open-nomad/nomad/heartbeat.go

265 lines
7.8 KiB
Go

// Copyright (c) HashiCorp, Inc.
// SPDX-License-Identifier: MPL-2.0
package nomad
import (
"errors"
"sync"
"time"
log "github.com/hashicorp/go-hclog"
memdb "github.com/hashicorp/go-memdb"
metrics "github.com/hashicorp/go-metrics"
"github.com/hashicorp/nomad/helper"
"github.com/hashicorp/nomad/nomad/structs"
)
const (
// heartbeatNotLeader is the error string returned when the heartbeat request
// couldn't be completed since the server is not the leader.
heartbeatNotLeader = "failed to reset heartbeat since server is not leader"
// NodeHeartbeatEventMissed is the event used when the Nodes heartbeat is
// missed.
NodeHeartbeatEventMissed = "Node heartbeat missed"
)
var (
// heartbeatNotLeaderErr is the error returned when the heartbeat request
// couldn't be completed since the server is not the leader.
heartbeatNotLeaderErr = errors.New(heartbeatNotLeader)
)
// nodeHeartbeater is used to track expiration times of node heartbeats. If it
// detects an expired node, the node status is updated to be 'down'.
type nodeHeartbeater struct {
srv *Server
logger log.Logger
// heartbeatTimers track the expiration time of each heartbeat that has
// a TTL. On expiration, the node status is updated to be 'down'.
heartbeatTimers map[string]*time.Timer
heartbeatTimersLock sync.Mutex
}
// newNodeHeartbeater returns a new node heartbeater used to detect and act on
// failed node heartbeats.
func newNodeHeartbeater(s *Server) *nodeHeartbeater {
return &nodeHeartbeater{
srv: s,
logger: s.logger.Named("heartbeat"),
}
}
// initializeHeartbeatTimers is used when a leader is newly elected to create
// a new map to track heartbeat expiration and to reset all the timers from
// the previously known set of timers.
func (h *nodeHeartbeater) initializeHeartbeatTimers() error {
// Scan all nodes and reset their timer
snap, err := h.srv.fsm.State().Snapshot()
if err != nil {
return err
}
// Get an iterator over nodes
ws := memdb.NewWatchSet()
iter, err := snap.Nodes(ws)
if err != nil {
return err
}
h.heartbeatTimersLock.Lock()
defer h.heartbeatTimersLock.Unlock()
// Handle each node
for {
raw := iter.Next()
if raw == nil {
break
}
node := raw.(*structs.Node)
if node.TerminalStatus() {
continue
}
h.resetHeartbeatTimerLocked(node.ID, h.srv.config.FailoverHeartbeatTTL)
}
return nil
}
// resetHeartbeatTimer is used to reset the TTL of a heartbeat.
// This can be used for new heartbeats and existing ones.
func (h *nodeHeartbeater) resetHeartbeatTimer(id string) (time.Duration, error) {
h.heartbeatTimersLock.Lock()
defer h.heartbeatTimersLock.Unlock()
// Do not create a timer for the node since we are not the leader. This
// check avoids the race in which leadership is lost but a timer is created
// on this server since it was servicing an RPC during a leadership loss.
if !h.srv.IsLeader() {
h.logger.Debug("ignoring resetting node TTL since this server is not the leader", "node_id", id)
return 0, heartbeatNotLeaderErr
}
// Compute the target TTL value
n := len(h.heartbeatTimers)
ttl := helper.RateScaledInterval(h.srv.config.MaxHeartbeatsPerSecond, h.srv.config.MinHeartbeatTTL, n)
ttl += helper.RandomStagger(ttl)
// Reset the TTL
h.resetHeartbeatTimerLocked(id, ttl+h.srv.config.HeartbeatGrace)
return ttl, nil
}
// resetHeartbeatTimerLocked is used to reset a heartbeat timer
// assuming the heartbeatTimerLock is already held
func (h *nodeHeartbeater) resetHeartbeatTimerLocked(id string, ttl time.Duration) {
// Ensure a timer map exists
if h.heartbeatTimers == nil {
h.heartbeatTimers = make(map[string]*time.Timer)
}
// Renew the heartbeat timer if it exists
if timer, ok := h.heartbeatTimers[id]; ok {
timer.Reset(ttl)
return
}
// Create a new timer to track expiration of this heartbeat
timer := time.AfterFunc(ttl, func() {
h.invalidateHeartbeat(id)
})
h.heartbeatTimers[id] = timer
}
// invalidateHeartbeat is invoked when a heartbeat TTL is reached and we
// need to invalidate the heartbeat.
func (h *nodeHeartbeater) invalidateHeartbeat(id string) {
defer metrics.MeasureSince([]string{"nomad", "heartbeat", "invalidate"}, time.Now())
// Clear the heartbeat timer
h.heartbeatTimersLock.Lock()
if timer, ok := h.heartbeatTimers[id]; ok {
timer.Stop()
delete(h.heartbeatTimers, id)
}
h.heartbeatTimersLock.Unlock()
// Do not invalidate the node since we are not the leader. This check avoids
// the race in which leadership is lost but a timer is created on this
// server since it was servicing an RPC during a leadership loss.
if !h.srv.IsLeader() {
h.logger.Debug("ignoring node TTL since this server is not the leader", "node_id", id)
return
}
h.logger.Warn("node TTL expired", "node_id", id)
canDisconnect, hasPendingReconnects := h.disconnectState(id)
// Make a request to update the node status
req := structs.NodeUpdateStatusRequest{
NodeID: id,
Status: structs.NodeStatusDown,
NodeEvent: structs.NewNodeEvent().SetSubsystem(structs.NodeEventSubsystemCluster).SetMessage(NodeHeartbeatEventMissed),
WriteRequest: structs.WriteRequest{
Region: h.srv.config.Region,
},
}
if canDisconnect && hasPendingReconnects {
req.Status = structs.NodeStatusDisconnected
}
var resp structs.NodeUpdateResponse
if err := h.srv.RPC("Node.UpdateStatus", &req, &resp); err != nil {
h.logger.Error("update node status failed", "error", err)
}
}
func (h *nodeHeartbeater) disconnectState(id string) (bool, bool) {
node, err := h.srv.State().NodeByID(nil, id)
if err != nil {
h.logger.Error("error retrieving node by id", "error", err)
return false, false
}
// Exit if the node is already down or just initializing.
if node.Status == structs.NodeStatusDown || node.Status == structs.NodeStatusInit {
return false, false
}
allocs, err := h.srv.State().AllocsByNode(nil, id)
if err != nil {
h.logger.Error("error retrieving allocs by node", "error", err)
return false, false
}
now := time.Now().UTC()
// Check if the node has any allocs that are configured with max_client_disconnect,
// that are past the disconnect window, and if so, whether it has at least one
// alloc that isn't yet expired.
nodeCanDisconnect := false
for _, alloc := range allocs {
allocCanDisconnect := alloc.DisconnectTimeout(now).After(now)
// Only process this until we find that at least one alloc is configured
// with max_client_disconnect.
if !nodeCanDisconnect && allocCanDisconnect {
nodeCanDisconnect = true
}
// Only process this until we find one that we want to run and has not
// yet expired.
if allocCanDisconnect &&
alloc.DesiredStatus == structs.AllocDesiredStatusRun &&
!alloc.Expired(now) {
return true, true
}
}
return nodeCanDisconnect, false
}
// clearHeartbeatTimer is used to clear the heartbeat time for
// a single heartbeat. This is used when a heartbeat is destroyed
// explicitly and no longer needed.
func (h *nodeHeartbeater) clearHeartbeatTimer(id string) error {
h.heartbeatTimersLock.Lock()
defer h.heartbeatTimersLock.Unlock()
if timer, ok := h.heartbeatTimers[id]; ok {
timer.Stop()
delete(h.heartbeatTimers, id)
}
return nil
}
// clearAllHeartbeatTimers is used when a leader is stepping
// down and we no longer need to track any heartbeat timers.
func (h *nodeHeartbeater) clearAllHeartbeatTimers() error {
h.heartbeatTimersLock.Lock()
defer h.heartbeatTimersLock.Unlock()
for _, t := range h.heartbeatTimers {
t.Stop()
}
h.heartbeatTimers = nil
return nil
}
// heartbeatStats is a long running routine used to capture
// the number of active heartbeats being tracked
func (h *nodeHeartbeater) heartbeatStats() {
for {
select {
case <-time.After(5 * time.Second):
h.heartbeatTimersLock.Lock()
num := len(h.heartbeatTimers)
h.heartbeatTimersLock.Unlock()
metrics.SetGauge([]string{"nomad", "heartbeat", "active"}, float32(num))
case <-h.srv.shutdownCh:
return
}
}
}