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asynq/heartbeat_test.go

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// Copyright 2020 Kentaro Hibino. All rights reserved.
// Use of this source code is governed by a MIT license
// that can be found in the LICENSE file.
package asynq
import (
"context"
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"sync"
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"testing"
"time"
"github.com/google/go-cmp/cmp"
"github.com/google/go-cmp/cmp/cmpopts"
"github.com/hibiken/asynq/internal/base"
"github.com/hibiken/asynq/internal/rdb"
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"github.com/hibiken/asynq/internal/testbroker"
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h "github.com/hibiken/asynq/internal/testutil"
"github.com/hibiken/asynq/internal/timeutil"
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)
// Test goes through a few phases.
//
// Phase1: Simulate Server startup; Simulate starting tasks listed in startedWorkers
// Phase2: Simulate finishing tasks listed in finishedTasks
// Phase3: Simulate Server shutdown;
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func TestHeartbeater(t *testing.T) {
r := setup(t)
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defer r.Close()
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rdbClient := rdb.NewRDB(r)
now := time.Now()
const elapsedTime = 10 * time.Second // simulated time elapsed between phase1 and phase2
clock := timeutil.NewSimulatedClock(time.Time{}) // time will be set in each test
t1 := h.NewTaskMessageWithQueue("task1", nil, "default")
t2 := h.NewTaskMessageWithQueue("task2", nil, "default")
t3 := h.NewTaskMessageWithQueue("task3", nil, "default")
t4 := h.NewTaskMessageWithQueue("task4", nil, "custom")
t5 := h.NewTaskMessageWithQueue("task5", nil, "custom")
t6 := h.NewTaskMessageWithQueue("task6", nil, "default")
// Note: intentionally set to time less than now.Add(rdb.LeaseDuration) to test lease extension is working.
lease1 := h.NewLeaseWithClock(now.Add(10*time.Second), clock)
lease2 := h.NewLeaseWithClock(now.Add(10*time.Second), clock)
lease3 := h.NewLeaseWithClock(now.Add(10*time.Second), clock)
lease4 := h.NewLeaseWithClock(now.Add(10*time.Second), clock)
lease5 := h.NewLeaseWithClock(now.Add(10*time.Second), clock)
lease6 := h.NewLeaseWithClock(now.Add(10*time.Second), clock)
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tests := []struct {
desc string
// Interval between heartbeats.
interval time.Duration
// Server info.
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host string
pid int
queues map[string]int
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concurrency int
active map[string][]*base.TaskMessage // initial active set state
lease map[string][]base.Z // initial lease set state
wantLease1 map[string][]base.Z // expected lease set state after starting all startedWorkers
wantLease2 map[string][]base.Z // expected lease set state after finishing all finishedTasks
startedWorkers []*workerInfo // workerInfo to send via the started channel
finishedTasks []*base.TaskMessage // tasks to send via the finished channel
startTime time.Time // simulated start time
elapsedTime time.Duration // simulated time elapsed between starting and finishing processing tasks
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}{
{
desc: "With single queue",
interval: 2 * time.Second,
host: "localhost",
pid: 45678,
queues: map[string]int{"default": 1},
concurrency: 10,
active: map[string][]*base.TaskMessage{
"default": {t1, t2, t3},
},
lease: map[string][]base.Z{
"default": {
{Message: t1, Score: now.Add(10 * time.Second).Unix()},
{Message: t2, Score: now.Add(10 * time.Second).Unix()},
{Message: t3, Score: now.Add(10 * time.Second).Unix()},
},
},
startedWorkers: []*workerInfo{
{msg: t1, started: now, deadline: now.Add(2 * time.Minute), lease: lease1},
{msg: t2, started: now, deadline: now.Add(2 * time.Minute), lease: lease2},
{msg: t3, started: now, deadline: now.Add(2 * time.Minute), lease: lease3},
},
finishedTasks: []*base.TaskMessage{t1, t2},
wantLease1: map[string][]base.Z{
"default": {
{Message: t1, Score: now.Add(rdb.LeaseDuration).Unix()},
{Message: t2, Score: now.Add(rdb.LeaseDuration).Unix()},
{Message: t3, Score: now.Add(rdb.LeaseDuration).Unix()},
},
},
wantLease2: map[string][]base.Z{
"default": {
{Message: t3, Score: now.Add(elapsedTime).Add(rdb.LeaseDuration).Unix()},
},
},
startTime: now,
elapsedTime: elapsedTime,
},
{
desc: "With multiple queue",
interval: 2 * time.Second,
host: "localhost",
pid: 45678,
queues: map[string]int{"default": 1, "custom": 2},
concurrency: 10,
active: map[string][]*base.TaskMessage{
"default": {t6},
"custom": {t4, t5},
},
lease: map[string][]base.Z{
"default": {
{Message: t6, Score: now.Add(10 * time.Second).Unix()},
},
"custom": {
{Message: t4, Score: now.Add(10 * time.Second).Unix()},
{Message: t5, Score: now.Add(10 * time.Second).Unix()},
},
},
startedWorkers: []*workerInfo{
{msg: t6, started: now, deadline: now.Add(2 * time.Minute), lease: lease6},
{msg: t4, started: now, deadline: now.Add(2 * time.Minute), lease: lease4},
{msg: t5, started: now, deadline: now.Add(2 * time.Minute), lease: lease5},
},
finishedTasks: []*base.TaskMessage{t6, t5},
wantLease1: map[string][]base.Z{
"default": {
{Message: t6, Score: now.Add(rdb.LeaseDuration).Unix()},
},
"custom": {
{Message: t4, Score: now.Add(rdb.LeaseDuration).Unix()},
{Message: t5, Score: now.Add(rdb.LeaseDuration).Unix()},
},
},
wantLease2: map[string][]base.Z{
"default": {},
"custom": {
{Message: t4, Score: now.Add(elapsedTime).Add(rdb.LeaseDuration).Unix()},
},
},
startTime: now,
elapsedTime: elapsedTime,
},
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}
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timeCmpOpt := cmpopts.EquateApproxTime(10 * time.Millisecond)
ignoreOpt := cmpopts.IgnoreUnexported(base.ServerInfo{})
ignoreFieldOpt := cmpopts.IgnoreFields(base.ServerInfo{}, "ServerID")
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for _, tc := range tests {
h.FlushDB(t, r)
h.SeedAllActiveQueues(t, r, tc.active)
h.SeedAllLease(t, r, tc.lease)
clock.SetTime(tc.startTime)
rdbClient.SetClock(clock)
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srvState := &serverState{}
startingCh := make(chan *workerInfo)
finishedCh := make(chan *base.TaskMessage)
hb := newHeartbeater(heartbeaterParams{
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logger: testLogger,
broker: rdbClient,
interval: tc.interval,
concurrency: tc.concurrency,
queues: tc.queues,
strictPriority: false,
state: srvState,
starting: startingCh,
finished: finishedCh,
})
hb.clock = clock
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// Change host and pid fields for testing purpose.
hb.host = tc.host
hb.pid = tc.pid
//===================
// Start Phase1
//===================
srvState.mu.Lock()
srvState.value = srvStateActive // simulating Server.Start
srvState.mu.Unlock()
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var wg sync.WaitGroup
hb.start(&wg)
// Simulate processor starting to work on tasks.
for _, w := range tc.startedWorkers {
startingCh <- w
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}
// Wait for heartbeater to write to redis
time.Sleep(tc.interval * 2)
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ss, err := rdbClient.ListServers()
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if err != nil {
t.Errorf("%s: could not read server info from redis: %v", tc.desc, err)
hb.shutdown()
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continue
}
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if len(ss) != 1 {
t.Errorf("%s: (*RDB).ListServers returned %d server info, want 1", tc.desc, len(ss))
hb.shutdown()
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continue
}
wantInfo := &base.ServerInfo{
Host: tc.host,
PID: tc.pid,
Queues: tc.queues,
Concurrency: tc.concurrency,
Started: now,
Status: "active",
ActiveWorkerCount: len(tc.startedWorkers),
}
if diff := cmp.Diff(wantInfo, ss[0], timeCmpOpt, ignoreOpt, ignoreFieldOpt); diff != "" {
t.Errorf("%s: redis stored server status %+v, want %+v; (-want, +got)\n%s", tc.desc, ss[0], wantInfo, diff)
hb.shutdown()
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continue
}
for qname, wantLease := range tc.wantLease1 {
gotLease := h.GetLeaseEntries(t, r, qname)
if diff := cmp.Diff(wantLease, gotLease, h.SortZSetEntryOpt); diff != "" {
t.Errorf("%s: mismatch found in %q: (-want,+got):\n%s", tc.desc, base.LeaseKey(qname), diff)
}
}
for _, w := range tc.startedWorkers {
if want := now.Add(rdb.LeaseDuration); w.lease.Deadline() != want {
t.Errorf("%s: lease deadline for %v is set to %v, want %v", tc.desc, w.msg, w.lease.Deadline(), want)
}
}
//===================
// Start Phase2
//===================
clock.AdvanceTime(tc.elapsedTime)
// Simulate processor finished processing tasks.
for _, msg := range tc.finishedTasks {
if err := rdbClient.Done(context.Background(), msg); err != nil {
t.Fatalf("RDB.Done failed: %v", err)
}
finishedCh <- msg
}
// Wait for heartbeater to write to redis
time.Sleep(tc.interval * 2)
for qname, wantLease := range tc.wantLease2 {
gotLease := h.GetLeaseEntries(t, r, qname)
if diff := cmp.Diff(wantLease, gotLease, h.SortZSetEntryOpt); diff != "" {
t.Errorf("%s: mismatch found in %q: (-want,+got):\n%s", tc.desc, base.LeaseKey(qname), diff)
}
}
//===================
// Start Phase3
//===================
// Server state change; simulating Server.Shutdown
srvState.mu.Lock()
srvState.value = srvStateClosed
srvState.mu.Unlock()
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// Wait for heartbeater to write to redis
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time.Sleep(tc.interval * 2)
wantInfo = &base.ServerInfo{
Host: tc.host,
PID: tc.pid,
Queues: tc.queues,
Concurrency: tc.concurrency,
Started: now,
Status: "closed",
ActiveWorkerCount: len(tc.startedWorkers) - len(tc.finishedTasks),
}
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ss, err = rdbClient.ListServers()
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if err != nil {
t.Errorf("%s: could not read server status from redis: %v", tc.desc, err)
hb.shutdown()
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continue
}
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if len(ss) != 1 {
t.Errorf("%s: (*RDB).ListServers returned %d server info, want 1", tc.desc, len(ss))
hb.shutdown()
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continue
}
if diff := cmp.Diff(wantInfo, ss[0], timeCmpOpt, ignoreOpt, ignoreFieldOpt); diff != "" {
t.Errorf("%s: redis stored process status %+v, want %+v; (-want, +got)\n%s", tc.desc, ss[0], wantInfo, diff)
hb.shutdown()
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continue
}
hb.shutdown()
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}
}
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func TestHeartbeaterWithRedisDown(t *testing.T) {
// Make sure that heartbeater goroutine doesn't panic
// if it cannot connect to redis.
defer func() {
if r := recover(); r != nil {
t.Errorf("panic occurred: %v", r)
}
}()
r := rdb.NewRDB(setup(t))
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defer r.Close()
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testBroker := testbroker.NewTestBroker(r)
state := &serverState{value: srvStateActive}
hb := newHeartbeater(heartbeaterParams{
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logger: testLogger,
broker: testBroker,
interval: time.Second,
concurrency: 10,
queues: map[string]int{"default": 1},
strictPriority: false,
state: state,
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starting: make(chan *workerInfo),
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finished: make(chan *base.TaskMessage),
})
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testBroker.Sleep()
var wg sync.WaitGroup
hb.start(&wg)
// wait for heartbeater to try writing data to redis
time.Sleep(2 * time.Second)
hb.shutdown()
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}