consul/agent/cache/cache_test.go

1851 lines
55 KiB
Go

package cache
import (
"context"
"errors"
"fmt"
"sort"
"sync"
"sync/atomic"
"testing"
"time"
"github.com/stretchr/testify/assert"
"github.com/stretchr/testify/mock"
"github.com/stretchr/testify/require"
"golang.org/x/time/rate"
"github.com/hashicorp/consul/acl"
"github.com/hashicorp/consul/lib/ttlcache"
"github.com/hashicorp/consul/sdk/testutil"
"github.com/hashicorp/consul/sdk/testutil/retry"
)
// Test a basic Get with no indexes (and therefore no blocking queries).
func TestCacheGet_noIndex(t *testing.T) {
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
typ.Static(FetchResult{Value: 42}, nil).Times(1)
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Get, should not fetch since we already have a satisfying value
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.True(t, meta.Hit)
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test a basic Get with no index and a failed fetch.
func TestCacheGet_initError(t *testing.T) {
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
fetcherr := fmt.Errorf("error")
typ.Static(FetchResult{}, fetcherr).Times(2)
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.Error(t, err)
require.Nil(t, result)
require.False(t, meta.Hit)
// Get, should fetch again since our last fetch was an error
result, meta, err = c.Get(context.Background(), "t", req)
require.Error(t, err)
require.Nil(t, result)
require.False(t, meta.Hit)
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test a cached error is replaced by a successful result. See
// https://github.com/hashicorp/consul/issues/4480
func TestCacheGet_cachedErrorsDontStick(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
fetcherr := fmt.Errorf("initial error")
// First fetch errors, subsequent fetches are successful and then block
typ.Static(FetchResult{}, fetcherr).Times(1)
typ.Static(FetchResult{Value: 42, Index: 123}, nil).Times(1)
// We trigger this to return same value to simulate a timeout.
triggerCh := make(chan time.Time)
typ.Static(FetchResult{Value: 42, Index: 123}, nil).WaitUntil(triggerCh)
// Get, should fetch and get error
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.Error(t, err)
require.Nil(t, result)
require.False(t, meta.Hit)
// Get, should fetch again since our last fetch was an error, but get success
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Now get should block until timeout and then get the same response NOT the
// cached error.
getCh1 := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{
Key: "hello",
MinIndex: 123,
// We _don't_ set a timeout here since that doesn't trigger the bug - the
// bug occurs when the Fetch call times out and returns the same value when
// an error is set. If it returns a new value the blocking loop works too.
}))
time.AfterFunc(50*time.Millisecond, func() {
// "Timeout" the Fetch after a short time.
close(triggerCh)
})
select {
case result := <-getCh1:
t.Fatalf("result or error returned before an update happened. "+
"If this is nil look above for the error log: %v", result)
case <-time.After(100 * time.Millisecond):
// It _should_ keep blocking for a new value here
}
// Sleep a tiny bit just to let maybe some background calls happen
// then verify the calls.
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test a Get with a request that returns a blank cache key. This should
// force a backend request and skip the cache entirely.
func TestCacheGet_blankCacheKey(t *testing.T) {
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
typ.Static(FetchResult{Value: 42}, nil).Times(2)
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: ""})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Get, should not fetch since we already have a satisfying value
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test that Get blocks on the initial value
func TestCacheGet_blockingInitSameKey(t *testing.T) {
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
triggerCh := make(chan time.Time)
typ.Static(FetchResult{Value: 42}, nil).WaitUntil(triggerCh).Times(1)
// Perform multiple gets
getCh1 := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
getCh2 := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
// They should block
select {
case <-getCh1:
t.Fatal("should block (ch1)")
case <-getCh2:
t.Fatal("should block (ch2)")
case <-time.After(50 * time.Millisecond):
}
// Trigger it
close(triggerCh)
// Should return
TestCacheGetChResult(t, getCh1, 42)
TestCacheGetChResult(t, getCh2, 42)
}
// Test that Get with different cache keys both block on initial value
// but that the fetches were both properly called.
func TestCacheGet_blockingInitDiffKeys(t *testing.T) {
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Keep track of the keys
var keysLock sync.Mutex
var keys []string
// Configure the type
triggerCh := make(chan time.Time)
typ.Static(FetchResult{Value: 42}, nil).
WaitUntil(triggerCh).
Times(2).
Run(func(args mock.Arguments) {
keysLock.Lock()
defer keysLock.Unlock()
keys = append(keys, args.Get(1).(Request).CacheInfo().Key)
})
// Perform multiple gets
getCh1 := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
getCh2 := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "goodbye"}))
// They should block
select {
case <-getCh1:
t.Fatal("should block (ch1)")
case <-getCh2:
t.Fatal("should block (ch2)")
case <-time.After(50 * time.Millisecond):
}
// Trigger it
close(triggerCh)
// Should return both!
TestCacheGetChResult(t, getCh1, 42)
TestCacheGetChResult(t, getCh2, 42)
// Verify proper keys
sort.Strings(keys)
require.Equal(t, []string{"goodbye", "hello"}, keys)
}
// Test a get with an index set will wait until an index that is higher
// is set in the cache.
func TestCacheGet_blockingIndex(t *testing.T) {
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
triggerCh := make(chan time.Time)
typ.Static(FetchResult{Value: 1, Index: 4}, nil).Once()
typ.Static(FetchResult{Value: 12, Index: 5}, nil).Once()
typ.Static(FetchResult{Value: 42, Index: 6}, nil).WaitUntil(triggerCh)
// Fetch should block
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{
Key: "hello", MinIndex: 5}))
// Should block
select {
case <-resultCh:
t.Fatal("should block")
case <-time.After(50 * time.Millisecond):
}
// Wait a bit
close(triggerCh)
// Should return
TestCacheGetChResult(t, resultCh, 42)
}
func TestCacheGet_cancellation(t *testing.T) {
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
typ.Static(FetchResult{Value: 1, Index: 4}, nil).Times(0).WaitUntil(time.After(1 * time.Millisecond))
ctx, cancel := context.WithDeadline(context.Background(), time.Now().Add(50*time.Millisecond))
// this is just to keep the linter happy
defer cancel()
result, _, err := c.Get(ctx, "t", TestRequest(t, RequestInfo{
Key: "hello", MinIndex: 5}))
require.Nil(t, result)
require.Error(t, err)
testutil.RequireErrorContains(t, err, context.DeadlineExceeded.Error())
}
// Test a get with an index set will timeout if the fetch doesn't return
// anything.
func TestCacheGet_blockingIndexTimeout(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
triggerCh := make(chan time.Time)
typ.Static(FetchResult{Value: 1, Index: 4}, nil).Once()
typ.Static(FetchResult{Value: 12, Index: 5}, nil).Once()
typ.Static(FetchResult{Value: 42, Index: 6}, nil).WaitUntil(triggerCh)
// Fetch should block
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{
Key: "hello", MinIndex: 5, Timeout: 200 * time.Millisecond}))
// Should block
select {
case <-resultCh:
t.Fatal("should block")
case <-time.After(50 * time.Millisecond):
}
// Should return after more of the timeout
select {
case result := <-resultCh:
require.Equal(t, 12, result)
case <-time.After(300 * time.Millisecond):
t.Fatal("should've returned")
}
}
// Test a get with an index set with requests returning an error
// will return that error.
func TestCacheGet_blockingIndexError(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
var retries uint32
fetchErr := fmt.Errorf("test fetch error")
typ.Static(FetchResult{Value: 1, Index: 4}, nil).Once()
typ.Static(FetchResult{Value: nil, Index: 5}, fetchErr).Run(func(args mock.Arguments) {
atomic.AddUint32(&retries, 1)
})
// First good fetch to populate catch
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 1)
// Fetch should not block and should return error
resultCh = TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{
Key: "hello", MinIndex: 7, Timeout: 1 * time.Minute}))
TestCacheGetChResult(t, resultCh, nil)
// Wait a bit
time.Sleep(100 * time.Millisecond)
// Check the number
actual := atomic.LoadUint32(&retries)
require.True(t, actual < 10, fmt.Sprintf("actual: %d", actual))
}
// Test that if a Type returns an empty value on Fetch that the previous
// value is preserved.
func TestCacheGet_emptyFetchResult(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
stateCh := make(chan int, 1)
// Configure the type
typ.Static(FetchResult{Value: 42, State: 31, Index: 1}, nil).Times(1)
// Return different State, it should NOT be ignored
typ.Static(FetchResult{Value: nil, State: 32}, nil).Run(func(args mock.Arguments) {
// We should get back the original state
opts := args.Get(0).(FetchOptions)
require.NotNil(t, opts.LastResult)
stateCh <- opts.LastResult.State.(int)
})
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Get, should not fetch since we already have a satisfying value
req = TestRequest(t, RequestInfo{
Key: "hello", MinIndex: 1, Timeout: 100 * time.Millisecond})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// State delivered to second call should be the result from first call.
select {
case state := <-stateCh:
require.Equal(t, 31, state)
case <-time.After(20 * time.Millisecond):
t.Fatal("timed out")
}
// Next request should get the SECOND returned state even though the fetch
// returns nil and so the previous result is used.
req = TestRequest(t, RequestInfo{
Key: "hello", MinIndex: 1, Timeout: 100 * time.Millisecond})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
select {
case state := <-stateCh:
require.Equal(t, 32, state)
case <-time.After(20 * time.Millisecond):
t.Fatal("timed out")
}
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test that a type registered with a periodic refresh will perform
// that refresh after the timer is up.
func TestCacheGet_periodicRefresh(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
Refresh: true,
RefreshTimer: 100 * time.Millisecond,
QueryTimeout: 5 * time.Minute,
})
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// This is a bit weird, but we do this to ensure that the final
// call to the Fetch (if it happens, depends on timing) just blocks.
triggerCh := make(chan time.Time)
defer close(triggerCh)
// Configure the type
typ.Static(FetchResult{Value: 1, Index: 4}, nil).Once()
typ.Static(FetchResult{Value: 12, Index: 5}, nil).Once()
typ.Static(FetchResult{Value: 12, Index: 5}, nil).WaitUntil(triggerCh)
// Fetch should block
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 1)
// Fetch again almost immediately should return old result
time.Sleep(5 * time.Millisecond)
resultCh = TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 1)
// Wait for the timer
time.Sleep(200 * time.Millisecond)
resultCh = TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 12)
}
// Test that a type registered with a periodic refresh will perform
// that refresh after the timer is up.
func TestCacheGet_periodicRefreshMultiple(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
Refresh: true,
RefreshTimer: 0 * time.Millisecond,
QueryTimeout: 5 * time.Minute,
})
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// This is a bit weird, but we do this to ensure that the final
// call to the Fetch (if it happens, depends on timing) just blocks.
trigger := make([]chan time.Time, 3)
for i := range trigger {
trigger[i] = make(chan time.Time)
}
// Configure the type
typ.Static(FetchResult{Value: 1, Index: 4}, nil).Once()
typ.Static(FetchResult{Value: 12, Index: 5}, nil).Once().WaitUntil(trigger[0])
typ.Static(FetchResult{Value: 24, Index: 6}, nil).Once().WaitUntil(trigger[1])
typ.Static(FetchResult{Value: 42, Index: 7}, nil).WaitUntil(trigger[2])
// Fetch should block
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 1)
// Fetch again almost immediately should return old result
time.Sleep(5 * time.Millisecond)
resultCh = TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 1)
// Trigger the next, sleep a bit, and verify we get the next result
close(trigger[0])
time.Sleep(100 * time.Millisecond)
resultCh = TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 12)
// Trigger the next, sleep a bit, and verify we get the next result
close(trigger[1])
time.Sleep(100 * time.Millisecond)
resultCh = TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 24)
}
// Test that a refresh performs a backoff.
func TestCacheGet_periodicRefreshErrorBackoff(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
Refresh: true,
RefreshTimer: 0,
QueryTimeout: 5 * time.Minute,
})
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
var retries uint32
fetchErr := fmt.Errorf("test fetch error")
typ.Static(FetchResult{Value: 1, Index: 4}, nil).Once()
typ.Static(FetchResult{Value: nil, Index: 5}, fetchErr).Run(func(args mock.Arguments) {
atomic.AddUint32(&retries, 1)
})
// Fetch
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 1)
// Sleep a bit. The refresh will quietly fail in the background. What we
// want to verify is that it doesn't retry too much. "Too much" is hard
// to measure since its CPU dependent if this test is failing. But due
// to the short sleep below, we can calculate about what we'd expect if
// backoff IS working.
time.Sleep(500 * time.Millisecond)
// Fetch should work, we should get a 1 still. Errors are ignored.
resultCh = TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 1)
// Check the number
actual := atomic.LoadUint32(&retries)
require.True(t, actual < 10, fmt.Sprintf("actual: %d", actual))
}
// Test that a badly behaved RPC that returns 0 index will perform a backoff.
func TestCacheGet_periodicRefreshBadRPCZeroIndexErrorBackoff(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
Refresh: true,
RefreshTimer: 0,
QueryTimeout: 5 * time.Minute,
})
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
var retries uint32
typ.Static(FetchResult{Value: 0, Index: 0}, nil).Run(func(args mock.Arguments) {
atomic.AddUint32(&retries, 1)
})
// Fetch
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 0)
// Sleep a bit. The refresh will quietly fail in the background. What we
// want to verify is that it doesn't retry too much. "Too much" is hard
// to measure since its CPU dependent if this test is failing. But due
// to the short sleep below, we can calculate about what we'd expect if
// backoff IS working.
time.Sleep(500 * time.Millisecond)
// Fetch should work, we should get a 0 still. Errors are ignored.
resultCh = TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 0)
// Check the number
actual := atomic.LoadUint32(&retries)
require.True(t, actual < 10, fmt.Sprintf("%d retries, should be < 10", actual))
}
// Test that fetching with no index makes an initial request with no index, but
// then ensures all background refreshes have > 0. This ensures we don't end up
// with any index 0 loops from background refreshed while also returning
// immediately on the initial request if there is no data written to that table
// yet.
func TestCacheGet_noIndexSetsOne(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
SupportsBlocking: true,
Refresh: true,
RefreshTimer: 0,
QueryTimeout: 5 * time.Minute,
})
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Simulate "well behaved" RPC with no data yet but returning 1
{
first := int32(1)
typ.Static(FetchResult{Value: 0, Index: 1}, nil).Run(func(args mock.Arguments) {
opts := args.Get(0).(FetchOptions)
isFirst := atomic.SwapInt32(&first, 0)
if isFirst == 1 {
assert.Equal(t, uint64(0), opts.MinIndex)
} else {
assert.True(t, opts.MinIndex > 0, "minIndex > 0")
}
})
// Fetch
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 0)
// Sleep a bit so background refresh happens
time.Sleep(100 * time.Millisecond)
}
// Same for "badly behaved" RPC that returns 0 index and no data
{
first := int32(1)
typ.Static(FetchResult{Value: 0, Index: 0}, nil).Run(func(args mock.Arguments) {
opts := args.Get(0).(FetchOptions)
isFirst := atomic.SwapInt32(&first, 0)
if isFirst == 1 {
assert.Equal(t, uint64(0), opts.MinIndex)
} else {
assert.True(t, opts.MinIndex > 0, "minIndex > 0")
}
})
// Fetch
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 0)
// Sleep a bit so background refresh happens
time.Sleep(100 * time.Millisecond)
}
}
// Test that the backend fetch sets the proper timeout.
func TestCacheGet_fetchTimeout(t *testing.T) {
t.Parallel()
typ := &MockType{}
timeout := 10 * time.Minute
typ.On("RegisterOptions").Return(RegisterOptions{
QueryTimeout: timeout,
SupportsBlocking: true,
})
defer typ.AssertExpectations(t)
c := New(Options{})
// Register the type with a timeout
c.RegisterType("t", typ)
// Configure the type
var actual time.Duration
typ.Static(FetchResult{Value: 42}, nil).Times(1).Run(func(args mock.Arguments) {
opts := args.Get(0).(FetchOptions)
actual = opts.Timeout
})
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Test the timeout
require.Equal(t, timeout, actual)
}
// Test that entries expire
func TestCacheGet_expire(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
LastGetTTL: 400 * time.Millisecond,
})
defer typ.AssertExpectations(t)
c := New(Options{})
// Register the type with a timeout
c.RegisterType("t", typ)
// Configure the type
typ.Static(FetchResult{Value: 42}, nil).Times(2)
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Wait for a non-trivial amount of time to sanity check the age increases at
// least this amount. Note that this is not a fudge for some timing-dependent
// background work it's just ensuring a non-trivial time elapses between the
// request above and below serially in this thread so short time is OK.
time.Sleep(5 * time.Millisecond)
// Get, should not fetch, verified via the mock assertions above
req = TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.True(t, meta.Hit)
require.True(t, meta.Age > 5*time.Millisecond)
// Sleep for the expiry
time.Sleep(500 * time.Millisecond)
// Get, should fetch
req = TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Sleep a tiny bit just to let maybe some background calls happen then verify
// that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test that entries expire for background refresh types that cancel fetch on
// eviction. This is really a special case of the test below where the close
// behavior of the type forces the timing that causes the race but it's worth
// keeping explicitly anyway to make sure this behavior is supported and
// doesn't introduce any different races.
func TestCacheGet_expireBackgroudRefreshCancel(t *testing.T) {
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
LastGetTTL: 400 * time.Millisecond,
Refresh: true,
RefreshTimer: 0,
SupportsBlocking: true,
})
defer typ.AssertExpectations(t)
c := New(Options{})
// Register the type with a timeout
c.RegisterType("t", typ)
// Create a cache state that is a closer that cancels the context on close
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
closer := &testCloser{
closeFn: func() {
cancel()
},
}
// Configure the type
typ.On("Fetch", mock.Anything, mock.Anything).
Return(func(o FetchOptions, r Request) FetchResult {
return FetchResult{Value: 8, Index: 4, State: closer}
}, func(o FetchOptions, r Request) error {
if o.MinIndex == 4 {
// Simulate waiting for a new value on second call until the cache type
// is evicted
<-ctx.Done()
return ctx.Err()
}
return nil
})
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 8, result)
require.Equal(t, uint64(4), meta.Index)
require.False(t, meta.Hit)
// Get, should not fetch, verified via the mock assertions above
req = TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 8, result)
require.Equal(t, uint64(4), meta.Index)
require.True(t, meta.Hit)
// Sleep for the expiry
time.Sleep(500 * time.Millisecond)
// Get, should fetch
req = TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 8, result)
require.Equal(t, uint64(4), meta.Index)
require.False(t, meta.Hit, "the fetch should not have re-populated the cache "+
"entry after it expired so this get should be a miss")
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test that entries expire for background refresh types that return before any
// watcher re-fetches.
func TestCacheGet_expireBackgroudRefresh(t *testing.T) {
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
LastGetTTL: 400 * time.Millisecond,
Refresh: true,
RefreshTimer: 0,
SupportsBlocking: true,
})
defer typ.AssertExpectations(t)
c := New(Options{})
// Register the type with a timeout
c.RegisterType("t", typ)
ctrlCh := make(chan struct{})
// Configure the type
typ.On("Fetch", mock.Anything, mock.Anything).
Return(func(o FetchOptions, r Request) FetchResult {
if o.MinIndex == 4 {
// Simulate returning from fetch (after a timeout with no value change)
// at a time controlled by the test to ensure we interleave requests.
<-ctrlCh
}
return FetchResult{Value: 8, Index: 4}
}, func(o FetchOptions, r Request) error {
return nil
})
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 8, result)
require.Equal(t, uint64(4), meta.Index)
require.False(t, meta.Hit)
// Get, should not fetch, verified via the mock assertions above
req = TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 8, result)
require.Equal(t, uint64(4), meta.Index)
require.True(t, meta.Hit)
// Sleep for the expiry
time.Sleep(500 * time.Millisecond)
// Now (after expiry) let the fetch call return
close(ctrlCh)
// Get, should fetch (it didn't originally because the fetch return would
// re-insert the value back into the cache and make it live forever).
req = TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 8, result)
require.Equal(t, uint64(4), meta.Index)
require.False(t, meta.Hit, "the fetch should not have re-populated the cache "+
"entry after it expired so this get should be a miss")
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test that entries reset their TTL on Get
func TestCacheGet_expireResetGet(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
LastGetTTL: 150 * time.Millisecond,
})
defer typ.AssertExpectations(t)
c := New(Options{})
// Register the type with a timeout
c.RegisterType("t", typ)
// Configure the type
typ.Static(FetchResult{Value: 42}, nil).Times(2)
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Fetch multiple times, where the total time is well beyond
// the TTL. We should not trigger any fetches during this time.
for i := 0; i < 5; i++ {
// Sleep a bit
time.Sleep(50 * time.Millisecond)
// Get, should not fetch
req = TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.True(t, meta.Hit)
}
time.Sleep(200 * time.Millisecond)
// Get, should fetch
req = TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test that entries reset their TTL on Get even when the value isn't changing
func TestCacheGet_expireResetGetNoChange(t *testing.T) {
t.Parallel()
// Create a closer so we can tell if the entry gets evicted.
closer := &testCloser{}
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
LastGetTTL: 150 * time.Millisecond,
SupportsBlocking: true,
Refresh: true,
})
typ.On("Fetch", mock.Anything, mock.Anything).
Return(func(o FetchOptions, r Request) FetchResult {
if o.MinIndex == 10 {
// Simulate a very fast timeout from the backend. This must be shorter
// than the TTL above (as it would be in real life) so that fetch returns
// a few times with the same value which _should_ cause the blocking watch
// to go round the Get loop and so keep the cache entry from being
// evicted.
time.Sleep(10 * time.Millisecond)
}
return FetchResult{Value: 42, Index: 10, State: closer}
}, func(o FetchOptions, r Request) error {
return nil
})
defer typ.AssertExpectations(t)
c := New(Options{})
// Register the type with a timeout
c.RegisterType("t", typ)
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.Equal(t, uint64(10), meta.Index)
require.False(t, meta.Hit)
// Do a blocking watch of the value that won't time out until after the TTL.
start := time.Now()
req = TestRequest(t, RequestInfo{Key: "hello", MinIndex: 10, Timeout: 300 * time.Millisecond})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.Equal(t, uint64(10), meta.Index)
require.GreaterOrEqual(t, time.Since(start).Milliseconds(), int64(300))
// This is the point of this test! Even though we waited for a change for
// longer than the TTL, we should have been updating the TTL so that the cache
// entry should not have been evicted. We can't verify that with meta.Hit
// since that is not set for blocking Get calls but we can assert that the
// entry was never closed (which assuming the test for eviction closing is
// also passing is a reliable signal).
require.False(t, closer.isClosed(), "cache entry should not have been evicted")
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test that entries with state that satisfies io.Closer get cleaned up
func TestCacheGet_expireClose(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := &MockType{}
defer typ.AssertExpectations(t)
c := New(Options{})
defer c.Close()
typ.On("RegisterOptions").Return(RegisterOptions{
SupportsBlocking: true,
LastGetTTL: 100 * time.Millisecond,
})
// Register the type with a timeout
c.RegisterType("t", typ)
// Configure the type
state := &testCloser{}
typ.Static(FetchResult{Value: 42, State: state}, nil).Times(1)
ctx := context.Background()
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(ctx, "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
require.False(t, state.isClosed())
// Sleep for the expiry
time.Sleep(200 * time.Millisecond)
// state.Close() should have been called
require.True(t, state.isClosed())
}
type testCloser struct {
closed uint32
closeFn func()
}
func (t *testCloser) Close() error {
atomic.SwapUint32(&t.closed, 1)
if t.closeFn != nil {
t.closeFn()
}
return nil
}
func (t *testCloser) isClosed() bool {
return atomic.LoadUint32(&t.closed) == 1
}
// Test a Get with a request that returns the same cache key across
// two different "types" returns two separate results.
func TestCacheGet_duplicateKeyDifferentType(t *testing.T) {
t.Parallel()
typ := TestType(t)
defer typ.AssertExpectations(t)
typ2 := TestType(t)
defer typ2.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
c.RegisterType("t2", typ2)
// Configure the types
typ.Static(FetchResult{Value: 100}, nil)
typ2.Static(FetchResult{Value: 200}, nil)
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "foo"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 100, result)
require.False(t, meta.Hit)
// Get from t2 with same key, should fetch
req = TestRequest(t, RequestInfo{Key: "foo"})
result, meta, err = c.Get(context.Background(), "t2", req)
require.NoError(t, err)
require.Equal(t, 200, result)
require.False(t, meta.Hit)
// Get from t again with same key, should cache
req = TestRequest(t, RequestInfo{Key: "foo"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 100, result)
require.True(t, meta.Hit)
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
typ2.AssertExpectations(t)
}
// Test that Get partitions the caches based on DC so two equivalent requests
// to different datacenters are automatically cached even if their keys are
// the same.
func TestCacheGet_partitionDC(t *testing.T) {
t.Parallel()
c := New(Options{})
c.RegisterType("t", &testPartitionType{})
// Perform multiple gets
getCh1 := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{
Datacenter: "dc1", Key: "hello"}))
getCh2 := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{
Datacenter: "dc9", Key: "hello"}))
// Should return both!
TestCacheGetChResult(t, getCh1, "dc1")
TestCacheGetChResult(t, getCh2, "dc9")
}
// Test that Get partitions the caches based on token so two equivalent requests
// with different ACL tokens do not return the same result.
func TestCacheGet_partitionToken(t *testing.T) {
t.Parallel()
c := New(Options{})
c.RegisterType("t", &testPartitionType{})
// Perform multiple gets
getCh1 := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{
Token: "", Key: "hello"}))
getCh2 := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{
Token: "foo", Key: "hello"}))
// Should return both!
TestCacheGetChResult(t, getCh1, "")
TestCacheGetChResult(t, getCh2, "foo")
}
// testPartitionType implements Type for testing that simply returns a value
// comprised of the request DC and ACL token, used for testing cache
// partitioning.
type testPartitionType struct{}
func (t *testPartitionType) Fetch(opts FetchOptions, r Request) (FetchResult, error) {
info := r.CacheInfo()
return FetchResult{
Value: fmt.Sprintf("%s%s", info.Datacenter, info.Token),
}, nil
}
func (t *testPartitionType) RegisterOptions() RegisterOptions {
return RegisterOptions{
SupportsBlocking: true,
}
}
// Test that background refreshing reports correct Age in failure and happy
// states.
func TestCacheGet_refreshAge(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
if testing.Short() {
t.Skip("too slow for -short run")
}
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
Refresh: true,
RefreshTimer: 0,
QueryTimeout: 5 * time.Minute,
})
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
var index, shouldFail uint64
typ.On("Fetch", mock.Anything, mock.Anything).
Return(func(o FetchOptions, r Request) FetchResult {
idx := atomic.LoadUint64(&index)
if atomic.LoadUint64(&shouldFail) == 1 {
return FetchResult{Value: nil, Index: idx}
}
if o.MinIndex == idx {
// Simulate waiting for a new value
time.Sleep(5 * time.Millisecond)
}
return FetchResult{Value: int(idx * 2), Index: idx}
}, func(o FetchOptions, r Request) error {
if atomic.LoadUint64(&shouldFail) == 1 {
return errors.New("test error")
}
return nil
})
// Set initial index/value
atomic.StoreUint64(&index, 4)
// Fetch
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 8)
{
// Wait a few milliseconds after initial fetch to check age is not reporting
// actual age.
time.Sleep(2 * time.Millisecond)
// Fetch again, non-blocking
result, meta, err := c.Get(context.Background(), "t", TestRequest(t, RequestInfo{Key: "hello"}))
require.NoError(t, err)
require.Equal(t, 8, result)
require.True(t, meta.Hit)
// Age should be zero since background refresh was "active"
require.Equal(t, time.Duration(0), meta.Age)
}
// Now fail the next background sync
atomic.StoreUint64(&shouldFail, 1)
// Wait until the current request times out and starts failing. The request
// should take a maximum of 5ms to return but give it some headroom to allow
// it to finish 5ms sleep, unblock and next background request to be attemoted
// and fail and state updated in noisy CI... We might want to retry if this is
// still flaky but see if a longer wait is sufficient for now.
time.Sleep(50 * time.Millisecond)
var lastAge time.Duration
{
result, meta, err := c.Get(context.Background(), "t", TestRequest(t, RequestInfo{Key: "hello"}))
require.NoError(t, err)
require.Equal(t, 8, result)
require.True(t, meta.Hit)
// Age should be non-zero since background refresh was "active"
require.True(t, meta.Age > 0)
lastAge = meta.Age
}
// Wait a bit longer - age should increase by at least this much
time.Sleep(5 * time.Millisecond)
{
result, meta, err := c.Get(context.Background(), "t", TestRequest(t, RequestInfo{Key: "hello"}))
require.NoError(t, err)
require.Equal(t, 8, result)
require.True(t, meta.Hit)
require.True(t, meta.Age > (lastAge+(1*time.Millisecond)))
}
// Now unfail the background refresh
atomic.StoreUint64(&shouldFail, 0)
// And update the data so we can see when the background task is working again
// (won't be immediate due to backoff on the errors).
atomic.AddUint64(&index, 1)
t0 := time.Now()
timeout := true
// Allow up to 5 seconds since the error backoff is likely to have kicked in
// and causes this to take different amounts of time depending on how quickly
// the test thread got down here relative to the failures.
for attempts := 0; attempts < 50; attempts++ {
time.Sleep(100 * time.Millisecond)
result, meta, err := c.Get(context.Background(), "t", TestRequest(t, RequestInfo{Key: "hello"}))
// Should never error even if background is failing as we have cached value
require.NoError(t, err)
require.True(t, meta.Hit)
// Got the new value!
if result == 10 {
// Age should be zero since background refresh is "active" again
t.Logf("Succeeded after %d attempts", attempts)
require.Equal(t, time.Duration(0), meta.Age)
timeout = false
break
}
}
require.False(t, timeout, "failed to observe update after %s", time.Since(t0))
}
func TestCacheGet_nonRefreshAge(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ := &MockType{}
typ.On("RegisterOptions").Return(RegisterOptions{
Refresh: false,
LastGetTTL: 100 * time.Millisecond,
})
defer typ.AssertExpectations(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
var index uint64
typ.On("Fetch", mock.Anything, mock.Anything).
Return(func(o FetchOptions, r Request) FetchResult {
idx := atomic.LoadUint64(&index)
return FetchResult{Value: int(idx * 2), Index: idx}
}, nil)
// Set initial index/value
atomic.StoreUint64(&index, 4)
// Fetch
resultCh := TestCacheGetCh(t, c, "t", TestRequest(t, RequestInfo{Key: "hello"}))
TestCacheGetChResult(t, resultCh, 8)
var lastAge time.Duration
{
// Wait a few milliseconds after initial fetch to check age IS reporting
// actual age.
time.Sleep(5 * time.Millisecond)
// Fetch again, non-blocking
result, meta, err := c.Get(context.Background(), "t", TestRequest(t, RequestInfo{Key: "hello"}))
require.NoError(t, err)
require.Equal(t, 8, result)
require.True(t, meta.Hit)
require.True(t, meta.Age > (5*time.Millisecond))
lastAge = meta.Age
}
// Wait for expiry
time.Sleep(200 * time.Millisecond)
{
result, meta, err := c.Get(context.Background(), "t", TestRequest(t, RequestInfo{Key: "hello"}))
require.NoError(t, err)
require.Equal(t, 8, result)
require.False(t, meta.Hit)
// Age should smaller again
require.True(t, meta.Age < lastAge)
}
{
// Wait for a non-trivial amount of time to sanity check the age increases at
// least this amount. Note that this is not a fudge for some timing-dependent
// background work it's just ensuring a non-trivial time elapses between the
// request above and below serilaly in this thread so short time is OK.
time.Sleep(5 * time.Millisecond)
// Fetch again, non-blocking
result, meta, err := c.Get(context.Background(), "t", TestRequest(t, RequestInfo{Key: "hello"}))
require.NoError(t, err)
require.Equal(t, 8, result)
require.True(t, meta.Hit)
require.True(t, meta.Age > (5*time.Millisecond))
lastAge = meta.Age
}
// Now verify that setting MaxAge results in cache invalidation
{
result, meta, err := c.Get(context.Background(), "t", TestRequest(t, RequestInfo{
Key: "hello",
MaxAge: 1 * time.Millisecond,
}))
require.NoError(t, err)
require.Equal(t, 8, result)
require.False(t, meta.Hit)
// Age should smaller again
require.True(t, meta.Age < lastAge)
}
}
func TestCacheGet_nonBlockingType(t *testing.T) {
t.Parallel()
typ := TestTypeNonBlocking(t)
c := New(Options{})
c.RegisterType("t", typ)
// Configure the type
typ.Static(FetchResult{Value: 42, Index: 1}, nil).Once()
typ.Static(FetchResult{Value: 43, Index: 2}, nil).Twice().
Run(func(args mock.Arguments) {
opts := args.Get(0).(FetchOptions)
// MinIndex should never be set for a non-blocking type.
require.Equal(t, uint64(0), opts.MinIndex)
})
// Get, should fetch
req := TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err := c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.False(t, meta.Hit)
// Get, should not fetch since we have a cached value
req = TestRequest(t, RequestInfo{Key: "hello"})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.True(t, meta.Hit)
// Get, should not attempt to fetch with blocking even if requested. The
// assertions below about the value being the same combined with the fact the
// mock will only return that value on first call suffice to show that
// blocking request is not being attempted.
req = TestRequest(t, RequestInfo{
Key: "hello",
MinIndex: 1,
Timeout: 10 * time.Minute,
})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 42, result)
require.True(t, meta.Hit)
time.Sleep(10 * time.Millisecond)
// Get with a max age should fetch again
req = TestRequest(t, RequestInfo{Key: "hello", MaxAge: 5 * time.Millisecond})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 43, result)
require.False(t, meta.Hit)
// Get with a must revalidate should fetch again even without a delay.
req = TestRequest(t, RequestInfo{Key: "hello", MustRevalidate: true})
result, meta, err = c.Get(context.Background(), "t", req)
require.NoError(t, err)
require.Equal(t, 43, result)
require.False(t, meta.Hit)
// Sleep a tiny bit just to let maybe some background calls happen
// then verify that we still only got the one call
time.Sleep(20 * time.Millisecond)
typ.AssertExpectations(t)
}
// Test a get with an index set will wait until an index that is higher
// is set in the cache.
func TestCacheReload(t *testing.T) {
t.Parallel()
typ1 := TestType(t)
defer typ1.AssertExpectations(t)
c := New(Options{EntryFetchRate: rate.Limit(1), EntryFetchMaxBurst: 1})
c.RegisterType("t1", typ1)
typ1.Mock.On("Fetch", mock.Anything, mock.Anything).Return(FetchResult{Value: 42, Index: 42}, nil).Maybe()
require.False(t, c.ReloadOptions(Options{EntryFetchRate: rate.Limit(1), EntryFetchMaxBurst: 1}), "Value should not be reloaded")
_, meta, err := c.Get(context.Background(), "t1", TestRequest(t, RequestInfo{Key: "hello1", MinIndex: uint64(1)}))
require.NoError(t, err)
require.Equal(t, meta.Index, uint64(42))
testEntry := func(t *testing.T, doTest func(t *testing.T, entry cacheEntry)) {
c.entriesLock.Lock()
tEntry, ok := c.types["t1"]
require.True(t, ok)
keyName := makeEntryKey("t1", "", "", "", "hello1")
ok, entryValid, entry := c.getEntryLocked(tEntry, keyName, RequestInfo{})
require.True(t, ok)
require.True(t, entryValid)
doTest(t, entry)
c.entriesLock.Unlock()
}
testEntry(t, func(t *testing.T, entry cacheEntry) {
require.Equal(t, entry.FetchRateLimiter.Limit(), rate.Limit(1))
require.Equal(t, entry.FetchRateLimiter.Burst(), 1)
})
// Modify only rateLimit
require.True(t, c.ReloadOptions(Options{EntryFetchRate: rate.Limit(100), EntryFetchMaxBurst: 1}))
testEntry(t, func(t *testing.T, entry cacheEntry) {
require.Equal(t, entry.FetchRateLimiter.Limit(), rate.Limit(100))
require.Equal(t, entry.FetchRateLimiter.Burst(), 1)
})
// Modify only Burst
require.True(t, c.ReloadOptions(Options{EntryFetchRate: rate.Limit(100), EntryFetchMaxBurst: 5}))
testEntry(t, func(t *testing.T, entry cacheEntry) {
require.Equal(t, entry.FetchRateLimiter.Limit(), rate.Limit(100))
require.Equal(t, entry.FetchRateLimiter.Burst(), 5)
})
// Modify only Burst and Limit at the same time
require.True(t, c.ReloadOptions(Options{EntryFetchRate: rate.Limit(1000), EntryFetchMaxBurst: 42}))
testEntry(t, func(t *testing.T, entry cacheEntry) {
require.Equal(t, entry.FetchRateLimiter.Limit(), rate.Limit(1000))
require.Equal(t, entry.FetchRateLimiter.Burst(), 42)
})
}
// TestCacheThrottle checks the assumptions for the cache throttling. It sets
// up a cache with Options{EntryFetchRate: 10.0, EntryFetchMaxBurst: 1}, which
// allows for 10req/s, or one request every 100ms.
// It configures two different cache types with each 3 updates. Each type has
// its own rate limiter which starts initially full, and we expect the
// following requests when creating blocking queries against both waiting for
// the third update:
// at ~0ms: typ1 and typ2 receive first value and are blocked until
// ~100ms: typ1 and typ2 receive second value and are blocked until
// ~200ms: typ1 and typ2 receive third value which we check
//
// This test will verify waiting with a blocking query for the last update will
// block for 190ms and only afterwards have the expected result.
// It demonstrates the ratelimiting waits for the expected amount of time and
// also that each type has its own ratelimiter, because results for both types
// are arriving at similar times, which wouldn't be the case if they use a
// shared limiter.
func TestCacheThrottle(t *testing.T) {
if testing.Short() {
t.Skip("too slow for testing.Short")
}
t.Parallel()
typ1 := TestType(t)
typ2 := TestType(t)
defer typ1.AssertExpectations(t)
defer typ2.AssertExpectations(t)
c := New(Options{EntryFetchRate: 10.0, EntryFetchMaxBurst: 1})
c.RegisterType("t1", typ1)
c.RegisterType("t2", typ2)
// Configure the type
typ1.Static(FetchResult{Value: 1, Index: 4}, nil).Once()
typ1.Static(FetchResult{Value: 12, Index: 5}, nil).Once()
typ1.Static(FetchResult{Value: 42, Index: 6}, nil).Once()
typ2.Static(FetchResult{Value: 1, Index: 4}, nil).Once()
typ2.Static(FetchResult{Value: 12, Index: 5}, nil).Once()
typ2.Static(FetchResult{Value: 43, Index: 6}, nil).Once()
result1Ch := TestCacheGetCh(t, c, "t1", TestRequest(t, RequestInfo{
Key: "hello1", MinIndex: 5}))
result2Ch := TestCacheGetCh(t, c, "t2", TestRequest(t, RequestInfo{
Key: "hello2", MinIndex: 5}))
select {
case <-result1Ch:
t.Fatal("result1Ch should block")
case <-result2Ch:
t.Fatal("result2Ch should block")
case <-time.After(190 * time.Millisecond):
}
after := time.After(30 * time.Millisecond)
var res1, res2 bool
OUT:
for {
select {
case result := <-result1Ch:
require.Equal(t, 42, result)
res1 = true
case result := <-result2Ch:
require.Equal(t, 43, result)
res2 = true
case <-after:
t.Fatal("shouldn't block that long")
}
if res1 && res2 {
break OUT
}
}
}
func TestCache_ExpiryLoop_ExitsWhenStopped(t *testing.T) {
c := &Cache{
stopCh: make(chan struct{}),
entries: make(map[string]cacheEntry),
entriesExpiryHeap: ttlcache.NewExpiryHeap(),
}
chStart := make(chan struct{})
chDone := make(chan struct{})
go func() {
close(chStart)
c.runExpiryLoop()
close(chDone)
}()
<-chStart
close(c.stopCh)
select {
case <-chDone:
case <-time.After(50 * time.Millisecond):
t.Fatalf("expected loop to exit when stopped")
}
}
func TestCache_Prepopulate(t *testing.T) {
typ := &fakeType{index: 5}
c := New(Options{})
c.RegisterType("t", typ)
c.Prepopulate("t", FetchResult{Value: 17, Index: 1}, "dc1", "", "token", "v1")
ctx := context.Background()
req := fakeRequest{
info: RequestInfo{
Key: "v1",
Token: "token",
Datacenter: "dc1",
MinIndex: 1,
},
}
result, _, err := c.Get(ctx, "t", req)
require.NoError(t, err)
require.Equal(t, 17, result)
}
func TestCache_RefreshLifeCycle(t *testing.T) {
typ := &MockType{}
t.Cleanup(func() { typ.AssertExpectations(t) })
typ.On("RegisterOptions").Times(0).Return(RegisterOptions{
// Maintain a blocking query, retry dropped connections quickly
Refresh: true,
SupportsBlocking: true,
RefreshTimer: 0 * time.Second,
QueryTimeout: 10 * time.Minute,
})
makeRequest := func(index uint64) fakeRequest {
return fakeRequest{
info: RequestInfo{
Key: "v1",
Token: "token",
Datacenter: "dc1",
MinIndex: index,
},
}
}
typ.On("Fetch", mock.Anything, mock.Anything).Once().Return(FetchResult{
Value: true,
Index: 2,
}, nil)
releaseSecondReq := make(chan time.Time)
typ.On("Fetch", mock.Anything, mock.Anything).Once().Return(FetchResult{}, acl.PermissionDenied("forced error")).WaitUntil(releaseSecondReq)
releaseThirdReq := make(chan time.Time)
typ.On("Fetch", mock.Anything, mock.Anything).Once().Return(FetchResult{}, acl.ErrNotFound).WaitUntil(releaseThirdReq)
c := New(Options{})
c.RegisterType("t", typ)
key := makeEntryKey("t", "dc1", "", "token", "v1")
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
// get the background refresh going
result, _, err := c.Get(ctx, "t", makeRequest(1))
require.NoError(t, err)
require.Equal(t, true, result)
waitUntilFetching := func(expectValue bool) {
retry.Run(t, func(t *retry.R) {
c.entriesLock.Lock()
defer c.entriesLock.Unlock()
entry, ok := c.entries[key]
require.True(t, ok)
if expectValue {
require.True(t, entry.Fetching)
} else {
require.False(t, entry.Fetching)
}
})
}
// ensure that the entry is fetching again
waitUntilFetching(true)
requestChan := make(chan error)
getError := func(index uint64) {
_, _, err := c.Get(ctx, "t", makeRequest(index))
if ctx.Err() != nil {
return
}
requestChan <- err
}
// background a call that will wait for a newer version
go getError(2)
// I really dislike the arbitrary sleep here. However we want to test out some of the
// branching in getWithIndex (called by Get) and that doesn't expose any way for us to
// know when that go routine has gotten far enough and is waiting on the latest value.
// Therefore the only thing we can do for now is to sleep long enough to let that
// go routine progress far enough.
time.Sleep(100 * time.Millisecond)
// release the blocking query to simulate an ACL permission denied error
close(releaseSecondReq)
// ensure we were woken up and see the permission denied error
select {
case err := <-requestChan:
require.True(t, acl.IsErrPermissionDenied(err))
case <-time.After(500 * time.Millisecond):
require.Fail(t, "blocking cache Get never returned")
}
// ensure that the entry is fetching again
waitUntilFetching(true)
// background a call that will wait for a newer version - will result in an acl not found error
go getError(5)
// Same arbitrary sleep as the one after the second request and the same reasoning.
time.Sleep(100 * time.Millisecond)
// release the blocking query to simulate an ACL not found error
close(releaseThirdReq)
// ensure we were woken up and see the ACL not found error
select {
case err := <-requestChan:
require.True(t, acl.IsErrNotFound(err))
case <-time.After(500 * time.Millisecond):
require.Fail(t, "blocking cache Get never returned")
}
// ensure that the ACL not found error killed off the background refresh
// but didn't remove it from the cache
waitUntilFetching(false)
}
type fakeType struct {
index uint64
}
func (f fakeType) Fetch(_ FetchOptions, _ Request) (FetchResult, error) {
idx := atomic.LoadUint64(&f.index)
return FetchResult{Value: int(idx * 2), Index: idx}, nil
}
func (f fakeType) RegisterOptions() RegisterOptions {
return RegisterOptions{Refresh: true}
}
var _ Type = (*fakeType)(nil)
type fakeRequest struct {
info RequestInfo
}
func (f fakeRequest) CacheInfo() RequestInfo {
return f.info
}
var _ Request = (*fakeRequest)(nil)