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prometheus/storage/metric/tiered.go
Matt T. Proud b2e4c88b80 Wrap LevelDB iterator operations behind interface. 
The LevelDB storage types return an interface type now that wraps
around the underlying iterator.  This both enhances testability but
improves upon, in my opinion, the interface design for the LevelDB
iterator.

Secondarily, the resource reaping behaviors for the LevelDB iterators
have been improved by dropping the externalized io.Closer object.

Finally, the iterator provisioning methods provide the option for
indicating whether one wants a snapshotted iterator or not.
2013-03-25 12:57:58 +01:00

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// Copyright 2013 Prometheus Team
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package metric
import (
"fmt"
"github.com/prometheus/prometheus/coding"
"github.com/prometheus/prometheus/coding/indexable"
"github.com/prometheus/prometheus/model"
dto "github.com/prometheus/prometheus/model/generated"
"github.com/prometheus/prometheus/storage"
"github.com/prometheus/prometheus/storage/raw/leveldb"
"sort"
"sync"
"time"
)
// tieredStorage both persists samples and generates materialized views for
// queries.
type tieredStorage struct {
appendToDiskQueue chan model.Sample
appendToMemoryQueue chan model.Sample
diskFrontier *diskFrontier
diskStorage *LevelDBMetricPersistence
draining chan chan bool
flushMemoryInterval time.Duration
memoryArena memorySeriesStorage
memoryTTL time.Duration
mutex sync.Mutex
viewQueue chan viewJob
writeMemoryInterval time.Duration
}
// viewJob encapsulates a request to extract sample values from the datastore.
type viewJob struct {
builder ViewRequestBuilder
output chan View
err chan error
}
// Provides a unified means for batch appending values into the datastore along
// with querying for values in an efficient way.
type Storage interface {
// Enqueues a Sample for storage.
AppendSample(model.Sample) error
// Enqueus a ViewRequestBuilder for materialization, subject to a timeout.
MakeView(request ViewRequestBuilder, timeout time.Duration) (View, error)
// Starts serving requests.
Serve()
// Stops the storage subsystem, flushing all pending operations.
Drain()
Flush()
Close()
// MetricPersistence proxy methods.
GetAllMetricNames() ([]string, error)
GetFingerprintsForLabelSet(model.LabelSet) (model.Fingerprints, error)
GetMetricForFingerprint(model.Fingerprint) (m *model.Metric, err error)
}
func NewTieredStorage(appendToMemoryQueueDepth, appendToDiskQueueDepth, viewQueueDepth uint, flushMemoryInterval, writeMemoryInterval, memoryTTL time.Duration, root string) Storage {
diskStorage, err := NewLevelDBMetricPersistence(root)
if err != nil {
panic(err)
}
return &tieredStorage{
appendToDiskQueue: make(chan model.Sample, appendToDiskQueueDepth),
appendToMemoryQueue: make(chan model.Sample, appendToMemoryQueueDepth),
diskStorage: diskStorage,
draining: make(chan chan bool),
flushMemoryInterval: flushMemoryInterval,
memoryArena: NewMemorySeriesStorage(),
memoryTTL: memoryTTL,
viewQueue: make(chan viewJob, viewQueueDepth),
writeMemoryInterval: writeMemoryInterval,
}
}
func (t *tieredStorage) AppendSample(s model.Sample) (err error) {
if len(t.draining) > 0 {
return fmt.Errorf("Storage is in the process of draining.")
}
t.appendToMemoryQueue <- s
return
}
func (t *tieredStorage) Drain() {
drainingDone := make(chan bool)
if len(t.draining) == 0 {
t.draining <- drainingDone
}
<-drainingDone
}
func (t *tieredStorage) MakeView(builder ViewRequestBuilder, deadline time.Duration) (view View, err error) {
if len(t.draining) > 0 {
err = fmt.Errorf("Storage is in the process of draining.")
return
}
result := make(chan View)
errChan := make(chan error)
t.viewQueue <- viewJob{
builder: builder,
output: result,
err: errChan,
}
select {
case value := <-result:
view = value
case err = <-errChan:
return
case <-time.After(deadline):
err = fmt.Errorf("MakeView timed out after %s.", deadline)
}
return
}
func (t *tieredStorage) rebuildDiskFrontier() (err error) {
begin := time.Now()
defer func() {
duration := time.Since(begin)
recordOutcome(duration, err, map[string]string{operation: appendSample, result: success}, map[string]string{operation: rebuildDiskFrontier, result: failure})
}()
i := t.diskStorage.metricSamples.NewIterator(true)
defer i.Close()
t.diskFrontier, err = newDiskFrontier(i)
if err != nil {
panic(err)
}
return
}
func (t *tieredStorage) Serve() {
var (
flushMemoryTicker = time.Tick(t.flushMemoryInterval)
writeMemoryTicker = time.Tick(t.writeMemoryInterval)
)
for {
t.reportQueues()
select {
case <-writeMemoryTicker:
t.writeMemory()
case <-flushMemoryTicker:
t.flushMemory()
case viewRequest := <-t.viewQueue:
t.renderView(viewRequest)
case drainingDone := <-t.draining:
t.flush()
drainingDone <- true
break
}
}
}
func (t *tieredStorage) reportQueues() {
queueSizes.Set(map[string]string{"queue": "append_to_disk", "facet": "occupancy"}, float64(len(t.appendToDiskQueue)))
queueSizes.Set(map[string]string{"queue": "append_to_disk", "facet": "capacity"}, float64(cap(t.appendToDiskQueue)))
queueSizes.Set(map[string]string{"queue": "append_to_memory", "facet": "occupancy"}, float64(len(t.appendToMemoryQueue)))
queueSizes.Set(map[string]string{"queue": "append_to_memory", "facet": "capacity"}, float64(cap(t.appendToMemoryQueue)))
queueSizes.Set(map[string]string{"queue": "view_generation", "facet": "occupancy"}, float64(len(t.viewQueue)))
queueSizes.Set(map[string]string{"queue": "view_generation", "facet": "capacity"}, float64(cap(t.viewQueue)))
}
func (t *tieredStorage) writeMemory() {
begin := time.Now()
defer func() {
duration := time.Since(begin)
recordOutcome(duration, nil, map[string]string{operation: appendSample, result: success}, map[string]string{operation: writeMemory, result: failure})
}()
t.mutex.Lock()
defer t.mutex.Unlock()
pendingLength := len(t.appendToMemoryQueue)
for i := 0; i < pendingLength; i++ {
t.memoryArena.AppendSample(<-t.appendToMemoryQueue)
}
}
func (t *tieredStorage) Flush() {
t.flush()
}
func (t *tieredStorage) Close() {
t.Drain()
t.diskStorage.Close()
}
// Write all pending appends.
func (t *tieredStorage) flush() (err error) {
// Trim any old values to reduce iterative write costs.
t.flushMemory()
t.writeMemory()
t.flushMemory()
return
}
type memoryToDiskFlusher struct {
toDiskQueue chan model.Sample
disk MetricPersistence
olderThan time.Time
valuesAccepted int
valuesRejected int
}
type memoryToDiskFlusherVisitor struct {
stream stream
flusher *memoryToDiskFlusher
}
func (f memoryToDiskFlusherVisitor) DecodeKey(in interface{}) (out interface{}, err error) {
out = time.Time(in.(skipListTime))
return
}
func (f memoryToDiskFlusherVisitor) DecodeValue(in interface{}) (out interface{}, err error) {
out = in.(value).get()
return
}
func (f memoryToDiskFlusherVisitor) Filter(key, value interface{}) (filterResult storage.FilterResult) {
var (
recordTime = key.(time.Time)
)
if recordTime.Before(f.flusher.olderThan) {
f.flusher.valuesAccepted++
return storage.ACCEPT
}
f.flusher.valuesRejected++
return storage.STOP
}
func (f memoryToDiskFlusherVisitor) Operate(key, value interface{}) (err *storage.OperatorError) {
var (
recordTime = key.(time.Time)
recordValue = value.(model.SampleValue)
)
if len(f.flusher.toDiskQueue) == cap(f.flusher.toDiskQueue) {
f.flusher.Flush()
}
f.flusher.toDiskQueue <- model.Sample{
Metric: f.stream.metric,
Timestamp: recordTime,
Value: recordValue,
}
f.stream.values.Delete(skipListTime(recordTime))
return
}
func (f *memoryToDiskFlusher) ForStream(stream stream) (decoder storage.RecordDecoder, filter storage.RecordFilter, operator storage.RecordOperator) {
visitor := memoryToDiskFlusherVisitor{
stream: stream,
flusher: f,
}
// fmt.Printf("fingerprint -> %s\n", model.NewFingerprintFromMetric(stream.metric).ToRowKey())
return visitor, visitor, visitor
}
func (f *memoryToDiskFlusher) Flush() {
length := len(f.toDiskQueue)
samples := model.Samples{}
for i := 0; i < length; i++ {
samples = append(samples, <-f.toDiskQueue)
}
start := time.Now()
f.disk.AppendSamples(samples)
if false {
fmt.Printf("Took %s to append...\n", time.Since(start))
}
}
func (f memoryToDiskFlusher) Close() {
f.Flush()
}
// Persist a whole bunch of samples to the datastore.
func (t *tieredStorage) flushMemory() {
begin := time.Now()
defer func() {
duration := time.Since(begin)
recordOutcome(duration, nil, map[string]string{operation: appendSample, result: success}, map[string]string{operation: flushMemory, result: failure})
}()
t.mutex.Lock()
defer t.mutex.Unlock()
flusher := &memoryToDiskFlusher{
disk: t.diskStorage,
olderThan: time.Now().Add(-1 * t.memoryTTL),
toDiskQueue: t.appendToDiskQueue,
}
defer flusher.Close()
t.memoryArena.ForEachSample(flusher)
return
}
func (t *tieredStorage) renderView(viewJob viewJob) {
// Telemetry.
var err error
begin := time.Now()
defer func() {
duration := time.Since(begin)
recordOutcome(duration, err, map[string]string{operation: renderView, result: success}, map[string]string{operation: renderView, result: failure})
}()
t.mutex.Lock()
defer t.mutex.Unlock()
var (
scans = viewJob.builder.ScanJobs()
view = newView()
)
// Rebuilding of the frontier should happen on a conditional basis if a
// (fingerprint, timestamp) tuple is outside of the current frontier.
err = t.rebuildDiskFrontier()
if err != nil {
panic(err)
}
if t.diskFrontier == nil {
// Storage still empty, return an empty view.
viewJob.output <- view
return
}
// Get a single iterator that will be used for all data extraction below.
iterator := t.diskStorage.metricSamples.NewIterator(true)
defer iterator.Close()
for _, scanJob := range scans {
seriesFrontier, err := newSeriesFrontier(scanJob.fingerprint, *t.diskFrontier, iterator)
if err != nil {
panic(err)
}
if seriesFrontier == nil {
continue
}
standingOps := scanJob.operations
for len(standingOps) > 0 {
// Load data value chunk(s) around the first standing op's current time.
highWatermark := *standingOps[0].CurrentTime()
// XXX: For earnest performance gains analagous to the benchmarking we
// performed, chunk should only be reloaded if it no longer contains
// the values we're looking for.
//
// To better understand this, look at https://github.com/prometheus/prometheus/blob/benchmark/leveldb/iterator-seek-characteristics/leveldb.go#L239 and note the behavior around retrievedValue.
chunk := t.loadChunkAroundTime(iterator, seriesFrontier, scanJob.fingerprint, highWatermark)
lastChunkTime := chunk[len(chunk)-1].Timestamp
if lastChunkTime.After(highWatermark) {
highWatermark = lastChunkTime
}
// For each op, extract all needed data from the current chunk.
out := []model.SamplePair{}
for _, op := range standingOps {
if op.CurrentTime().After(highWatermark) {
break
}
for op.CurrentTime() != nil && !op.CurrentTime().After(highWatermark) {
out = op.ExtractSamples(chunk)
}
}
// Append the extracted samples to the materialized view.
for _, sample := range out {
view.appendSample(scanJob.fingerprint, sample.Timestamp, sample.Value)
}
// Throw away standing ops which are finished.
filteredOps := ops{}
for _, op := range standingOps {
if op.CurrentTime() != nil {
filteredOps = append(filteredOps, op)
}
}
standingOps = filteredOps
// Sort ops by start time again, since they might be slightly off now.
// For example, consider a current chunk of values and two interval ops
// with different interval lengths. Their states after the cycle above
// could be:
//
// (C = current op time)
//
// Chunk: [ X X X X X ]
// Op 1: [ X X C . . . ]
// Op 2: [ X X C . . .]
//
// Op 2 now has an earlier current time than Op 1.
sort.Sort(startsAtSort{standingOps})
}
}
viewJob.output <- view
return
}
func (t *tieredStorage) loadChunkAroundTime(iterator leveldb.Iterator, frontier *seriesFrontier, fingerprint model.Fingerprint, ts time.Time) (chunk []model.SamplePair) {
var (
targetKey = &dto.SampleKey{
Fingerprint: fingerprint.ToDTO(),
}
foundKey = &dto.SampleKey{}
foundValue *dto.SampleValueSeries
)
// Limit the target key to be within the series' keyspace.
if ts.After(frontier.lastSupertime) {
targetKey.Timestamp = indexable.EncodeTime(frontier.lastSupertime)
} else {
targetKey.Timestamp = indexable.EncodeTime(ts)
}
// Try seeking to target key.
rawKey, _ := coding.NewProtocolBufferEncoder(targetKey).Encode()
iterator.Seek(rawKey)
foundKey, err := extractSampleKey(iterator)
if err != nil {
panic(err)
}
// Figure out if we need to rewind by one block.
// Imagine the following supertime blocks with time ranges:
//
// Block 1: ft 1000 - lt 1009 <data>
// Block 1: ft 1010 - lt 1019 <data>
//
// If we are aiming to find time 1005, we would first seek to the block with
// supertime 1010, then need to rewind by one block by virtue of LevelDB
// iterator seek behavior.
//
// Only do the rewind if there is another chunk before this one.
rewound := false
firstTime := indexable.DecodeTime(foundKey.Timestamp)
if ts.Before(firstTime) && !frontier.firstSupertime.After(ts) {
iterator.Previous()
rewound = true
}
foundValue, err = extractSampleValues(iterator)
if err != nil {
panic(err)
}
// If we rewound, but the target time is still past the current block, return
// the last value of the current (rewound) block and the entire next block.
if rewound {
foundKey, err = extractSampleKey(iterator)
if err != nil {
panic(err)
}
currentChunkLastTime := time.Unix(*foundKey.LastTimestamp, 0)
if ts.After(currentChunkLastTime) {
sampleCount := len(foundValue.Value)
chunk = append(chunk, model.SamplePair{
Timestamp: time.Unix(*foundValue.Value[sampleCount-1].Timestamp, 0),
Value: model.SampleValue(*foundValue.Value[sampleCount-1].Value),
})
// We know there's a next block since we have rewound from it.
iterator.Next()
foundValue, err = extractSampleValues(iterator)
if err != nil {
panic(err)
}
}
}
// Now append all the samples of the currently seeked block to the output.
for _, sample := range foundValue.Value {
chunk = append(chunk, model.SamplePair{
Timestamp: time.Unix(*sample.Timestamp, 0),
Value: model.SampleValue(*sample.Value),
})
}
return
}
func (t *tieredStorage) GetAllMetricNames() ([]string, error) {
// TODO: handle memory persistence as well.
return t.diskStorage.GetAllMetricNames()
}
func (t *tieredStorage) GetFingerprintsForLabelSet(labelSet model.LabelSet) (model.Fingerprints, error) {
// TODO: handle memory persistence as well.
return t.diskStorage.GetFingerprintsForLabelSet(labelSet)
}
func (t *tieredStorage) GetMetricForFingerprint(f model.Fingerprint) (m *model.Metric, err error) {
// TODO: handle memory persistence as well.
return t.diskStorage.GetMetricForFingerprint(f)
}
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