// Copyright (c) HashiCorp, Inc. // SPDX-License-Identifier: MPL-2.0 package nomad import ( "errors" "fmt" "net/http" "time" "github.com/armon/go-metrics" "github.com/hashicorp/go-bexpr" "github.com/hashicorp/go-hclog" "github.com/hashicorp/go-memdb" "github.com/hashicorp/go-multierror" "github.com/hashicorp/go-version" "github.com/hashicorp/nomad/acl" "github.com/hashicorp/nomad/nomad/state" "github.com/hashicorp/nomad/nomad/state/paginator" "github.com/hashicorp/nomad/nomad/structs" "github.com/hashicorp/nomad/scheduler" ) const ( // DefaultDequeueTimeout is used if no dequeue timeout is provided DefaultDequeueTimeout = time.Second ) var minVersionEvalDeleteByFilter = version.Must(version.NewVersion("1.4.3")) // Eval endpoint is used for eval interactions type Eval struct { srv *Server ctx *RPCContext logger hclog.Logger } func NewEvalEndpoint(srv *Server, ctx *RPCContext) *Eval { return &Eval{srv: srv, ctx: ctx, logger: srv.logger.Named("eval")} } // GetEval is used to request information about a specific evaluation func (e *Eval) GetEval(args *structs.EvalSpecificRequest, reply *structs.SingleEvalResponse) error { authErr := e.srv.Authenticate(e.ctx, args) if done, err := e.srv.forward("Eval.GetEval", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricRead, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "get_eval"}, time.Now()) // Check for read-job permissions before performing blocking query. allowNsOp := acl.NamespaceValidator(acl.NamespaceCapabilityReadJob) aclObj, err := e.srv.ResolveACL(args) if err != nil { return err } else if !allowNsOp(aclObj, args.RequestNamespace()) { return structs.ErrPermissionDenied } // Setup the blocking query opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, state *state.StateStore) error { var related []*structs.EvaluationStub // Look for the eval eval, err := state.EvalByID(ws, args.EvalID) if err != nil { return fmt.Errorf("failed to lookup eval: %v", err) } if eval != nil { // Re-check namespace in case it differs from request. if !allowNsOp(aclObj, eval.Namespace) { return structs.ErrPermissionDenied } // Lookup related evals if requested. if args.IncludeRelated { related, err = state.EvalsRelatedToID(ws, eval.ID) if err != nil { return fmt.Errorf("failed to lookup related evals: %v", err) } // Use a copy to avoid modifying the original eval. eval = eval.Copy() eval.RelatedEvals = related } } // Setup the output. reply.Eval = eval if eval != nil { reply.Index = eval.ModifyIndex } else { // 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 e.srv.setQueryMeta(&reply.QueryMeta) return nil }} return e.srv.blockingRPC(&opts) } // Dequeue is used to dequeue a pending evaluation func (e *Eval) Dequeue(args *structs.EvalDequeueRequest, reply *structs.EvalDequeueResponse) error { authErr := e.srv.Authenticate(e.ctx, args) // Ensure the connection was initiated by another server if TLS is used. err := validateTLSCertificateLevel(e.srv, e.ctx, tlsCertificateLevelServer) if err != nil { return err } if done, err := e.srv.forward("Eval.Dequeue", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricWrite, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "dequeue"}, time.Now()) // Ensure there is at least one scheduler if len(args.Schedulers) == 0 { return fmt.Errorf("dequeue requires at least one scheduler type") } // Check that there isn't a scheduler version mismatch if args.SchedulerVersion != scheduler.SchedulerVersion { return fmt.Errorf("dequeue disallowed: calling scheduler version is %d; leader version is %d", args.SchedulerVersion, scheduler.SchedulerVersion) } // Ensure there is a default timeout if args.Timeout <= 0 { args.Timeout = DefaultDequeueTimeout } // If the eval broker is paused, attempt to block and wait for a state // change before returning. This avoids a tight loop and mimics the // behaviour where there are no evals to process. // // The call can return because either the timeout is reached or the broker // SetEnabled function was called to modify its state. It is possible this // is because of leadership transition, therefore the RPC should exit to // allow all safety checks and RPC forwarding to occur again. // // The log line is trace, because the default worker timeout is 500ms which // produces a large amount of logging. if !e.srv.evalBroker.Enabled() { message := e.srv.evalBroker.enabledNotifier.WaitForChange(args.Timeout) e.logger.Trace("eval broker wait for un-pause", "message", message) return nil } // Attempt the dequeue eval, token, err := e.srv.evalBroker.Dequeue(args.Schedulers, args.Timeout) if err != nil { return err } // Provide the output if any if eval != nil { // Get the index that the worker should wait until before scheduling. waitIndex, err := e.getWaitIndex(eval.Namespace, eval.JobID, eval.ModifyIndex) if err != nil { var mErr multierror.Error _ = multierror.Append(&mErr, err) // We have dequeued the evaluation but won't be returning it to the // worker so Nack the eval. if err := e.srv.evalBroker.Nack(eval.ID, token); err != nil { _ = multierror.Append(&mErr, err) } return &mErr } reply.Eval = eval reply.Token = token reply.WaitIndex = waitIndex } // Set the query response e.srv.setQueryMeta(&reply.QueryMeta) return nil } // getWaitIndex returns the wait index that should be used by the worker before // invoking the scheduler. The index should be the highest modify index of any // evaluation for the job. This prevents scheduling races for the same job when // there are blocked evaluations. func (e *Eval) getWaitIndex(namespace, job string, evalModifyIndex uint64) (uint64, error) { snap, err := e.srv.State().Snapshot() if err != nil { return 0, err } evals, err := snap.EvalsByJob(nil, namespace, job) if err != nil { return 0, err } // Since dequeueing evals is concurrent with applying Raft messages to // the state store, initialize to the currently dequeued eval's index // in case it isn't in the snapshot used by EvalsByJob yet. max := evalModifyIndex for _, eval := range evals { if max < eval.ModifyIndex { max = eval.ModifyIndex } } return max, nil } // Ack is used to acknowledge completion of a dequeued evaluation func (e *Eval) Ack(args *structs.EvalAckRequest, reply *structs.GenericResponse) error { authErr := e.srv.Authenticate(e.ctx, args) // Ensure the connection was initiated by another server if TLS is used. err := validateTLSCertificateLevel(e.srv, e.ctx, tlsCertificateLevelServer) if err != nil { return err } if done, err := e.srv.forward("Eval.Ack", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricWrite, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "ack"}, time.Now()) // Ack the EvalID if err := e.srv.evalBroker.Ack(args.EvalID, args.Token); err != nil { return err } // Wake up the eval cancelation reaper. This never blocks; if the buffer is // full we know it's going to get picked up by the reaper so we don't need // another send on that channel. select { case e.srv.reapCancelableEvalsCh <- struct{}{}: default: } return nil } // Nack is used to negative acknowledge completion of a dequeued evaluation. func (e *Eval) Nack(args *structs.EvalAckRequest, reply *structs.GenericResponse) error { authErr := e.srv.Authenticate(e.ctx, args) // Ensure the connection was initiated by another server if TLS is used. err := validateTLSCertificateLevel(e.srv, e.ctx, tlsCertificateLevelServer) if err != nil { return err } if done, err := e.srv.forward("Eval.Nack", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricWrite, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "nack"}, time.Now()) // Nack the EvalID if err := e.srv.evalBroker.Nack(args.EvalID, args.Token); err != nil { return err } return nil } // Update is used to perform an update of an Eval if it is outstanding. func (e *Eval) Update(args *structs.EvalUpdateRequest, reply *structs.GenericResponse) error { authErr := e.srv.Authenticate(e.ctx, args) // Ensure the connection was initiated by another server if TLS is used. err := validateTLSCertificateLevel(e.srv, e.ctx, tlsCertificateLevelServer) if err != nil { return err } if done, err := e.srv.forward("Eval.Update", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricWrite, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "update"}, time.Now()) // Ensure there is only a single update with token if len(args.Evals) != 1 { return fmt.Errorf("only a single eval can be updated") } eval := args.Evals[0] // Verify the evaluation is outstanding, and that the tokens match. if err := e.srv.evalBroker.OutstandingReset(eval.ID, args.EvalToken); err != nil { return err } // Update via Raft _, index, err := e.srv.raftApply(structs.EvalUpdateRequestType, args) if err != nil { return err } // Update the index reply.Index = index return nil } // Create is used to make a new evaluation func (e *Eval) Create(args *structs.EvalUpdateRequest, reply *structs.GenericResponse) error { authErr := e.srv.Authenticate(e.ctx, args) // Ensure the connection was initiated by another server if TLS is used. err := validateTLSCertificateLevel(e.srv, e.ctx, tlsCertificateLevelServer) if err != nil { return err } if done, err := e.srv.forward("Eval.Create", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricWrite, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "create"}, time.Now()) // Ensure there is only a single update with token if len(args.Evals) != 1 { return fmt.Errorf("only a single eval can be created") } eval := args.Evals[0] // Verify the parent evaluation is outstanding, and that the tokens match. if err := e.srv.evalBroker.OutstandingReset(eval.PreviousEval, args.EvalToken); err != nil { return err } // Look for the eval snap, err := e.srv.fsm.State().Snapshot() if err != nil { return err } ws := memdb.NewWatchSet() out, err := snap.EvalByID(ws, eval.ID) if err != nil { return err } if out != nil { return fmt.Errorf("evaluation already exists") } // Update via Raft _, index, err := e.srv.raftApply(structs.EvalUpdateRequestType, args) if err != nil { return err } // Update the index reply.Index = index return nil } // Reblock is used to reinsert an existing blocked evaluation into the blocked // evaluation tracker. func (e *Eval) Reblock(args *structs.EvalUpdateRequest, reply *structs.GenericResponse) error { authErr := e.srv.Authenticate(e.ctx, args) // Ensure the connection was initiated by another server if TLS is used. err := validateTLSCertificateLevel(e.srv, e.ctx, tlsCertificateLevelServer) if err != nil { return err } if done, err := e.srv.forward("Eval.Reblock", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricWrite, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "reblock"}, time.Now()) // Ensure there is only a single update with token if len(args.Evals) != 1 { return fmt.Errorf("only a single eval can be reblocked") } eval := args.Evals[0] // Verify the evaluation is outstanding, and that the tokens match. if err := e.srv.evalBroker.OutstandingReset(eval.ID, args.EvalToken); err != nil { return err } // Look for the eval snap, err := e.srv.fsm.State().Snapshot() if err != nil { return err } ws := memdb.NewWatchSet() out, err := snap.EvalByID(ws, eval.ID) if err != nil { return err } if out == nil { return fmt.Errorf("evaluation does not exist") } if out.Status != structs.EvalStatusBlocked { return fmt.Errorf("evaluation not blocked") } // Reblock the eval e.srv.blockedEvals.Reblock(eval, args.EvalToken) return nil } // Reap is used to cleanup dead evaluations and allocations func (e *Eval) Reap(args *structs.EvalReapRequest, reply *structs.GenericResponse) error { authErr := e.srv.Authenticate(e.ctx, args) // Ensure the connection was initiated by another server if TLS is used. err := validateTLSCertificateLevel(e.srv, e.ctx, tlsCertificateLevelServer) if err != nil { return err } if done, err := e.srv.forward("Eval.Reap", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricWrite, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "reap"}, time.Now()) // Update via Raft _, index, err := e.srv.raftApply(structs.EvalDeleteRequestType, args) if err != nil { return err } // Update the index reply.Index = index return nil } // Delete is used by operators to delete evaluations during severe outages. It // differs from Reap while duplicating some behavior to ensure we have the // correct controls for user initiated deletions. func (e *Eval) Delete( args *structs.EvalDeleteRequest, reply *structs.EvalDeleteResponse) error { authErr := e.srv.Authenticate(e.ctx, args) if done, err := e.srv.forward(structs.EvalDeleteRPCMethod, args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricWrite, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "delete"}, time.Now()) // This RPC endpoint is very destructive and alters Nomad's core state, // meaning only those with management tokens can call it. if aclObj, err := e.srv.ResolveACL(args); err != nil { return err } else if aclObj != nil && !aclObj.IsManagement() { return structs.ErrPermissionDenied } if args.Filter != "" && !ServersMeetMinimumVersion( e.srv.Members(), e.srv.Region(), minVersionEvalDeleteByFilter, true) { return fmt.Errorf( "all servers must be running version %v or later to delete evals by filter", minVersionEvalDeleteByFilter) } if args.Filter != "" && len(args.EvalIDs) > 0 { return fmt.Errorf("evals cannot be deleted by both ID and filter") } if args.Filter == "" && len(args.EvalIDs) == 0 { return fmt.Errorf("evals must be deleted by either ID or filter") } // The eval broker must be disabled otherwise Nomad's state will likely get // wild in a very un-fun way. if e.srv.evalBroker.Enabled() { return errors.New("eval broker is enabled; eval broker must be paused to delete evals") } if args.Filter != "" { count, index, err := e.deleteEvalsByFilter(args) if err != nil { return err } // Update the index and return. reply.Index = index reply.Count = count return nil } // Grab the state snapshot, so we can look up relevant eval information. serverStateSnapshot, err := e.srv.State().Snapshot() if err != nil { return fmt.Errorf("failed to lookup state snapshot: %v", err) } ws := memdb.NewWatchSet() count := 0 // Iterate the evaluations and ensure they are safe to delete. It is // possible passed evals are not safe to delete and would make Nomads state // a little wonky. The nature of the RPC return error, means a single // unsafe eval ID fails the whole call. for _, evalID := range args.EvalIDs { evalInfo, err := serverStateSnapshot.EvalByID(ws, evalID) if err != nil { return fmt.Errorf("failed to lookup eval: %v", err) } if evalInfo == nil { return errors.New("eval not found") } ok, err := serverStateSnapshot.EvalIsUserDeleteSafe(ws, evalInfo) if err != nil { return err } if !ok { return fmt.Errorf("eval %s is not safe to delete", evalInfo.ID) } count++ } // Generate the Raft request object using the reap request object. This // avoids adding new Raft messages types and follows the existing reap // flow. raftReq := structs.EvalReapRequest{ Evals: args.EvalIDs, UserInitiated: true, WriteRequest: args.WriteRequest, } // Update via Raft. _, index, err := e.srv.raftApply(structs.EvalDeleteRequestType, &raftReq) if err != nil { return err } // Update the index and return. reply.Index = index reply.Count = count return nil } // deleteEvalsByFilter deletes evaluations in batches based on the filter. It // returns a count, the index, and any error func (e *Eval) deleteEvalsByFilter(args *structs.EvalDeleteRequest) (int, uint64, error) { count := 0 index := uint64(0) filter, err := bexpr.CreateEvaluator(args.Filter) if err != nil { return count, index, err } // Note that deleting evals by filter is imprecise: For sets of evals larger // than a single batch eval inserts may occur behind the cursor and therefore // be missed. This imprecision is not considered to hurt this endpoint's // purpose of reducing pressure on servers during periods of heavy scheduling // activity. snap, err := e.srv.State().Snapshot() if err != nil { return count, index, fmt.Errorf("failed to lookup state snapshot: %v", err) } iter, err := snap.Evals(nil, state.SortDefault) if err != nil { return count, index, err } // We *can* send larger raft logs but rough benchmarks for deleting 1M evals // show that a smaller page size strikes a balance between throughput and // time we block the FSM apply for other operations perPage := structs.MaxUUIDsPerWriteRequest / 10 raftReq := structs.EvalReapRequest{ Filter: args.Filter, PerPage: int32(perPage), UserInitiated: true, WriteRequest: args.WriteRequest, } // Note: Paginator is designed around fetching a single page for a single // RPC call and finalizes its state after that page. So we're doing our own // pagination here. pageCount := 0 lastToken := "" for { raw := iter.Next() if raw == nil { break } eval := raw.(*structs.Evaluation) deleteOk, err := snap.EvalIsUserDeleteSafe(nil, eval) if !deleteOk || err != nil { continue } match, err := filter.Evaluate(eval) if !match || err != nil { continue } pageCount++ lastToken = eval.ID if pageCount >= perPage { raftReq.PerPage = int32(pageCount) _, index, err = e.srv.raftApply(structs.EvalDeleteRequestType, &raftReq) if err != nil { return count, index, err } count += pageCount pageCount = 0 raftReq.NextToken = lastToken } } // send last batch if it's partial if pageCount > 0 { raftReq.PerPage = int32(pageCount) _, index, err = e.srv.raftApply(structs.EvalDeleteRequestType, &raftReq) if err != nil { return count, index, err } count += pageCount } return count, index, nil } // List is used to get a list of the evaluations in the system func (e *Eval) List(args *structs.EvalListRequest, reply *structs.EvalListResponse) error { authErr := e.srv.Authenticate(e.ctx, args) if done, err := e.srv.forward("Eval.List", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricList, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "list"}, time.Now()) namespace := args.RequestNamespace() // Check for read-job permissions aclObj, err := e.srv.ResolveACL(args) if err != nil { return err } if !aclObj.AllowNsOp(namespace, acl.NamespaceCapabilityReadJob) { return structs.ErrPermissionDenied } allow := aclObj.AllowNsOpFunc(acl.NamespaceCapabilityReadJob) if args.Filter != "" { // Check for incompatible filtering. hasLegacyFilter := args.FilterJobID != "" || args.FilterEvalStatus != "" if hasLegacyFilter { return structs.ErrIncompatibleFiltering } } // Setup the blocking query sort := state.SortOption(args.Reverse) opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, store *state.StateStore) error { // Scan all the evaluations var err error var iter memdb.ResultIterator var opts paginator.StructsTokenizerOptions // Get the namespaces the user is allowed to access. allowableNamespaces, err := allowedNSes(aclObj, store, allow) if err == structs.ErrPermissionDenied { // return empty evals if token isn't authorized for any // namespace, matching other endpoints reply.Evaluations = make([]*structs.Evaluation, 0) } else if err != nil { return err } else { if prefix := args.QueryOptions.Prefix; prefix != "" { iter, err = store.EvalsByIDPrefix(ws, namespace, prefix, sort) opts = paginator.StructsTokenizerOptions{ WithID: true, } } else if namespace != structs.AllNamespacesSentinel { iter, err = store.EvalsByNamespaceOrdered(ws, namespace, sort) opts = paginator.StructsTokenizerOptions{ WithCreateIndex: true, WithID: true, } } else { iter, err = store.Evals(ws, sort) opts = paginator.StructsTokenizerOptions{ WithCreateIndex: true, WithID: true, } } if err != nil { return err } iter = memdb.NewFilterIterator(iter, func(raw interface{}) bool { if eval := raw.(*structs.Evaluation); eval != nil { return args.ShouldBeFiltered(eval) } return false }) tokenizer := paginator.NewStructsTokenizer(iter, opts) filters := []paginator.Filter{ paginator.NamespaceFilter{ AllowableNamespaces: allowableNamespaces, }, } var evals []*structs.Evaluation paginator, err := paginator.NewPaginator(iter, tokenizer, filters, args.QueryOptions, func(raw interface{}) error { eval := raw.(*structs.Evaluation) evals = append(evals, eval) return nil }) if err != nil { return structs.NewErrRPCCodedf( http.StatusBadRequest, "failed to create result paginator: %v", err) } nextToken, err := paginator.Page() if err != nil { return structs.NewErrRPCCodedf( http.StatusBadRequest, "failed to read result page: %v", err) } reply.QueryMeta.NextToken = nextToken reply.Evaluations = evals } // Use the last index that affected the jobs table index, err := store.Index("evals") if err != nil { return err } reply.Index = index // Set the query response e.srv.setQueryMeta(&reply.QueryMeta) return nil }} return e.srv.blockingRPC(&opts) } // Count is used to get a list of the evaluations in the system func (e *Eval) Count(args *structs.EvalCountRequest, reply *structs.EvalCountResponse) error { authErr := e.srv.Authenticate(e.ctx, args) if done, err := e.srv.forward("Eval.Count", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricList, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "count"}, time.Now()) namespace := args.RequestNamespace() // Check for read-job permissions aclObj, err := e.srv.ResolveACL(args) if err != nil { return err } if !aclObj.AllowNsOp(namespace, acl.NamespaceCapabilityReadJob) { return structs.ErrPermissionDenied } allow := aclObj.AllowNsOpFunc(acl.NamespaceCapabilityReadJob) var filter *bexpr.Evaluator if args.Filter != "" { filter, err = bexpr.CreateEvaluator(args.Filter) if err != nil { return err } } // Setup the blocking query. This is only superficially like Eval.List, // because we don't any concerns about pagination, sorting, and legacy // filter fields. opts := blockingOptions{ queryOpts: &args.QueryOptions, queryMeta: &reply.QueryMeta, run: func(ws memdb.WatchSet, store *state.StateStore) error { // Scan all the evaluations var err error var iter memdb.ResultIterator // Get the namespaces the user is allowed to access. allowableNamespaces, err := allowedNSes(aclObj, store, allow) if err != nil { return err } if prefix := args.QueryOptions.Prefix; prefix != "" { iter, err = store.EvalsByIDPrefix(ws, namespace, prefix, state.SortDefault) } else if namespace != structs.AllNamespacesSentinel { iter, err = store.EvalsByNamespace(ws, namespace) } else { iter, err = store.Evals(ws, state.SortDefault) } if err != nil { return err } count := 0 iter = memdb.NewFilterIterator(iter, func(raw interface{}) bool { if raw == nil { return true } eval := raw.(*structs.Evaluation) if allowableNamespaces != nil && !allowableNamespaces[eval.Namespace] { return true } if filter != nil { ok, err := filter.Evaluate(eval) if err != nil { return true } return !ok } return false }) for { raw := iter.Next() if raw == nil { break } count++ } // Use the last index that affected the jobs table index, err := store.Index("evals") if err != nil { return err } reply.Index = index reply.Count = count // Set the query response e.srv.setQueryMeta(&reply.QueryMeta) return nil }} return e.srv.blockingRPC(&opts) } // Allocations is used to list the allocations for an evaluation func (e *Eval) Allocations(args *structs.EvalSpecificRequest, reply *structs.EvalAllocationsResponse) error { authErr := e.srv.Authenticate(e.ctx, args) if done, err := e.srv.forward("Eval.Allocations", args, args, reply); done { return err } e.srv.MeasureRPCRate("eval", structs.RateMetricList, args) if authErr != nil { return structs.ErrPermissionDenied } defer metrics.MeasureSince([]string{"nomad", "eval", "allocations"}, time.Now()) // Check for read-job permissions allowNsOp := acl.NamespaceValidator(acl.NamespaceCapabilityReadJob) aclObj, err := e.srv.ResolveACL(args) if err != nil { return err } else if !allowNsOp(aclObj, args.RequestNamespace()) { 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 the allocations allocs, err := state.AllocsByEval(ws, args.EvalID) if err != nil { return err } // Convert to a stub if len(allocs) > 0 { // Evaluations do not span namespaces so just check the // first allocs namespace. ns := allocs[0].Namespace if ns != args.RequestNamespace() && !allowNsOp(aclObj, ns) { return structs.ErrPermissionDenied } reply.Allocations = make([]*structs.AllocListStub, 0, len(allocs)) for _, alloc := range allocs { reply.Allocations = append(reply.Allocations, alloc.Stub(nil)) } } // 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 e.srv.setQueryMeta(&reply.QueryMeta) return nil }} return e.srv.blockingRPC(&opts) }