToken == nil {
j.VaultToken = stringToPtr("")
}
if j.VaultNamespace == nil {
j.VaultNamespace = stringToPtr("")
}
if j.NomadTokenID == nil {
j.NomadTokenID = stringToPtr("")
}
if j.Status == nil {
j.Status = stringToPtr("")
}
if j.StatusDescription == nil {
j.StatusDescription = stringToPtr("")
}
if j.Stable == nil {
j.Stable = boolToPtr(false)
}
if j.Version == nil {
j.Version = uint64ToPtr(0)
}
if j.CreateIndex == nil {
j.CreateIndex = uint64ToPtr(0)
}
if j.ModifyIndex == nil {
j.ModifyIndex = uint64ToPtr(0)
}
if j.JobModifyIndex == nil {
j.JobModifyIndex = uint64ToPtr(0)
}
if j.Periodic != nil {
j.Periodic.Canonicalize()
}
if j.Update != nil {
j.Update.Canonicalize()
} else if *j.Type == JobTypeService {
j.Update = DefaultUpdateStrategy()
}
if j.Multiregion != nil {
j.Multiregion.Canonicalize()
}
for _, tg := range j.TaskGroups {
tg.Canonicalize(j)
}
for _, spread := range j.Spreads {
spread.Canonicalize()
}
for _, a := range j.Affinities {
a.Canonicalize()
}
}
// LookupTaskGroup finds a task group by name
func (j *Job) LookupTaskGroup(name string) *TaskGroup {
for _, tg := range j.TaskGroups {
if *tg.Name == name {
return tg
}
}
return nil
}
// JobSummary summarizes the state of the allocations of a job
type JobSummary struct {
JobID string
Namespace string
Summary map[string]TaskGroupSummary
Children *JobChildrenSummary
// Raft Indexes
CreateIndex uint64
ModifyIndex uint64
}
// JobChildrenSummary contains the summary of children job status
type JobChildrenSummary struct {
Pending int64
Running int64
Dead int64
}
func (jc *JobChildrenSummary) Sum() int {
if jc == nil {
return 0
}
return int(jc.Pending + jc.Running + jc.Dead)
}
// TaskGroup summarizes the state of all the allocations of a particular
// TaskGroup
type TaskGroupSummary struct {
Queued int
Complete int
Failed int
Running int
Starting int
Lost int
}
// JobListStub is used to return a subset of information about
// jobs during list operations.
type JobListStub struct {
ID string
ParentID string
Name string
Namespace string `json:",omitempty"`
Datacenters []string
Type string
Priority int
Periodic bool
ParameterizedJob bool
Stop bool
Status string
StatusDescription string
JobSummary *JobSummary
CreateIndex uint64
ModifyIndex uint64
JobModifyIndex uint64
SubmitTime int64
}
// JobIDSort is used to sort jobs by their job ID's.
type JobIDSort []*JobListStub
func (j JobIDSort) Len() int {
return len(j)
}
func (j JobIDSort) Less(a, b int) bool {
return j[a].ID < j[b].ID
}
func (j JobIDSort) Swap(a, b int) {
j[a], j[b] = j[b], j[a]
}
// NewServiceJob creates and returns a new service-style job
// for long-lived processes using the provided name, ID, and
// relative job priority.
func NewServiceJob(id, name, region string, pri int) *Job {
return newJob(id, name, region, JobTypeService, pri)
}
// NewBatchJob creates and returns a new batch-style job for
// short-lived processes using the provided name and ID along
// with the relative job priority.
func NewBatchJob(id, name, region string, pri int) *Job {
return newJob(id, name, region, JobTypeBatch, pri)
}
// newJob is used to create a new Job struct.
func newJob(id, name, region, typ string, pri int) *Job {
return &Job{
Region: &region,
ID: &id,
Name: &name,
Type: &typ,
Priority: &pri,
}
}
// SetMeta is used to set arbitrary k/v pairs of metadata on a job.
func (j *Job) SetMeta(key, val string) *Job {
if j.Meta == nil {
j.Meta = make(map[string]string)
}
j.Meta[key] = val
return j
}
// AddDatacenter is used to add a datacenter to a job.
func (j *Job) AddDatacenter(dc string) *Job {
j.Datacenters = append(j.Datacenters, dc)
return j
}
// Constrain is used to add a constraint to a job.
func (j *Job) Constrain(c *Constraint) *Job {
j.Constraints = append(j.Constraints, c)
return j
}
// AddAffinity is used to add an affinity to a job.
func (j *Job) AddAffinity(a *Affinity) *Job {
j.Affinities = append(j.Affinities, a)
return j
}
// AddTaskGroup adds a task group to an existing job.
func (j *Job) AddTaskGroup(grp *TaskGroup) *Job {
j.TaskGroups = append(j.TaskGroups, grp)
return j
}
// AddPeriodicConfig adds a periodic config to an existing job.
func (j *Job) AddPeriodicConfig(cfg *PeriodicConfig) *Job {
j.Periodic = cfg
return j
}
func (j *Job) AddSpread(s *Spread) *Job {
j.Spreads = append(j.Spreads, s)
return j
}
type WriteRequest struct {
// The target region for this write
Region string
// Namespace is the target namespace for this write
Namespace string
// SecretID is the secret ID of an ACL token
SecretID string
}
// JobValidateRequest is used to validate a job
type JobValidateRequest struct {
Job *Job
WriteRequest
}
// JobValidateResponse is the response from validate request
type JobValidateResponse struct {
// DriverConfigValidated indicates whether the agent validated the driver
// config
DriverConfigValidated bool
// ValidationErrors is a list of validation errors
ValidationErrors []string
// Error is a string version of any error that may have occurred
Error string
// Warnings contains any warnings about the given job. These may include
// deprecation warnings.
Warnings string
}
// JobRevertRequest is used to revert a job to a prior version.
type JobRevertRequest struct {
// JobID is the ID of the job being reverted
JobID string
// JobVersion the version to revert to.
JobVersion uint64
// EnforcePriorVersion if set will enforce that the job is at the given
// version before reverting.
EnforcePriorVersion *uint64
// ConsulToken is the Consul token that proves the submitter of the job revert
// has access to the Service Identity policies associated with the job's
// Consul Connect enabled services. This field is only used to transfer the
// token and is not stored after the Job revert.
ConsulToken string `json:",omitempty"`
// VaultToken is the Vault token that proves the submitter of the job revert
// has access to any Vault policies specified in the targeted job version. This
// field is only used to authorize the revert and is not stored after the Job
// revert.
VaultToken string `json:",omitempty"`
WriteRequest
}
// JobRegisterRequest is used to update a job
type JobRegisterRequest struct {
Job *Job
// If EnforceIndex is set then the job will only be registered if the passed
// JobModifyIndex matches the current Jobs index. If the index is zero, the
// register only occurs if the job is new.
EnforceIndex bool `json:",omitempty"`
JobModifyIndex uint64 `json:",omitempty"`
PolicyOverride bool `json:",omitempty"`
PreserveCounts bool `json:",omitempty"`
WriteRequest
}
// JobRegisterResponse is used to respond to a job registration
type JobRegisterResponse struct {
EvalID string
EvalCreateIndex uint64
JobModifyIndex uint64
// Warnings contains any warnings about the given job. These may include
// deprecation warnings.
Warnings string
QueryMeta
}
// JobDeregisterResponse is used to respond to a job deregistration
type JobDeregisterResponse struct {
EvalID string
EvalCreateIndex uint64
JobModifyIndex uint64
QueryMeta
}
type JobPlanRequest struct {
Job *Job
Diff bool
PolicyOverride bool
WriteRequest
}
type JobPlanResponse struct {
JobModifyIndex uint64
CreatedEvals []*Evaluation
Diff *JobDiff
Annotations *PlanAnnotations
FailedTGAllocs map[string]*AllocationMetric
NextPeriodicLaunch time.Time
// Warnings contains any warnings about the given job. These may include
// deprecation warnings.
Warnings string
}
type JobDiff struct {
Type string
ID string
Fields []*FieldDiff
Objects []*ObjectDiff
TaskGroups []*TaskGroupDiff
}
type TaskGroupDiff struct {
Type string
Name string
Fields []*FieldDiff
Objects []*ObjectDiff
Tasks []*TaskDiff
Updates map[string]uint64
}
type TaskDiff struct {
Type string
Name string
Fields []*FieldDiff
Objects []*ObjectDiff
Annotations []string
}
type FieldDiff struct {
Type string
Name string
Old, New string
Annotations []string
}
type ObjectDiff struct {
Type string
Name string
Fields []*FieldDiff
Objects []*ObjectDiff
}
type PlanAnnotations struct {
DesiredTGUpdates map[string]*DesiredUpdates
PreemptedAllocs []*AllocationListStub
}
type DesiredUpdates struct {
Ignore uint64
Place uint64
Migrate uint64
Stop uint64
InPlaceUpdate uint64
DestructiveUpdate uint64
Canary uint64
Preemptions uint64
}
type JobDispatchRequest struct {
JobID string
Payload []byte
Meta map[string]string
}
type JobDispatchResponse struct {
DispatchedJobID string
EvalID string
EvalCreateIndex uint64
JobCreateIndex uint64
WriteMeta
}
// JobVersionsResponse is used for a job get versions request
type JobVersionsResponse struct {
Versions []*Job
Diffs []*JobDiff
QueryMeta
}
// JobStabilityRequest is used to marked a job as stable.
type JobStabilityRequest struct {
// Job to set the stability on
JobID string
JobVersion uint64
// Set the stability
Stable bool
WriteRequest
}
// JobStabilityResponse is the response when marking a job as stable.
type JobStabilityResponse struct {
JobModifyIndex uint64
WriteMeta
}
// JobEvaluateRequest is used when we just need to re-evaluate a target job
type JobEvaluateRequest struct {
JobID string
EvalOptions EvalOptions
WriteRequest
}
// EvalOptions is used to encapsulate options when forcing a job evaluation
type EvalOptions struct {
ForceReschedule bool
}