package nomad import ( "context" "fmt" "sort" "strings" "time" "github.com/armon/go-metrics" "github.com/golang/snappy" "github.com/hashicorp/consul/lib" memdb "github.com/hashicorp/go-memdb" "github.com/hashicorp/go-multierror" "github.com/hashicorp/nomad/acl" "github.com/hashicorp/nomad/client/driver" "github.com/hashicorp/nomad/helper" "github.com/hashicorp/nomad/nomad/state" "github.com/hashicorp/nomad/nomad/structs" "github.com/hashicorp/nomad/scheduler" ) const ( // RegisterEnforceIndexErrPrefix is the prefix to use in errors caused by // enforcing the job modify index during registers. RegisterEnforceIndexErrPrefix = "Enforcing job modify index" // DispatchPayloadSizeLimit is the maximum size of the uncompressed input // data payload. DispatchPayloadSizeLimit = 16 * 1024 ) var ( // vaultConstraint is the implicit constraint added to jobs requesting a // Vault token vaultConstraint = &structs.Constraint{ LTarget: "${attr.vault.version}", RTarget: ">= 0.6.1", Operand: structs.ConstraintVersion, } ) // Job endpoint is used for job interactions type Job struct { srv *Server } // Register is used to upsert a job for scheduling func (j *Job) Register(args *structs.JobRegisterRequest, reply *structs.JobRegisterResponse) error { if done, err := j.srv.forward("Job.Register", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "register"}, time.Now()) // Validate the arguments if args.Job == nil { return fmt.Errorf("missing job for registration") } // Initialize the job fields (sets defaults and any necessary init work). canonicalizeWarnings := args.Job.Canonicalize() // Add implicit constraints setImplicitConstraints(args.Job) // Validate the job and capture any warnings err, warnings := validateJob(args.Job) if err != nil { return err } // Set the warning message reply.Warnings = structs.MergeMultierrorWarnings(warnings, canonicalizeWarnings) // Check job submission permissions if aclObj, err := j.srv.resolveToken(args.SecretID); err != nil { return err } else if aclObj != nil { if !aclObj.AllowNsOp(structs.DefaultNamespace, acl.NamespaceCapabilitySubmitJob) { return structs.ErrPermissionDenied } // Check if override is set and we do not have permissions if args.PolicyOverride { if !aclObj.AllowNsOp(structs.DefaultNamespace, acl.NamespaceCapabilitySentinelOverride) { j.srv.logger.Printf("[WARN] nomad.job: policy override attempted without permissions for Job %q", args.Job.ID) return structs.ErrPermissionDenied } j.srv.logger.Printf("[WARN] nomad.job: policy override set for Job %q", args.Job.ID) } } // Lookup the job snap, err := j.srv.State().Snapshot() if err != nil { return err } ws := memdb.NewWatchSet() existingJob, err := snap.JobByID(ws, args.RequestNamespace(), args.Job.ID) if err != nil { return err } // If EnforceIndex set, check it before trying to apply if args.EnforceIndex { jmi := args.JobModifyIndex if existingJob != nil { if jmi == 0 { return fmt.Errorf("%s 0: job already exists", RegisterEnforceIndexErrPrefix) } else if jmi != existingJob.JobModifyIndex { return fmt.Errorf("%s %d: job exists with conflicting job modify index: %d", RegisterEnforceIndexErrPrefix, jmi, existingJob.JobModifyIndex) } } else if jmi != 0 { return fmt.Errorf("%s %d: job does not exist", RegisterEnforceIndexErrPrefix, jmi) } } // Validate job transitions if its an update if existingJob != nil { if err := validateJobUpdate(existingJob, args.Job); err != nil { return err } } // Ensure that the job has permissions for the requested Vault tokens policies := args.Job.VaultPolicies() if len(policies) != 0 { vconf := j.srv.config.VaultConfig if !vconf.IsEnabled() { return fmt.Errorf("Vault not enabled and Vault policies requested") } // Have to check if the user has permissions if !vconf.AllowsUnauthenticated() { if args.Job.VaultToken == "" { return fmt.Errorf("Vault policies requested but missing Vault Token") } vault := j.srv.vault s, err := vault.LookupToken(context.Background(), args.Job.VaultToken) if err != nil { return err } allowedPolicies, err := PoliciesFrom(s) if err != nil { return err } // If we are given a root token it can access all policies if !lib.StrContains(allowedPolicies, "root") { flatPolicies := structs.VaultPoliciesSet(policies) subset, offending := helper.SliceStringIsSubset(allowedPolicies, flatPolicies) if !subset { return fmt.Errorf("Passed Vault Token doesn't allow access to the following policies: %s", strings.Join(offending, ", ")) } } } } // Enforce Sentinel policies policyWarnings, err := j.enforceSubmitJob(args.PolicyOverride, args.Job) if err != nil { return err } if policyWarnings != nil { reply.Warnings = structs.MergeMultierrorWarnings(warnings, canonicalizeWarnings, policyWarnings) } // Clear the Vault token args.Job.VaultToken = "" // Check if the job has changed at all if existingJob == nil || existingJob.SpecChanged(args.Job) { // Set the submit time args.Job.SetSubmitTime() // Commit this update via Raft fsmErr, index, err := j.srv.raftApply(structs.JobRegisterRequestType, args) if err, ok := fsmErr.(error); ok && err != nil { j.srv.logger.Printf("[ERR] nomad.job: Register failed: %v", err) return err } if err != nil { j.srv.logger.Printf("[ERR] nomad.job: Register failed: %v", err) return err } // Populate the reply with job information reply.JobModifyIndex = index } else { reply.JobModifyIndex = existingJob.JobModifyIndex } // If the job is periodic or parameterized, we don't create an eval. if args.Job.IsPeriodic() || args.Job.IsParameterized() { return nil } // Create a new evaluation eval := &structs.Evaluation{ ID: structs.GenerateUUID(), Namespace: args.RequestNamespace(), Priority: args.Job.Priority, Type: args.Job.Type, TriggeredBy: structs.EvalTriggerJobRegister, JobID: args.Job.ID, JobModifyIndex: reply.JobModifyIndex, Status: structs.EvalStatusPending, } update := &structs.EvalUpdateRequest{ Evals: []*structs.Evaluation{eval}, WriteRequest: structs.WriteRequest{Region: args.Region}, } // Commit this evaluation via Raft // XXX: There is a risk of partial failure where the JobRegister succeeds // but that the EvalUpdate does not. _, evalIndex, err := j.srv.raftApply(structs.EvalUpdateRequestType, update) if err != nil { j.srv.logger.Printf("[ERR] nomad.job: Eval create failed: %v", err) return err } // Populate the reply with eval information reply.EvalID = eval.ID reply.EvalCreateIndex = evalIndex reply.Index = evalIndex return nil } // setImplicitConstraints adds implicit constraints to the job based on the // features it is requesting. func setImplicitConstraints(j *structs.Job) { // Get the required Vault Policies policies := j.VaultPolicies() // Get the required signals signals := j.RequiredSignals() // Hot path if len(signals) == 0 && len(policies) == 0 { return } // Add Vault constraints for _, tg := range j.TaskGroups { _, ok := policies[tg.Name] if !ok { // Not requesting Vault continue } found := false for _, c := range tg.Constraints { if c.Equal(vaultConstraint) { found = true break } } if !found { tg.Constraints = append(tg.Constraints, vaultConstraint) } } // Add signal constraints for _, tg := range j.TaskGroups { tgSignals, ok := signals[tg.Name] if !ok { // Not requesting Vault continue } // Flatten the signals required := helper.MapStringStringSliceValueSet(tgSignals) sigConstraint := getSignalConstraint(required) found := false for _, c := range tg.Constraints { if c.Equal(sigConstraint) { found = true break } } if !found { tg.Constraints = append(tg.Constraints, sigConstraint) } } } // getSignalConstraint builds a suitable constraint based on the required // signals func getSignalConstraint(signals []string) *structs.Constraint { return &structs.Constraint{ Operand: structs.ConstraintSetContains, LTarget: "${attr.os.signals}", RTarget: strings.Join(signals, ","), } } // Summary retreives the summary of a job func (j *Job) Summary(args *structs.JobSummaryRequest, reply *structs.JobSummaryResponse) error { if done, err := j.srv.forward("Job.Summary", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job_summary", "get_job_summary"}, time.Now()) // Check for read-job permissions if aclObj, err := j.srv.resolveToken(args.SecretID); err != nil { return err } else if aclObj != nil && !aclObj.AllowNsOp(args.RequestNamespace(), acl.NamespaceCapabilityReadJob) { return structs.ErrPermissionDenied } // Setup the blocking query opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, state *state.StateStore) error { // Look for job summary out, err := state.JobSummaryByID(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } // Setup the output reply.JobSummary = out if out != nil { reply.Index = out.ModifyIndex } else { // Use the last index that affected the job_summary table index, err := state.Index("job_summary") if err != nil { return err } reply.Index = index } // Set the query response j.srv.setQueryMeta(&reply.QueryMeta) return nil }} return j.srv.blockingRPC(&opts) } // Validate validates a job func (j *Job) Validate(args *structs.JobValidateRequest, reply *structs.JobValidateResponse) error { defer metrics.MeasureSince([]string{"nomad", "job", "validate"}, time.Now()) // Check for read-job permissions if aclObj, err := j.srv.resolveToken(args.SecretID); err != nil { return err } else if aclObj != nil && !aclObj.AllowNsOp(args.RequestNamespace(), acl.NamespaceCapabilityReadJob) { return structs.ErrPermissionDenied } // Initialize the job fields (sets defaults and any necessary init work). canonicalizeWarnings := args.Job.Canonicalize() // Add implicit constraints setImplicitConstraints(args.Job) // Validate the job and capture any warnings err, warnings := validateJob(args.Job) if err != nil { if merr, ok := err.(*multierror.Error); ok { for _, err := range merr.Errors { reply.ValidationErrors = append(reply.ValidationErrors, err.Error()) } reply.Error = merr.Error() } else { reply.ValidationErrors = append(reply.ValidationErrors, err.Error()) reply.Error = err.Error() } } // Set the warning message reply.Warnings = structs.MergeMultierrorWarnings(warnings, canonicalizeWarnings) reply.DriverConfigValidated = true return nil } // Revert is used to revert the job to a prior version func (j *Job) Revert(args *structs.JobRevertRequest, reply *structs.JobRegisterResponse) error { if done, err := j.srv.forward("Job.Revert", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "revert"}, time.Now()) // Validate the arguments if args.JobID == "" { return fmt.Errorf("missing job ID for revert") } // Lookup the job by version snap, err := j.srv.fsm.State().Snapshot() if err != nil { return err } ws := memdb.NewWatchSet() cur, err := snap.JobByID(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } if cur == nil { return fmt.Errorf("job %q not found", args.JobID) } if args.JobVersion == cur.Version { return fmt.Errorf("can't revert to current version") } jobV, err := snap.JobByIDAndVersion(ws, args.RequestNamespace(), args.JobID, args.JobVersion) if err != nil { return err } if jobV == nil { return fmt.Errorf("job %q in namespace %q at version %d not found", args.JobID, args.RequestNamespace(), args.JobVersion) } // Build the register request reg := &structs.JobRegisterRequest{ Job: jobV.Copy(), WriteRequest: args.WriteRequest, } // If the request is enforcing the existing version do a check. if args.EnforcePriorVersion != nil { if cur.Version != *args.EnforcePriorVersion { return fmt.Errorf("Current job has version %d; enforcing version %d", cur.Version, *args.EnforcePriorVersion) } reg.EnforceIndex = true reg.JobModifyIndex = cur.JobModifyIndex } // Register the version. return j.Register(reg, reply) } // Stable is used to mark the job version as stable func (j *Job) Stable(args *structs.JobStabilityRequest, reply *structs.JobStabilityResponse) error { if done, err := j.srv.forward("Job.Stable", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "stable"}, time.Now()) // Validate the arguments if args.JobID == "" { return fmt.Errorf("missing job ID for marking job as stable") } // Lookup the job by version snap, err := j.srv.fsm.State().Snapshot() if err != nil { return err } ws := memdb.NewWatchSet() jobV, err := snap.JobByIDAndVersion(ws, args.RequestNamespace(), args.JobID, args.JobVersion) if err != nil { return err } if jobV == nil { return fmt.Errorf("job %q in namespace %q at version %d not found", args.JobID, args.RequestNamespace(), args.JobVersion) } // Commit this stability request via Raft _, modifyIndex, err := j.srv.raftApply(structs.JobStabilityRequestType, args) if err != nil { j.srv.logger.Printf("[ERR] nomad.job: Job stability request failed: %v", err) return err } // Setup the reply reply.Index = modifyIndex return nil } // Evaluate is used to force a job for re-evaluation func (j *Job) Evaluate(args *structs.JobEvaluateRequest, reply *structs.JobRegisterResponse) error { if done, err := j.srv.forward("Job.Evaluate", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "evaluate"}, time.Now()) // Validate the arguments if args.JobID == "" { return fmt.Errorf("missing job ID for evaluation") } // Lookup the job snap, err := j.srv.fsm.State().Snapshot() if err != nil { return err } ws := memdb.NewWatchSet() job, err := snap.JobByID(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } if job == nil { return fmt.Errorf("job not found") } if job.IsPeriodic() { return fmt.Errorf("can't evaluate periodic job") } else if job.IsParameterized() { return fmt.Errorf("can't evaluate parameterized job") } // Create a new evaluation eval := &structs.Evaluation{ ID: structs.GenerateUUID(), Namespace: args.RequestNamespace(), Priority: job.Priority, Type: job.Type, TriggeredBy: structs.EvalTriggerJobRegister, JobID: job.ID, JobModifyIndex: job.ModifyIndex, Status: structs.EvalStatusPending, } update := &structs.EvalUpdateRequest{ Evals: []*structs.Evaluation{eval}, WriteRequest: structs.WriteRequest{Region: args.Region}, } // Commit this evaluation via Raft _, evalIndex, err := j.srv.raftApply(structs.EvalUpdateRequestType, update) if err != nil { j.srv.logger.Printf("[ERR] nomad.job: Eval create failed: %v", err) return err } // Setup the reply reply.EvalID = eval.ID reply.EvalCreateIndex = evalIndex reply.JobModifyIndex = job.ModifyIndex reply.Index = evalIndex return nil } // Deregister is used to remove a job the cluster. func (j *Job) Deregister(args *structs.JobDeregisterRequest, reply *structs.JobDeregisterResponse) error { if done, err := j.srv.forward("Job.Deregister", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "deregister"}, time.Now()) // Validate the arguments if args.JobID == "" { return fmt.Errorf("missing job ID for deregistering") } // Lookup the job snap, err := j.srv.fsm.State().Snapshot() if err != nil { return err } ws := memdb.NewWatchSet() job, err := snap.JobByID(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } // Commit this update via Raft _, index, err := j.srv.raftApply(structs.JobDeregisterRequestType, args) if err != nil { j.srv.logger.Printf("[ERR] nomad.job: Deregister failed: %v", err) return err } // Populate the reply with job information reply.JobModifyIndex = index // If the job is periodic or parameterized, we don't create an eval. if job != nil && (job.IsPeriodic() || job.IsParameterized()) { return nil } // Create a new evaluation // XXX: The job priority / type is strange for this, since it's not a high // priority even if the job was. The scheduler itself also doesn't matter, // since all should be able to handle deregistration in the same way. eval := &structs.Evaluation{ ID: structs.GenerateUUID(), Namespace: args.RequestNamespace(), Priority: structs.JobDefaultPriority, Type: structs.JobTypeService, TriggeredBy: structs.EvalTriggerJobDeregister, JobID: args.JobID, JobModifyIndex: index, Status: structs.EvalStatusPending, } update := &structs.EvalUpdateRequest{ Evals: []*structs.Evaluation{eval}, WriteRequest: structs.WriteRequest{Region: args.Region}, } // Commit this evaluation via Raft _, evalIndex, err := j.srv.raftApply(structs.EvalUpdateRequestType, update) if err != nil { j.srv.logger.Printf("[ERR] nomad.job: Eval create failed: %v", err) return err } // Populate the reply with eval information reply.EvalID = eval.ID reply.EvalCreateIndex = evalIndex reply.Index = evalIndex return nil } // GetJob is used to request information about a specific job func (j *Job) GetJob(args *structs.JobSpecificRequest, reply *structs.SingleJobResponse) error { if done, err := j.srv.forward("Job.GetJob", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "get_job"}, time.Now()) // Setup the blocking query opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, state *state.StateStore) error { // Look for the job out, err := state.JobByID(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } // Setup the output reply.Job = out if out != nil { reply.Index = out.ModifyIndex } else { // Use the last index that affected the nodes table index, err := state.Index("jobs") if err != nil { return err } reply.Index = index } // Set the query response j.srv.setQueryMeta(&reply.QueryMeta) return nil }} return j.srv.blockingRPC(&opts) } // GetJobVersions is used to retrieve all tracked versions of a job. func (j *Job) GetJobVersions(args *structs.JobVersionsRequest, reply *structs.JobVersionsResponse) error { if done, err := j.srv.forward("Job.GetJobVersions", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "get_job_versions"}, time.Now()) // Setup the blocking query opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, state *state.StateStore) error { // Look for the job out, err := state.JobVersionsByID(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } // Setup the output reply.Versions = out if len(out) != 0 { reply.Index = out[0].ModifyIndex // Compute the diffs if args.Diffs { for i := 0; i < len(out)-1; i++ { old, new := out[i+1], out[i] d, err := old.Diff(new, true) if err != nil { return fmt.Errorf("failed to create job diff: %v", err) } reply.Diffs = append(reply.Diffs, d) } } } else { // Use the last index that affected the nodes table index, err := state.Index("job_version") if err != nil { return err } reply.Index = index } // Set the query response j.srv.setQueryMeta(&reply.QueryMeta) return nil }} return j.srv.blockingRPC(&opts) } // List is used to list the jobs registered in the system func (j *Job) List(args *structs.JobListRequest, reply *structs.JobListResponse) error { if done, err := j.srv.forward("Job.List", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "list"}, time.Now()) // Check for list-job permissions if aclObj, err := j.srv.resolveToken(args.SecretID); err != nil { return err } else if aclObj != nil && !aclObj.AllowNsOp(args.RequestNamespace(), acl.NamespaceCapabilityListJobs) { return structs.ErrPermissionDenied } // Setup the blocking query opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, state *state.StateStore) error { // Capture all the jobs var err error var iter memdb.ResultIterator if prefix := args.QueryOptions.Prefix; prefix != "" { iter, err = state.JobsByIDPrefix(ws, args.RequestNamespace(), prefix) } else { iter, err = state.JobsByNamespace(ws, args.RequestNamespace()) } if err != nil { return err } var jobs []*structs.JobListStub for { raw := iter.Next() if raw == nil { break } job := raw.(*structs.Job) summary, err := state.JobSummaryByID(ws, args.RequestNamespace(), job.ID) if err != nil { return fmt.Errorf("unable to look up summary for job: %v", job.ID) } jobs = append(jobs, job.Stub(summary)) } reply.Jobs = jobs // Use the last index that affected the jobs table index, err := state.Index("jobs") if err != nil { return err } reply.Index = index // Set the query response j.srv.setQueryMeta(&reply.QueryMeta) return nil }} return j.srv.blockingRPC(&opts) } // Allocations is used to list the allocations for a job func (j *Job) Allocations(args *structs.JobSpecificRequest, reply *structs.JobAllocationsResponse) error { if done, err := j.srv.forward("Job.Allocations", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "allocations"}, time.Now()) // Setup the blocking query opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, state *state.StateStore) error { // Capture the allocations allocs, err := state.AllocsByJob(ws, args.RequestNamespace(), args.JobID, args.AllAllocs) if err != nil { return err } // Convert to stubs if len(allocs) > 0 { reply.Allocations = make([]*structs.AllocListStub, 0, len(allocs)) for _, alloc := range allocs { reply.Allocations = append(reply.Allocations, alloc.Stub()) } } // Use the last index that affected the allocs table index, err := state.Index("allocs") if err != nil { return err } reply.Index = index // Set the query response j.srv.setQueryMeta(&reply.QueryMeta) return nil }} return j.srv.blockingRPC(&opts) } // Evaluations is used to list the evaluations for a job func (j *Job) Evaluations(args *structs.JobSpecificRequest, reply *structs.JobEvaluationsResponse) error { if done, err := j.srv.forward("Job.Evaluations", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "evaluations"}, time.Now()) // Setup the blocking query opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, state *state.StateStore) error { // Capture the evals var err error reply.Evaluations, err = state.EvalsByJob(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } // Use the last index that affected the evals table index, err := state.Index("evals") if err != nil { return err } reply.Index = index // Set the query response j.srv.setQueryMeta(&reply.QueryMeta) return nil }} return j.srv.blockingRPC(&opts) } // Deployments is used to list the deployments for a job func (j *Job) Deployments(args *structs.JobSpecificRequest, reply *structs.DeploymentListResponse) error { if done, err := j.srv.forward("Job.Deployments", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "deployments"}, time.Now()) // Setup the blocking query opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, state *state.StateStore) error { // Capture the deployments deploys, err := state.DeploymentsByJobID(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } // Use the last index that affected the deployment table index, err := state.Index("deployment") if err != nil { return err } reply.Index = index reply.Deployments = deploys // Set the query response j.srv.setQueryMeta(&reply.QueryMeta) return nil }} return j.srv.blockingRPC(&opts) } // LatestDeployment is used to retrieve the latest deployment for a job func (j *Job) LatestDeployment(args *structs.JobSpecificRequest, reply *structs.SingleDeploymentResponse) error { if done, err := j.srv.forward("Job.LatestDeployment", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "latest_deployment"}, time.Now()) // Setup the blocking query opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, state *state.StateStore) error { // Capture the deployments deploys, err := state.DeploymentsByJobID(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } // Use the last index that affected the deployment table index, err := state.Index("deployment") if err != nil { return err } reply.Index = index if len(deploys) > 0 { sort.Slice(deploys, func(i, j int) bool { return deploys[i].CreateIndex > deploys[j].CreateIndex }) reply.Deployment = deploys[0] } // Set the query response j.srv.setQueryMeta(&reply.QueryMeta) return nil }} return j.srv.blockingRPC(&opts) } // Plan is used to cause a dry-run evaluation of the Job and return the results // with a potential diff containing annotations. func (j *Job) Plan(args *structs.JobPlanRequest, reply *structs.JobPlanResponse) error { if done, err := j.srv.forward("Job.Plan", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "plan"}, time.Now()) // Validate the arguments if args.Job == nil { return fmt.Errorf("Job required for plan") } // Initialize the job fields (sets defaults and any necessary init work). canonicalizeWarnings := args.Job.Canonicalize() // Add implicit constraints setImplicitConstraints(args.Job) // Validate the job and capture any warnings err, warnings := validateJob(args.Job) if err != nil { return err } // Set the warning message reply.Warnings = structs.MergeMultierrorWarnings(warnings, canonicalizeWarnings) // Check job submission permissions, which we assume is the same for plan if aclObj, err := j.srv.resolveToken(args.SecretID); err != nil { return err } else if aclObj != nil { if !aclObj.AllowNsOp(structs.DefaultNamespace, acl.NamespaceCapabilitySubmitJob) { return structs.ErrPermissionDenied } // Check if override is set and we do not have permissions if args.PolicyOverride { if !aclObj.AllowNsOp(structs.DefaultNamespace, acl.NamespaceCapabilitySentinelOverride) { return structs.ErrPermissionDenied } } } // Enforce Sentinel policies policyWarnings, err := j.enforceSubmitJob(args.PolicyOverride, args.Job) if err != nil { return err } if policyWarnings != nil { reply.Warnings = structs.MergeMultierrorWarnings(warnings, canonicalizeWarnings, policyWarnings) } // Acquire a snapshot of the state snap, err := j.srv.fsm.State().Snapshot() if err != nil { return err } // Get the original job ws := memdb.NewWatchSet() oldJob, err := snap.JobByID(ws, args.RequestNamespace(), args.Job.ID) if err != nil { return err } var index uint64 var updatedIndex uint64 if oldJob != nil { index = oldJob.JobModifyIndex // We want to reuse deployments where possible, so only insert the job if // it has changed or the job didn't exist if oldJob.SpecChanged(args.Job) { // Insert the updated Job into the snapshot updatedIndex = oldJob.JobModifyIndex + 1 snap.UpsertJob(updatedIndex, args.Job) } } else if oldJob == nil { // Insert the updated Job into the snapshot snap.UpsertJob(100, args.Job) } // Create an eval and mark it as requiring annotations and insert that as well eval := &structs.Evaluation{ ID: structs.GenerateUUID(), Namespace: args.RequestNamespace(), Priority: args.Job.Priority, Type: args.Job.Type, TriggeredBy: structs.EvalTriggerJobRegister, JobID: args.Job.ID, JobModifyIndex: updatedIndex, Status: structs.EvalStatusPending, AnnotatePlan: true, } // Create an in-memory Planner that returns no errors and stores the // submitted plan and created evals. planner := &scheduler.Harness{ State: &snap.StateStore, } // Create the scheduler and run it sched, err := scheduler.NewScheduler(eval.Type, j.srv.logger, snap, planner) if err != nil { return err } if err := sched.Process(eval); err != nil { return err } // Annotate and store the diff if plans := len(planner.Plans); plans != 1 { return fmt.Errorf("scheduler resulted in an unexpected number of plans: %v", plans) } annotations := planner.Plans[0].Annotations if args.Diff { jobDiff, err := oldJob.Diff(args.Job, true) if err != nil { return fmt.Errorf("failed to create job diff: %v", err) } if err := scheduler.Annotate(jobDiff, annotations); err != nil { return fmt.Errorf("failed to annotate job diff: %v", err) } reply.Diff = jobDiff } // Grab the failures if len(planner.Evals) != 1 { return fmt.Errorf("scheduler resulted in an unexpected number of eval updates: %v", planner.Evals) } updatedEval := planner.Evals[0] // If it is a periodic job calculate the next launch if args.Job.IsPeriodic() && args.Job.Periodic.Enabled { reply.NextPeriodicLaunch = args.Job.Periodic.Next(time.Now().In(args.Job.Periodic.GetLocation())) } reply.FailedTGAllocs = updatedEval.FailedTGAllocs reply.JobModifyIndex = index reply.Annotations = annotations reply.CreatedEvals = planner.CreateEvals reply.Index = index return nil } // validateJob validates a Job and task drivers and returns an error if there is // a validation problem or if the Job is of a type a user is not allowed to // submit. func validateJob(job *structs.Job) (invalid, warnings error) { validationErrors := new(multierror.Error) if err := job.Validate(); err != nil { multierror.Append(validationErrors, err) } // Get any warnings warnings = job.Warnings() // Get the signals required signals := job.RequiredSignals() // Validate the driver configurations. for _, tg := range job.TaskGroups { // Get the signals for the task group tgSignals, tgOk := signals[tg.Name] for _, task := range tg.Tasks { d, err := driver.NewDriver( task.Driver, driver.NewEmptyDriverContext(), ) if err != nil { msg := "failed to create driver for task %q in group %q for validation: %v" multierror.Append(validationErrors, fmt.Errorf(msg, tg.Name, task.Name, err)) continue } if err := d.Validate(task.Config); err != nil { formatted := fmt.Errorf("group %q -> task %q -> config: %v", tg.Name, task.Name, err) multierror.Append(validationErrors, formatted) } // The task group didn't have any task that required signals if !tgOk { continue } // This task requires signals. Ensure the driver is capable if required, ok := tgSignals[task.Name]; ok { abilities := d.Abilities() if !abilities.SendSignals { formatted := fmt.Errorf("group %q -> task %q: driver %q doesn't support sending signals. Requested signals are %v", tg.Name, task.Name, task.Driver, strings.Join(required, ", ")) multierror.Append(validationErrors, formatted) } } } } if job.Type == structs.JobTypeCore { multierror.Append(validationErrors, fmt.Errorf("job type cannot be core")) } if len(job.Payload) != 0 { multierror.Append(validationErrors, fmt.Errorf("job can't be submitted with a payload, only dispatched")) } return validationErrors.ErrorOrNil(), warnings } // validateJobUpdate ensures updates to a job are valid. func validateJobUpdate(old, new *structs.Job) error { // Type transitions are disallowed if old.Type != new.Type { return fmt.Errorf("cannot update job from type %q to %q", old.Type, new.Type) } // Transitioning to/from periodic is disallowed if old.IsPeriodic() && !new.IsPeriodic() { return fmt.Errorf("cannot update non-periodic job to being periodic") } if new.IsPeriodic() && !old.IsPeriodic() { return fmt.Errorf("cannot update periodic job to being non-periodic") } // Transitioning to/from parameterized is disallowed if old.IsParameterized() && !new.IsParameterized() { return fmt.Errorf("cannot update non-parameterized job to being parameterized") } if new.IsParameterized() && !old.IsParameterized() { return fmt.Errorf("cannot update parameterized job to being non-parameterized") } return nil } // Dispatch a parameterized job. func (j *Job) Dispatch(args *structs.JobDispatchRequest, reply *structs.JobDispatchResponse) error { if done, err := j.srv.forward("Job.Dispatch", args, args, reply); done { return err } defer metrics.MeasureSince([]string{"nomad", "job", "dispatch"}, time.Now()) // Lookup the parameterized job if args.JobID == "" { return fmt.Errorf("missing parameterized job ID") } snap, err := j.srv.fsm.State().Snapshot() if err != nil { return err } ws := memdb.NewWatchSet() parameterizedJob, err := snap.JobByID(ws, args.RequestNamespace(), args.JobID) if err != nil { return err } if parameterizedJob == nil { return fmt.Errorf("parameterized job not found") } if !parameterizedJob.IsParameterized() { return fmt.Errorf("Specified job %q is not a parameterized job", args.JobID) } if parameterizedJob.Stop { return fmt.Errorf("Specified job %q is stopped", args.JobID) } // Validate the arguments if err := validateDispatchRequest(args, parameterizedJob); err != nil { return err } // Derive the child job and commit it via Raft dispatchJob := parameterizedJob.Copy() dispatchJob.ParameterizedJob = nil dispatchJob.ID = structs.DispatchedID(parameterizedJob.ID, time.Now()) dispatchJob.ParentID = parameterizedJob.ID dispatchJob.Name = dispatchJob.ID dispatchJob.SetSubmitTime() // Merge in the meta data for k, v := range args.Meta { if dispatchJob.Meta == nil { dispatchJob.Meta = make(map[string]string, len(args.Meta)) } dispatchJob.Meta[k] = v } // Compress the payload dispatchJob.Payload = snappy.Encode(nil, args.Payload) regReq := &structs.JobRegisterRequest{ Job: dispatchJob, WriteRequest: args.WriteRequest, } // Commit this update via Raft fsmErr, jobCreateIndex, err := j.srv.raftApply(structs.JobRegisterRequestType, regReq) if err, ok := fsmErr.(error); ok && err != nil { j.srv.logger.Printf("[ERR] nomad.job: Dispatched job register failed: %v", err) return err } if err != nil { j.srv.logger.Printf("[ERR] nomad.job: Dispatched job register failed: %v", err) return err } reply.JobCreateIndex = jobCreateIndex reply.DispatchedJobID = dispatchJob.ID reply.Index = jobCreateIndex // If the job is periodic, we don't create an eval. if !dispatchJob.IsPeriodic() { // Create a new evaluation eval := &structs.Evaluation{ ID: structs.GenerateUUID(), Namespace: args.RequestNamespace(), Priority: dispatchJob.Priority, Type: dispatchJob.Type, TriggeredBy: structs.EvalTriggerJobRegister, JobID: dispatchJob.ID, JobModifyIndex: jobCreateIndex, Status: structs.EvalStatusPending, } update := &structs.EvalUpdateRequest{ Evals: []*structs.Evaluation{eval}, WriteRequest: structs.WriteRequest{Region: args.Region}, } // Commit this evaluation via Raft _, evalIndex, err := j.srv.raftApply(structs.EvalUpdateRequestType, update) if err != nil { j.srv.logger.Printf("[ERR] nomad.job: Eval create failed: %v", err) return err } // Setup the reply reply.EvalID = eval.ID reply.EvalCreateIndex = evalIndex reply.Index = evalIndex } return nil } // validateDispatchRequest returns whether the request is valid given the // parameterized job. func validateDispatchRequest(req *structs.JobDispatchRequest, job *structs.Job) error { // Check the payload constraint is met hasInputData := len(req.Payload) != 0 if job.ParameterizedJob.Payload == structs.DispatchPayloadRequired && !hasInputData { return fmt.Errorf("Payload is not provided but required by parameterized job") } else if job.ParameterizedJob.Payload == structs.DispatchPayloadForbidden && hasInputData { return fmt.Errorf("Payload provided but forbidden by parameterized job") } // Check the payload doesn't exceed the size limit if l := len(req.Payload); l > DispatchPayloadSizeLimit { return fmt.Errorf("Payload exceeds maximum size; %d > %d", l, DispatchPayloadSizeLimit) } // Check if the metadata is a set keys := make(map[string]struct{}, len(req.Meta)) for k := range keys { if _, ok := keys[k]; ok { return fmt.Errorf("Duplicate key %q in passed metadata", k) } keys[k] = struct{}{} } required := helper.SliceStringToSet(job.ParameterizedJob.MetaRequired) optional := helper.SliceStringToSet(job.ParameterizedJob.MetaOptional) // Check the metadata key constraints are met unpermitted := make(map[string]struct{}) for k := range req.Meta { _, req := required[k] _, opt := optional[k] if !req && !opt { unpermitted[k] = struct{}{} } } if len(unpermitted) != 0 { flat := make([]string, 0, len(unpermitted)) for k := range unpermitted { flat = append(flat, k) } return fmt.Errorf("Dispatch request included unpermitted metadata keys: %v", flat) } missing := make(map[string]struct{}) for _, k := range job.ParameterizedJob.MetaRequired { if _, ok := req.Meta[k]; !ok { missing[k] = struct{}{} } } if len(missing) != 0 { flat := make([]string, 0, len(missing)) for k := range missing { flat = append(flat, k) } return fmt.Errorf("Dispatch did not provide required meta keys: %v", flat) } return nil }