open-nomad/scheduler/util.go

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package scheduler
import (
"fmt"
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"math/rand"
"reflect"
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log "github.com/hashicorp/go-hclog"
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memdb "github.com/hashicorp/go-memdb"
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"github.com/hashicorp/nomad/nomad/structs"
)
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// allocTuple is a tuple of the allocation name and potential alloc ID
type allocTuple struct {
Name string
TaskGroup *structs.TaskGroup
Alloc *structs.Allocation
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}
// materializeTaskGroups is used to materialize all the task groups
// a job requires. This is used to do the count expansion.
func materializeTaskGroups(job *structs.Job) map[string]*structs.TaskGroup {
out := make(map[string]*structs.TaskGroup)
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if job.Stopped() {
return out
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}
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for _, tg := range job.TaskGroups {
for i := 0; i < tg.Count; i++ {
name := fmt.Sprintf("%s.%s[%d]", job.Name, tg.Name, i)
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out[name] = tg
}
}
return out
}
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// diffResult is used to return the sets that result from the diff
type diffResult struct {
place, update, migrate, stop, ignore, lost []allocTuple
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}
func (d *diffResult) GoString() string {
return fmt.Sprintf("allocs: (place %d) (update %d) (migrate %d) (stop %d) (ignore %d) (lost %d)",
len(d.place), len(d.update), len(d.migrate), len(d.stop), len(d.ignore), len(d.lost))
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}
func (d *diffResult) Append(other *diffResult) {
d.place = append(d.place, other.place...)
d.update = append(d.update, other.update...)
d.migrate = append(d.migrate, other.migrate...)
d.stop = append(d.stop, other.stop...)
d.ignore = append(d.ignore, other.ignore...)
d.lost = append(d.lost, other.lost...)
}
// diffSystemAllocsForNode is used to do a set difference between the target allocations
// and the existing allocations for a particular node. This returns 6 sets of results,
// the list of named task groups that need to be placed (no existing allocation), the
// allocations that need to be updated (job definition is newer), allocs that
// need to be migrated (node is draining), the allocs that need to be evicted
// (no longer required), those that should be ignored and those that are lost
// that need to be replaced (running on a lost node).
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//
// job is the job whose allocs is going to be diff-ed.
// taintedNodes is an index of the nodes which are either down or in drain mode
// by name.
// required is a set of allocations that must exist.
// allocs is a list of non terminal allocations.
// terminalAllocs is an index of the latest terminal allocations by name.
func diffSystemAllocsForNode(job *structs.Job, nodeID string,
eligibleNodes, taintedNodes map[string]*structs.Node,
required map[string]*structs.TaskGroup, allocs []*structs.Allocation,
terminalAllocs map[string]*structs.Allocation) *diffResult {
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result := &diffResult{}
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// Scan the existing updates
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existing := make(map[string]struct{})
for _, exist := range allocs {
// Index the existing node
name := exist.Name
existing[name] = struct{}{}
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// Check for the definition in the required set
tg, ok := required[name]
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// If not required, we stop the alloc
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if !ok {
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result.stop = append(result.stop, allocTuple{
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Name: name,
TaskGroup: tg,
Alloc: exist,
})
continue
}
// If we have been marked for migration and aren't terminal, migrate
if !exist.TerminalStatus() && exist.DesiredTransition.ShouldMigrate() {
result.migrate = append(result.migrate, allocTuple{
Name: name,
TaskGroup: tg,
Alloc: exist,
})
continue
}
// If we are on a tainted node, we must migrate if we are a service or
// if the batch allocation did not finish
if node, ok := taintedNodes[exist.NodeID]; ok {
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// If the job is batch and finished successfully, the fact that the
// node is tainted does not mean it should be migrated or marked as
// lost as the work was already successfully finished. However for
// service/system jobs, tasks should never complete. The check of
// batch type, defends against client bugs.
if exist.Job.Type == structs.JobTypeBatch && exist.RanSuccessfully() {
goto IGNORE
}
if !exist.TerminalStatus() && (node == nil || node.TerminalStatus()) {
result.lost = append(result.lost, allocTuple{
Name: name,
TaskGroup: tg,
Alloc: exist,
})
} else {
goto IGNORE
}
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continue
}
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// For an existing allocation, if the nodeID is no longer
// eligible, the diff should be ignored
if _, ok := eligibleNodes[nodeID]; !ok {
goto IGNORE
}
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// If the definition is updated we need to update
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if job.JobModifyIndex != exist.Job.JobModifyIndex {
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result.update = append(result.update, allocTuple{
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Name: name,
TaskGroup: tg,
Alloc: exist,
})
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continue
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}
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// Everything is up-to-date
IGNORE:
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result.ignore = append(result.ignore, allocTuple{
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Name: name,
TaskGroup: tg,
Alloc: exist,
})
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}
// Scan the required groups
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for name, tg := range required {
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// Check for an existing allocation
_, ok := existing[name]
// Require a placement if no existing allocation. If there
// is an existing allocation, we would have checked for a potential
// update or ignore above. Ignore placements for tainted or
// ineligible nodes
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if !ok {
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// Tainted and ineligible nodes for a non existing alloc
// should be filtered out and not count towards ignore or place
if _, tainted := taintedNodes[nodeID]; tainted {
continue
}
if _, eligible := eligibleNodes[nodeID]; !eligible {
continue
}
allocTuple := allocTuple{
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Name: name,
TaskGroup: tg,
Alloc: terminalAllocs[name],
}
// If the new allocation isn't annotated with a previous allocation
// or if the previous allocation isn't from the same node then we
// annotate the allocTuple with a new Allocation
if allocTuple.Alloc == nil || allocTuple.Alloc.NodeID != nodeID {
allocTuple.Alloc = &structs.Allocation{NodeID: nodeID}
}
result.place = append(result.place, allocTuple)
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}
}
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return result
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}
// diffSystemAllocs is like diffSystemAllocsForNode however, the allocations in the
// diffResult contain the specific nodeID they should be allocated on.
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//
// job is the job whose allocs is going to be diff-ed.
// nodes is a list of nodes in ready state.
// taintedNodes is an index of the nodes which are either down or in drain mode
// by name.
// allocs is a list of non terminal allocations.
// terminalAllocs is an index of the latest terminal allocations by name.
func diffSystemAllocs(job *structs.Job, nodes []*structs.Node, taintedNodes map[string]*structs.Node,
allocs []*structs.Allocation, terminalAllocs map[string]*structs.Allocation) *diffResult {
// Build a mapping of nodes to all their allocs.
nodeAllocs := make(map[string][]*structs.Allocation, len(allocs))
for _, alloc := range allocs {
nallocs := append(nodeAllocs[alloc.NodeID], alloc)
nodeAllocs[alloc.NodeID] = nallocs
}
eligibleNodes := make(map[string]*structs.Node)
for _, node := range nodes {
if _, ok := nodeAllocs[node.ID]; !ok {
nodeAllocs[node.ID] = nil
}
eligibleNodes[node.ID] = node
}
// Create the required task groups.
required := materializeTaskGroups(job)
result := &diffResult{}
for nodeID, allocs := range nodeAllocs {
diff := diffSystemAllocsForNode(job, nodeID, eligibleNodes, taintedNodes, required, allocs, terminalAllocs)
result.Append(diff)
}
return result
}
// readyNodesInDCs returns all the ready nodes in the given datacenters and a
// mapping of each data center to the count of ready nodes.
func readyNodesInDCs(state State, dcs []string) ([]*structs.Node, map[string]int, error) {
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// Index the DCs
dcMap := make(map[string]int, len(dcs))
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for _, dc := range dcs {
dcMap[dc] = 0
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}
// Scan the nodes
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ws := memdb.NewWatchSet()
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var out []*structs.Node
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iter, err := state.Nodes(ws)
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if err != nil {
return nil, nil, err
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}
for {
raw := iter.Next()
if raw == nil {
break
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}
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// Filter on datacenter and status
node := raw.(*structs.Node)
if node.Status != structs.NodeStatusReady {
continue
}
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if node.Drain {
continue
}
if node.SchedulingEligibility != structs.NodeSchedulingEligible {
continue
}
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if _, ok := dcMap[node.Datacenter]; !ok {
continue
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}
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out = append(out, node)
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dcMap[node.Datacenter]++
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}
return out, dcMap, nil
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}
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// retryMax is used to retry a callback until it returns success or
// a maximum number of attempts is reached. An optional reset function may be
// passed which is called after each failed iteration. If the reset function is
// set and returns true, the number of attempts is reset back to max.
func retryMax(max int, cb func() (bool, error), reset func() bool) error {
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attempts := 0
for attempts < max {
done, err := cb()
if err != nil {
return err
}
if done {
return nil
}
// Check if we should reset the number attempts
if reset != nil && reset() {
attempts = 0
} else {
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attempts++
}
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}
return &SetStatusError{
Err: fmt.Errorf("maximum attempts reached (%d)", max),
EvalStatus: structs.EvalStatusFailed,
}
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}
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// progressMade checks to see if the plan result made allocations or updates.
// If the result is nil, false is returned.
func progressMade(result *structs.PlanResult) bool {
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return result != nil && (len(result.NodeUpdate) != 0 ||
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len(result.NodeAllocation) != 0 || result.Deployment != nil ||
len(result.DeploymentUpdates) != 0)
}
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// taintedNodes is used to scan the allocations and then check if the
// underlying nodes are tainted, and should force a migration of the allocation.
// All the nodes returned in the map are tainted.
func taintedNodes(state State, allocs []*structs.Allocation) (map[string]*structs.Node, error) {
out := make(map[string]*structs.Node)
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for _, alloc := range allocs {
if _, ok := out[alloc.NodeID]; ok {
continue
}
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ws := memdb.NewWatchSet()
node, err := state.NodeByID(ws, alloc.NodeID)
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if err != nil {
return nil, err
}
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// If the node does not exist, we should migrate
if node == nil {
out[alloc.NodeID] = nil
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continue
}
if structs.ShouldDrainNode(node.Status) || node.Drain {
out[alloc.NodeID] = node
}
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}
return out, nil
}
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// shuffleNodes randomizes the slice order with the Fisher-Yates algorithm
func shuffleNodes(nodes []*structs.Node) {
n := len(nodes)
for i := n - 1; i > 0; i-- {
j := rand.Intn(i + 1)
nodes[i], nodes[j] = nodes[j], nodes[i]
}
}
// tasksUpdated does a diff between task groups to see if the
// tasks, their drivers, environment variables or config have updated. The
// inputs are the task group name to diff and two jobs to diff.
// taskUpdated and functions called within assume that the given
// taskGroup has already been checked to not be nil
func tasksUpdated(jobA, jobB *structs.Job, taskGroup string) bool {
a := jobA.LookupTaskGroup(taskGroup)
b := jobB.LookupTaskGroup(taskGroup)
// If the number of tasks do not match, clearly there is an update
if len(a.Tasks) != len(b.Tasks) {
return true
}
// Check ephemeral disk
if !reflect.DeepEqual(a.EphemeralDisk, b.EphemeralDisk) {
return true
}
// Check that the network resources haven't changed
if networkUpdated(a.Networks, b.Networks) {
return true
}
// Check Affinities
if affinitiesUpdated(jobA, jobB, taskGroup) {
return true
}
// Check Spreads
if spreadsUpdated(jobA, jobB, taskGroup) {
return true
}
// Check connect service(s) updated
if connectServiceUpdated(a.Services, b.Services) {
return true
}
// Check each task
for _, at := range a.Tasks {
bt := b.LookupTask(at.Name)
if bt == nil {
return true
}
if at.Driver != bt.Driver {
return true
}
if at.User != bt.User {
return true
}
if !reflect.DeepEqual(at.Config, bt.Config) {
return true
}
if !reflect.DeepEqual(at.Env, bt.Env) {
return true
}
if !reflect.DeepEqual(at.Artifacts, bt.Artifacts) {
return true
}
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if !reflect.DeepEqual(at.Vault, bt.Vault) {
return true
}
if !reflect.DeepEqual(at.Templates, bt.Templates) {
return true
}
// Check the metadata
if !reflect.DeepEqual(
jobA.CombinedTaskMeta(taskGroup, at.Name),
jobB.CombinedTaskMeta(taskGroup, bt.Name)) {
return true
}
// Inspect the network to see if the dynamic ports are different
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if networkUpdated(at.Resources.Networks, bt.Resources.Networks) {
return true
}
// Inspect the non-network resources
if ar, br := at.Resources, bt.Resources; ar.CPU != br.CPU {
return true
} else if ar.MemoryMB != br.MemoryMB {
return true
} else if !ar.Devices.Equals(&br.Devices) {
return true
}
}
return false
}
// connectServiceUpdated returns true if any services with a connect stanza have
// been changed in such a way that requires a destructive update.
//
// Ordinary services can be updated in-place by updating the service definition
// in Consul. Connect service changes mostly require destroying the task.
func connectServiceUpdated(servicesA, servicesB []*structs.Service) bool {
for _, serviceA := range servicesA {
if serviceA.Connect != nil {
for _, serviceB := range servicesB {
if serviceA.Name == serviceB.Name {
if connectUpdated(serviceA.Connect, serviceB.Connect) {
return true
}
// Part of the Connect plumbing is derived from port label,
// if that changes we need to destroy the task.
if serviceA.PortLabel != serviceB.PortLabel {
return true
}
break
}
}
}
}
return false
}
// connectUpdated returns true if the connect block has been updated in a manner
// that will require a destructive update.
//
// Fields that can be updated through consul-sync do not need a destructive
// update.
func connectUpdated(connectA, connectB *structs.ConsulConnect) bool {
if connectA == nil || connectB == nil {
return connectA != connectB
}
if connectA.Native != connectB.Native {
return true
}
if !connectA.Gateway.Equals(connectB.Gateway) {
return true
}
if !connectA.SidecarTask.Equals(connectB.SidecarTask) {
return true
}
// not everything in sidecar_service needs task destruction
if connectSidecarServiceUpdated(connectA.SidecarService, connectB.SidecarService) {
return true
}
return false
}
func connectSidecarServiceUpdated(ssA, ssB *structs.ConsulSidecarService) bool {
if ssA == nil || ssB == nil {
return ssA != ssB
}
if ssA.Port != ssB.Port {
return true
}
// sidecar_service.tags handled in-place (registration)
// sidecar_service.proxy handled in-place (registration + xDS)
return false
}
func networkUpdated(netA, netB []*structs.NetworkResource) bool {
if len(netA) != len(netB) {
return true
}
for idx := range netA {
an := netA[idx]
bn := netB[idx]
if an.Mode != bn.Mode {
return true
}
if an.MBits != bn.MBits {
return true
}
if !reflect.DeepEqual(an.DNS, bn.DNS) {
return true
}
aPorts, bPorts := networkPortMap(an), networkPortMap(bn)
if !reflect.DeepEqual(aPorts, bPorts) {
return true
}
}
return false
}
// networkPortMap takes a network resource and returns a AllocatedPorts.
// The value for dynamic ports is disregarded even if it is set. This
// makes this function suitable for comparing two network resources for changes.
func networkPortMap(n *structs.NetworkResource) structs.AllocatedPorts {
var m structs.AllocatedPorts
for _, p := range n.ReservedPorts {
m = append(m, structs.AllocatedPortMapping{
Label: p.Label,
Value: p.Value,
To: p.To,
HostIP: p.HostNetwork,
})
}
for _, p := range n.DynamicPorts {
m = append(m, structs.AllocatedPortMapping{
Label: p.Label,
Value: -1,
To: p.To,
HostIP: p.HostNetwork,
})
}
return m
}
func affinitiesUpdated(jobA, jobB *structs.Job, taskGroup string) bool {
var aAffinities []*structs.Affinity
var bAffinities []*structs.Affinity
tgA := jobA.LookupTaskGroup(taskGroup)
tgB := jobB.LookupTaskGroup(taskGroup)
// Append jobA job and task group level affinities
aAffinities = append(aAffinities, jobA.Affinities...)
aAffinities = append(aAffinities, tgA.Affinities...)
// Append jobB job and task group level affinities
bAffinities = append(bAffinities, jobB.Affinities...)
bAffinities = append(bAffinities, tgB.Affinities...)
// append task affinities
for _, task := range tgA.Tasks {
aAffinities = append(aAffinities, task.Affinities...)
}
for _, task := range tgB.Tasks {
bAffinities = append(bAffinities, task.Affinities...)
}
// Check for equality
if len(aAffinities) != len(bAffinities) {
return true
}
return !reflect.DeepEqual(aAffinities, bAffinities)
}
func spreadsUpdated(jobA, jobB *structs.Job, taskGroup string) bool {
var aSpreads []*structs.Spread
var bSpreads []*structs.Spread
tgA := jobA.LookupTaskGroup(taskGroup)
tgB := jobB.LookupTaskGroup(taskGroup)
// append jobA and task group level spreads
aSpreads = append(aSpreads, jobA.Spreads...)
aSpreads = append(aSpreads, tgA.Spreads...)
// append jobB and task group level spreads
bSpreads = append(bSpreads, jobB.Spreads...)
bSpreads = append(bSpreads, tgB.Spreads...)
// Check for equality
if len(aSpreads) != len(bSpreads) {
return true
}
return !reflect.DeepEqual(aSpreads, bSpreads)
}
// setStatus is used to update the status of the evaluation
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func setStatus(logger log.Logger, planner Planner,
eval, nextEval, spawnedBlocked *structs.Evaluation,
tgMetrics map[string]*structs.AllocMetric, status, desc string,
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queuedAllocs map[string]int, deploymentID string) error {
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logger.Debug("setting eval status", "status", status)
newEval := eval.Copy()
newEval.Status = status
newEval.StatusDescription = desc
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newEval.DeploymentID = deploymentID
newEval.FailedTGAllocs = tgMetrics
if nextEval != nil {
newEval.NextEval = nextEval.ID
}
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if spawnedBlocked != nil {
newEval.BlockedEval = spawnedBlocked.ID
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}
if queuedAllocs != nil {
newEval.QueuedAllocations = queuedAllocs
}
return planner.UpdateEval(newEval)
}
// inplaceUpdate attempts to update allocations in-place where possible. It
// returns the allocs that couldn't be done inplace and then those that could.
func inplaceUpdate(ctx Context, eval *structs.Evaluation, job *structs.Job,
stack Stack, updates []allocTuple) (destructive, inplace []allocTuple) {
// doInplace manipulates the updates map to make the current allocation
// an inplace update.
doInplace := func(cur, last, inplaceCount *int) {
updates[*cur], updates[*last-1] = updates[*last-1], updates[*cur]
*cur--
*last--
*inplaceCount++
}
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ws := memdb.NewWatchSet()
n := len(updates)
inplaceCount := 0
for i := 0; i < n; i++ {
// Get the update
update := updates[i]
// Check if the task drivers or config has changed, requires
// a rolling upgrade since that cannot be done in-place.
existing := update.Alloc.Job
if tasksUpdated(job, existing, update.TaskGroup.Name) {
continue
}
// Terminal batch allocations are not filtered when they are completed
// successfully. We should avoid adding the allocation to the plan in
// the case that it is an in-place update to avoid both additional data
// in the plan and work for the clients.
if update.Alloc.TerminalStatus() {
doInplace(&i, &n, &inplaceCount)
continue
}
// Get the existing node
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node, err := ctx.State().NodeByID(ws, update.Alloc.NodeID)
if err != nil {
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ctx.Logger().Error("failed to get node", "node_id", update.Alloc.NodeID, "error", err)
continue
}
if node == nil {
continue
}
// Set the existing node as the base set
stack.SetNodes([]*structs.Node{node})
// Stage an eviction of the current allocation. This is done so that
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// the current allocation is discounted when checking for feasibility.
// Otherwise we would be trying to fit the tasks current resources and
// updated resources. After select is called we can remove the evict.
ctx.Plan().AppendStoppedAlloc(update.Alloc, allocInPlace, "", "")
// Attempt to match the task group
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option := stack.Select(update.TaskGroup, nil) // This select only looks at one node so we don't pass selectOptions
// Pop the allocation
ctx.Plan().PopUpdate(update.Alloc)
// Skip if we could not do an in-place update
if option == nil {
continue
}
// Restore the network and device offers from the existing allocation.
// We do not allow network resources (reserved/dynamic ports)
// to be updated. This is guarded in taskUpdated, so we can
// safely restore those here.
for task, resources := range option.TaskResources {
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var networks structs.Networks
var devices []*structs.AllocatedDeviceResource
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if update.Alloc.AllocatedResources != nil {
if tr, ok := update.Alloc.AllocatedResources.Tasks[task]; ok {
networks = tr.Networks
devices = tr.Devices
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}
} else if tr, ok := update.Alloc.TaskResources[task]; ok {
networks = tr.Networks
}
// Add the networks and devices back
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resources.Networks = networks
resources.Devices = devices
}
// Create a shallow copy
newAlloc := new(structs.Allocation)
*newAlloc = *update.Alloc
// Update the allocation
newAlloc.EvalID = eval.ID
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newAlloc.Job = nil // Use the Job in the Plan
newAlloc.Resources = nil // Computed in Plan Apply
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newAlloc.AllocatedResources = &structs.AllocatedResources{
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Tasks: option.TaskResources,
TaskLifecycles: option.TaskLifecycles,
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Shared: structs.AllocatedSharedResources{
DiskMB: int64(update.TaskGroup.EphemeralDisk.SizeMB),
Ports: update.Alloc.AllocatedResources.Shared.Ports,
Networks: update.Alloc.AllocatedResources.Shared.Networks.Copy(),
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},
}
newAlloc.Metrics = ctx.Metrics()
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ctx.Plan().AppendAlloc(newAlloc, nil)
// Remove this allocation from the slice
doInplace(&i, &n, &inplaceCount)
}
if len(updates) > 0 {
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ctx.Logger().Debug("made in-place updates", "in-place", inplaceCount, "total_updates", len(updates))
}
return updates[:n], updates[n:]
}
// evictAndPlace is used to mark allocations for evicts and add them to the
// placement queue. evictAndPlace modifies both the diffResult and the
// limit. It returns true if the limit has been reached.
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func evictAndPlace(ctx Context, diff *diffResult, allocs []allocTuple, desc string, limit *int) bool {
n := len(allocs)
for i := 0; i < n && i < *limit; i++ {
a := allocs[i]
ctx.Plan().AppendStoppedAlloc(a.Alloc, desc, "", "")
diff.place = append(diff.place, a)
}
if n <= *limit {
*limit -= n
return false
}
*limit = 0
return true
}
// tgConstrainTuple is used to store the total constraints of a task group.
type tgConstrainTuple struct {
// Holds the combined constraints of the task group and all it's sub-tasks.
constraints []*structs.Constraint
// The set of required drivers within the task group.
drivers map[string]struct{}
}
// taskGroupConstraints collects the constraints, drivers and resources required by each
// sub-task to aggregate the TaskGroup totals
func taskGroupConstraints(tg *structs.TaskGroup) tgConstrainTuple {
c := tgConstrainTuple{
constraints: make([]*structs.Constraint, 0, len(tg.Constraints)),
drivers: make(map[string]struct{}),
}
c.constraints = append(c.constraints, tg.Constraints...)
for _, task := range tg.Tasks {
c.drivers[task.Driver] = struct{}{}
c.constraints = append(c.constraints, task.Constraints...)
}
return c
}
// desiredUpdates takes the diffResult as well as the set of inplace and
// destructive updates and returns a map of task groups to their set of desired
// updates.
func desiredUpdates(diff *diffResult, inplaceUpdates,
destructiveUpdates []allocTuple) map[string]*structs.DesiredUpdates {
desiredTgs := make(map[string]*structs.DesiredUpdates)
for _, tuple := range diff.place {
name := tuple.TaskGroup.Name
des, ok := desiredTgs[name]
if !ok {
des = &structs.DesiredUpdates{}
desiredTgs[name] = des
}
des.Place++
}
for _, tuple := range diff.stop {
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name := tuple.Alloc.TaskGroup
des, ok := desiredTgs[name]
if !ok {
des = &structs.DesiredUpdates{}
desiredTgs[name] = des
}
des.Stop++
}
for _, tuple := range diff.ignore {
name := tuple.TaskGroup.Name
des, ok := desiredTgs[name]
if !ok {
des = &structs.DesiredUpdates{}
desiredTgs[name] = des
}
des.Ignore++
}
for _, tuple := range diff.migrate {
name := tuple.TaskGroup.Name
des, ok := desiredTgs[name]
if !ok {
des = &structs.DesiredUpdates{}
desiredTgs[name] = des
}
des.Migrate++
}
for _, tuple := range inplaceUpdates {
name := tuple.TaskGroup.Name
des, ok := desiredTgs[name]
if !ok {
des = &structs.DesiredUpdates{}
desiredTgs[name] = des
}
des.InPlaceUpdate++
}
for _, tuple := range destructiveUpdates {
name := tuple.TaskGroup.Name
des, ok := desiredTgs[name]
if !ok {
des = &structs.DesiredUpdates{}
desiredTgs[name] = des
}
des.DestructiveUpdate++
}
return desiredTgs
}
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// adjustQueuedAllocations decrements the number of allocations pending per task
// group based on the number of allocations successfully placed
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func adjustQueuedAllocations(logger log.Logger, result *structs.PlanResult, queuedAllocs map[string]int) {
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if result == nil {
return
}
for _, allocations := range result.NodeAllocation {
for _, allocation := range allocations {
// Ensure that the allocation is newly created. We check that
// the CreateIndex is equal to the ModifyIndex in order to check
// that the allocation was just created. We do not check that
// the CreateIndex is equal to the results AllocIndex because
// the allocations we get back have gone through the planner's
// optimistic snapshot and thus their indexes may not be
// correct, but they will be consistent.
if allocation.CreateIndex != allocation.ModifyIndex {
continue
}
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if _, ok := queuedAllocs[allocation.TaskGroup]; ok {
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queuedAllocs[allocation.TaskGroup]--
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} else {
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logger.Error("allocation placed but task group is not in list of unplaced allocations", "task_group", allocation.TaskGroup)
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}
}
}
}
// updateNonTerminalAllocsToLost updates the allocations which are in pending/running state
// on tainted node to lost, but only for allocs already DesiredStatus stop or evict
func updateNonTerminalAllocsToLost(plan *structs.Plan, tainted map[string]*structs.Node, allocs []*structs.Allocation) {
for _, alloc := range allocs {
node, ok := tainted[alloc.NodeID]
if !ok {
continue
}
// Only handle down nodes or nodes that are gone (node == nil)
if node != nil && node.Status != structs.NodeStatusDown {
continue
}
// If the alloc is already correctly marked lost, we're done
if (alloc.DesiredStatus == structs.AllocDesiredStatusStop ||
alloc.DesiredStatus == structs.AllocDesiredStatusEvict) &&
(alloc.ClientStatus == structs.AllocClientStatusRunning ||
alloc.ClientStatus == structs.AllocClientStatusPending) {
plan.AppendStoppedAlloc(alloc, allocLost, structs.AllocClientStatusLost, "")
}
}
}
// genericAllocUpdateFn is a factory for the scheduler to create an allocUpdateType
// function to be passed into the reconciler. The factory takes objects that
// exist only in the scheduler context and returns a function that can be used
// by the reconciler to make decisions about how to update an allocation. The
// factory allows the reconciler to be unaware of how to determine the type of
// update necessary and can minimize the set of objects it is exposed to.
func genericAllocUpdateFn(ctx Context, stack Stack, evalID string) allocUpdateType {
return func(existing *structs.Allocation, newJob *structs.Job, newTG *structs.TaskGroup) (ignore, destructive bool, updated *structs.Allocation) {
// Same index, so nothing to do
if existing.Job.JobModifyIndex == newJob.JobModifyIndex {
return true, false, nil
}
// Check if the task drivers or config has changed, requires
// a destructive upgrade since that cannot be done in-place.
if tasksUpdated(newJob, existing.Job, newTG.Name) {
return false, true, nil
}
// Terminal batch allocations are not filtered when they are completed
// successfully. We should avoid adding the allocation to the plan in
// the case that it is an in-place update to avoid both additional data
// in the plan and work for the clients.
if existing.TerminalStatus() {
return true, false, nil
}
// Get the existing node
ws := memdb.NewWatchSet()
node, err := ctx.State().NodeByID(ws, existing.NodeID)
if err != nil {
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ctx.Logger().Error("failed to get node", "node_id", existing.NodeID, "error", err)
return true, false, nil
}
if node == nil {
return false, true, nil
}
// Set the existing node as the base set
stack.SetNodes([]*structs.Node{node})
// Stage an eviction of the current allocation. This is done so that
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// the current allocation is discounted when checking for feasibility.
// Otherwise we would be trying to fit the tasks current resources and
// updated resources. After select is called we can remove the evict.
ctx.Plan().AppendStoppedAlloc(existing, allocInPlace, "", "")
// Attempt to match the task group
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option := stack.Select(newTG, nil) // This select only looks at one node so we don't pass selectOptions
// Pop the allocation
ctx.Plan().PopUpdate(existing)
// Require destructive if we could not do an in-place update
if option == nil {
return false, true, nil
}
// Restore the network and device offers from the existing allocation.
// We do not allow network resources (reserved/dynamic ports)
// to be updated. This is guarded in taskUpdated, so we can
// safely restore those here.
for task, resources := range option.TaskResources {
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var networks structs.Networks
var devices []*structs.AllocatedDeviceResource
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if existing.AllocatedResources != nil {
if tr, ok := existing.AllocatedResources.Tasks[task]; ok {
networks = tr.Networks
devices = tr.Devices
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}
} else if tr, ok := existing.TaskResources[task]; ok {
networks = tr.Networks
}
// Add the networks back
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resources.Networks = networks
resources.Devices = devices
}
// Create a shallow copy
newAlloc := new(structs.Allocation)
*newAlloc = *existing
// Update the allocation
newAlloc.EvalID = evalID
newAlloc.Job = nil // Use the Job in the Plan
newAlloc.Resources = nil // Computed in Plan Apply
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newAlloc.AllocatedResources = &structs.AllocatedResources{
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Tasks: option.TaskResources,
TaskLifecycles: option.TaskLifecycles,
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Shared: structs.AllocatedSharedResources{
DiskMB: int64(newTG.EphemeralDisk.SizeMB),
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},
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}
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// Since this is an inplace update, we should copy network and port
// information from the original alloc. This is similar to how
// we copy network info for task level networks above.
//
// existing.AllocatedResources is nil on Allocations created by
// Nomad v0.8 or earlier.
if existing.AllocatedResources != nil {
newAlloc.AllocatedResources.Shared.Networks = existing.AllocatedResources.Shared.Networks
newAlloc.AllocatedResources.Shared.Ports = existing.AllocatedResources.Shared.Ports
}
// Use metrics from existing alloc for in place upgrade
// This is because if the inplace upgrade succeeded, any scoring metadata from
// when it first went through the scheduler should still be preserved. Using scoring
// metadata from the context would incorrectly replace it with metadata only from a single node that the
// allocation is already on.
newAlloc.Metrics = existing.Metrics.Copy()
return false, false, newAlloc
}
}