// Copyright 2017 The Prometheus Authors
// 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 tsdb implements a time series storage for float64 sample data.
package tsdb
import (
"context"
"fmt"
"io"
"io/ioutil"
"math"
"os"
"path/filepath"
"sort"
"strconv"
"strings"
"sync"
"time"
"github.com/go-kit/log"
"github.com/go-kit/log/level"
"github.com/oklog/ulid"
"github.com/pkg/errors"
"github.com/prometheus/client_golang/prometheus"
"golang.org/x/sync/errgroup"
"github.com/prometheus/prometheus/pkg/labels"
"github.com/prometheus/prometheus/storage"
"github.com/prometheus/prometheus/tsdb/chunkenc"
"github.com/prometheus/prometheus/tsdb/chunks"
tsdb_errors "github.com/prometheus/prometheus/tsdb/errors"
"github.com/prometheus/prometheus/tsdb/fileutil"
_ "github.com/prometheus/prometheus/tsdb/goversion" // Load the package into main to make sure minium Go version is met.
"github.com/prometheus/prometheus/tsdb/wal"
)
const (
// Default duration of a block in milliseconds.
DefaultBlockDuration = int64 ( 2 * time . Hour / time . Millisecond )
// Block dir suffixes to make deletion and creation operations atomic.
// We decided to do suffixes instead of creating meta.json as last (or delete as first) one,
// because in error case you still can recover meta.json from the block content within local TSDB dir.
// TODO(bwplotka): TSDB can end up with various .tmp files (e.g meta.json.tmp, WAL or segment tmp file. Think
// about removing those too on start to save space. Currently only blocks tmp dirs are removed.
tmpForDeletionBlockDirSuffix = ".tmp-for-deletion"
tmpForCreationBlockDirSuffix = ".tmp-for-creation"
// Pre-2.21 tmp dir suffix, used in clean-up functions.
tmpLegacy = ".tmp"
lockfileDisabled = - 1
lockfileReplaced = 0
lockfileCreatedCleanly = 1
)
var (
// ErrNotReady is returned if the underlying storage is not ready yet.
ErrNotReady = errors . New ( "TSDB not ready" )
)
// DefaultOptions used for the DB. They are sane for setups using
// millisecond precision timestamps.
func DefaultOptions ( ) * Options {
return & Options {
WALSegmentSize : wal . DefaultSegmentSize ,
MaxBlockChunkSegmentSize : chunks . DefaultChunkSegmentSize ,
RetentionDuration : int64 ( 15 * 24 * time . Hour / time . Millisecond ) ,
MinBlockDuration : DefaultBlockDuration ,
MaxBlockDuration : DefaultBlockDuration ,
NoLockfile : false ,
AllowOverlappingBlocks : false ,
WALCompression : false ,
StripeSize : DefaultStripeSize ,
HeadChunksWriteBufferSize : chunks . DefaultWriteBufferSize ,
}
}
// Options of the DB storage.
type Options struct {
// Segments (wal files) max size.
// WALSegmentSize = 0, segment size is default size.
// WALSegmentSize > 0, segment size is WALSegmentSize.
// WALSegmentSize < 0, wal is disabled.
WALSegmentSize int
// MaxBlockChunkSegmentSize is the max size of block chunk segment files.
// MaxBlockChunkSegmentSize = 0, chunk segment size is default size.
// MaxBlockChunkSegmentSize > 0, chunk segment size is MaxBlockChunkSegmentSize.
MaxBlockChunkSegmentSize int64
// Duration of persisted data to keep.
// Unit agnostic as long as unit is consistent with MinBlockDuration and MaxBlockDuration.
// Typically it is in milliseconds.
RetentionDuration int64
// Maximum number of bytes in blocks to be retained.
// 0 or less means disabled.
// NOTE: For proper storage calculations need to consider
// the size of the WAL folder which is not added when calculating
// the current size of the database.
MaxBytes int64
// NoLockfile disables creation and consideration of a lock file.
NoLockfile bool
// Overlapping blocks are allowed if AllowOverlappingBlocks is true.
// This in-turn enables vertical compaction and vertical query merge.
AllowOverlappingBlocks bool
// WALCompression will turn on Snappy compression for records on the WAL.
WALCompression bool
// StripeSize is the size in entries of the series hash map. Reducing the size will save memory but impact performance.
StripeSize int
// The timestamp range of head blocks after which they get persisted.
// It's the minimum duration of any persisted block.
// Unit agnostic as long as unit is consistent with RetentionDuration and MaxBlockDuration.
// Typically it is in milliseconds.
MinBlockDuration int64
// The maximum timestamp range of compacted blocks.
// Unit agnostic as long as unit is consistent with MinBlockDuration and RetentionDuration.
// Typically it is in milliseconds.
MaxBlockDuration int64
// HeadChunksWriteBufferSize configures the write buffer size used by the head chunks mapper.
HeadChunksWriteBufferSize int
// SeriesLifecycleCallback specifies a list of callbacks that will be called during a lifecycle of a series.
// It is always a no-op in Prometheus and mainly meant for external users who import TSDB.
SeriesLifecycleCallback SeriesLifecycleCallback
// BlocksToDelete is a function which returns the blocks which can be deleted.
// It is always the default time and size based retention in Prometheus and
// mainly meant for external users who import TSDB.
BlocksToDelete BlocksToDeleteFunc
// MaxExemplars sets the size, in # of exemplars stored, of the single circular buffer used to store exemplars in memory.
// See tsdb/exemplar.go, specifically the CircularExemplarStorage struct and it's constructor NewCircularExemplarStorage.
MaxExemplars int
}
type BlocksToDeleteFunc func ( blocks [ ] * Block ) map [ ulid . ULID ] struct { }
// DB handles reads and writes of time series falling into
// a hashed partition of a seriedb.
type DB struct {
dir string
lockf fileutil . Releaser
lockfPath string
logger log . Logger
metrics * dbMetrics
opts * Options
chunkPool chunkenc . Pool
compactor Compactor
blocksToDelete BlocksToDeleteFunc
// Mutex for that must be held when modifying the general block layout.
mtx sync . RWMutex
blocks [ ] * Block
head * Head
compactc chan struct { }
donec chan struct { }
stopc chan struct { }
// cmtx ensures that compactions and deletions don't run simultaneously.
cmtx sync . Mutex
// autoCompactMtx ensures that no compaction gets triggered while
// changing the autoCompact var.
autoCompactMtx sync . Mutex
autoCompact bool
// Cancel a running compaction when a shutdown is initiated.
compactCancel context . CancelFunc
}
type dbMetrics struct {
loadedBlocks prometheus . GaugeFunc
symbolTableSize prometheus . GaugeFunc
reloads prometheus . Counter
reloadsFailed prometheus . Counter
compactionsFailed prometheus . Counter
compactionsTriggered prometheus . Counter
compactionsSkipped prometheus . Counter
sizeRetentionCount prometheus . Counter
timeRetentionCount prometheus . Counter
startTime prometheus . GaugeFunc
tombCleanTimer prometheus . Histogram
blocksBytes prometheus . Gauge
maxBytes prometheus . Gauge
lockfileCreatedCleanly prometheus . Gauge
}
func newDBMetrics ( db * DB , r prometheus . Registerer ) * dbMetrics {
m := & dbMetrics { }
m . loadedBlocks = prometheus . NewGaugeFunc ( prometheus . GaugeOpts {
Name : "prometheus_tsdb_blocks_loaded" ,
Help : "Number of currently loaded data blocks" ,
} , func ( ) float64 {
db . mtx . RLock ( )
defer db . mtx . RUnlock ( )
return float64 ( len ( db . blocks ) )
} )
m . symbolTableSize = prometheus . NewGaugeFunc ( prometheus . GaugeOpts {
Name : "prometheus_tsdb_symbol_table_size_bytes" ,
Help : "Size of symbol table in memory for loaded blocks" ,
} , func ( ) float64 {
db . mtx . RLock ( )
blocks := db . blocks [ : ]
db . mtx . RUnlock ( )
symTblSize := uint64 ( 0 )
for _ , b := range blocks {
symTblSize += b . GetSymbolTableSize ( )
}
return float64 ( symTblSize )
} )
m . reloads = prometheus . NewCounter ( prometheus . CounterOpts {
Name : "prometheus_tsdb_reloads_total" ,
Help : "Number of times the database reloaded block data from disk." ,
} )
m . reloadsFailed = prometheus . NewCounter ( prometheus . CounterOpts {
Name : "prometheus_tsdb_reloads_failures_total" ,
Help : "Number of times the database failed to reloadBlocks block data from disk." ,
} )
m . compactionsTriggered = prometheus . NewCounter ( prometheus . CounterOpts {
Name : "prometheus_tsdb_compactions_triggered_total" ,
Help : "Total number of triggered compactions for the partition." ,
} )
m . compactionsFailed = prometheus . NewCounter ( prometheus . CounterOpts {
Name : "prometheus_tsdb_compactions_failed_total" ,
Help : "Total number of compactions that failed for the partition." ,
} )
m . timeRetentionCount = prometheus . NewCounter ( prometheus . CounterOpts {
Name : "prometheus_tsdb_time_retentions_total" ,
Help : "The number of times that blocks were deleted because the maximum time limit was exceeded." ,
} )
m . compactionsSkipped = prometheus . NewCounter ( prometheus . CounterOpts {
Name : "prometheus_tsdb_compactions_skipped_total" ,
Help : "Total number of skipped compactions due to disabled auto compaction." ,
} )
m . startTime = prometheus . NewGaugeFunc ( prometheus . GaugeOpts {
Name : "prometheus_tsdb_lowest_timestamp" ,
Help : "Lowest timestamp value stored in the database. The unit is decided by the library consumer." ,
} , func ( ) float64 {
db . mtx . RLock ( )
defer db . mtx . RUnlock ( )
if len ( db . blocks ) == 0 {
return float64 ( db . head . MinTime ( ) )
}
return float64 ( db . blocks [ 0 ] . meta . MinTime )
} )
m . tombCleanTimer = prometheus . NewHistogram ( prometheus . HistogramOpts {
Name : "prometheus_tsdb_tombstone_cleanup_seconds" ,
Help : "The time taken to recompact blocks to remove tombstones." ,
} )
m . blocksBytes = prometheus . NewGauge ( prometheus . GaugeOpts {
Name : "prometheus_tsdb_storage_blocks_bytes" ,
Help : "The number of bytes that are currently used for local storage by all blocks." ,
} )
m . maxBytes = prometheus . NewGauge ( prometheus . GaugeOpts {
Name : "prometheus_tsdb_retention_limit_bytes" ,
Help : "Max number of bytes to be retained in the tsdb blocks, configured 0 means disabled" ,
} )
m . sizeRetentionCount = prometheus . NewCounter ( prometheus . CounterOpts {
Name : "prometheus_tsdb_size_retentions_total" ,
Help : "The number of times that blocks were deleted because the maximum number of bytes was exceeded." ,
} )
m . lockfileCreatedCleanly = prometheus . NewGauge ( prometheus . GaugeOpts {
Name : "prometheus_tsdb_clean_start" ,
Help : "-1: lockfile is disabled. 0: a lockfile from a previous execution was replaced. 1: lockfile creation was clean" ,
} )
if r != nil {
r . MustRegister (
m . loadedBlocks ,
m . symbolTableSize ,
m . reloads ,
m . reloadsFailed ,
m . compactionsFailed ,
m . compactionsTriggered ,
m . compactionsSkipped ,
m . sizeRetentionCount ,
m . timeRetentionCount ,
m . startTime ,
m . tombCleanTimer ,
m . blocksBytes ,
m . maxBytes ,
m . lockfileCreatedCleanly ,
)
}
return m
}
// DBStats contains statistics about the DB seperated by component (eg. head).
// They are available before the DB has finished initializing.
type DBStats struct {
Head * HeadStats
}
// NewDBStats returns a new DBStats object initialized using the
// the new function from each component.
func NewDBStats ( ) * DBStats {
return & DBStats {
Head : NewHeadStats ( ) ,
}
}
// ErrClosed is returned when the db is closed.
var ErrClosed = errors . New ( "db already closed" )
// DBReadOnly provides APIs for read only operations on a database.
// Current implementation doesn't support concurrency so
// all API calls should happen in the same go routine.
type DBReadOnly struct {
logger log . Logger
dir string
closers [ ] io . Closer
closed chan struct { }
}
// OpenDBReadOnly opens DB in the given directory for read only operations.
func OpenDBReadOnly ( dir string , l log . Logger ) ( * DBReadOnly , error ) {
if _ , err := os . Stat ( dir ) ; err != nil {
return nil , errors . Wrap ( err , "opening the db dir" )
}
if l == nil {
l = log . NewNopLogger ( )
}
return & DBReadOnly {
logger : l ,
dir : dir ,
closed : make ( chan struct { } ) ,
} , nil
}
// FlushWAL creates a new block containing all data that's currently in the memory buffer/WAL.
// Samples that are in existing blocks will not be written to the new block.
// Note that if the read only database is running concurrently with a
// writable database then writing the WAL to the database directory can race.
func ( db * DBReadOnly ) FlushWAL ( dir string ) ( returnErr error ) {
blockReaders , err := db . Blocks ( )
if err != nil {
return errors . Wrap ( err , "read blocks" )
}
maxBlockTime := int64 ( math . MinInt64 )
if len ( blockReaders ) > 0 {
maxBlockTime = blockReaders [ len ( blockReaders ) - 1 ] . Meta ( ) . MaxTime
}
w , err := wal . Open ( db . logger , filepath . Join ( db . dir , "wal" ) )
if err != nil {
return err
}
opts := DefaultHeadOptions ( )
opts . ChunkDirRoot = db . dir
head , err := NewHead ( nil , db . logger , w , opts , NewHeadStats ( ) )
if err != nil {
return err
}
defer func ( ) {
returnErr = tsdb_errors . NewMulti (
returnErr ,
errors . Wrap ( head . Close ( ) , "closing Head" ) ,
) . Err ( )
} ( )
// Set the min valid time for the ingested wal samples
// to be no lower than the maxt of the last block.
if err := head . Init ( maxBlockTime ) ; err != nil {
return errors . Wrap ( err , "read WAL" )
}
mint := head . MinTime ( )
maxt := head . MaxTime ( )
rh := NewRangeHead ( head , mint , maxt )
compactor , err := NewLeveledCompactor (
context . Background ( ) ,
nil ,
db . logger ,
ExponentialBlockRanges ( DefaultOptions ( ) . MinBlockDuration , 3 , 5 ) ,
chunkenc . NewPool ( ) ,
nil ,
)
if err != nil {
return errors . Wrap ( err , "create leveled compactor" )
}
// Add +1 millisecond to block maxt because block intervals are half-open: [b.MinTime, b.MaxTime).
// Because of this block intervals are always +1 than the total samples it includes.
_ , err = compactor . Write ( dir , rh , mint , maxt + 1 , nil )
return errors . Wrap ( err , "writing WAL" )
}
func ( db * DBReadOnly ) loadDataAsQueryable ( maxt int64 ) ( storage . SampleAndChunkQueryable , error ) {
select {
case <- db . closed :
return nil , ErrClosed
default :
}
blockReaders , err := db . Blocks ( )
if err != nil {
return nil , err
}
blocks := make ( [ ] * Block , len ( blockReaders ) )
for i , b := range blockReaders {
b , ok := b . ( * Block )
if ! ok {
return nil , errors . New ( "unable to convert a read only block to a normal block" )
}
blocks [ i ] = b
}
opts := DefaultHeadOptions ( )
opts . ChunkDirRoot = db . dir
head , err := NewHead ( nil , db . logger , nil , opts , NewHeadStats ( ) )
if err != nil {
return nil , err
}
maxBlockTime := int64 ( math . MinInt64 )
if len ( blocks ) > 0 {
maxBlockTime = blocks [ len ( blocks ) - 1 ] . Meta ( ) . MaxTime
}
// Also add the WAL if the current blocks don't cover the requests time range.
if maxBlockTime <= maxt {
if err := head . Close ( ) ; err != nil {
return nil , err
}
w , err := wal . Open ( db . logger , filepath . Join ( db . dir , "wal" ) )
if err != nil {
return nil , err
}
opts := DefaultHeadOptions ( )
opts . ChunkDirRoot = db . dir
head , err = NewHead ( nil , db . logger , w , opts , NewHeadStats ( ) )
if err != nil {
return nil , err
}
// Set the min valid time for the ingested wal samples
// to be no lower than the maxt of the last block.
if err := head . Init ( maxBlockTime ) ; err != nil {
return nil , errors . Wrap ( err , "read WAL" )
}
// Set the wal to nil to disable all wal operations.
// This is mainly to avoid blocking when closing the head.
head . wal = nil
}
db . closers = append ( db . closers , head )
return & DB {
dir : db . dir ,
logger : db . logger ,
blocks : blocks ,
head : head ,
} , nil
}
// Querier loads the blocks and wal and returns a new querier over the data partition for the given time range.
// Current implementation doesn't support multiple Queriers.
func ( db * DBReadOnly ) Querier ( ctx context . Context , mint , maxt int64 ) ( storage . Querier , error ) {
q , err := db . loadDataAsQueryable ( maxt )
if err != nil {
return nil , err
}
return q . Querier ( ctx , mint , maxt )
}
// ChunkQuerier loads blocks and the wal and returns a new chunk querier over the data partition for the given time range.
// Current implementation doesn't support multiple ChunkQueriers.
func ( db * DBReadOnly ) ChunkQuerier ( ctx context . Context , mint , maxt int64 ) ( storage . ChunkQuerier , error ) {
q , err := db . loadDataAsQueryable ( maxt )
if err != nil {
return nil , err
}
return q . ChunkQuerier ( ctx , mint , maxt )
}
// Blocks returns a slice of block readers for persisted blocks.
func ( db * DBReadOnly ) Blocks ( ) ( [ ] BlockReader , error ) {
select {
case <- db . closed :
return nil , ErrClosed
default :
}
loadable , corrupted , err := openBlocks ( db . logger , db . dir , nil , nil )
if err != nil {
return nil , err
}
// Corrupted blocks that have been superseded by a loadable block can be safely ignored.
for _ , block := range loadable {
for _ , b := range block . Meta ( ) . Compaction . Parents {
delete ( corrupted , b . ULID )
}
}
if len ( corrupted ) > 0 {
for _ , b := range loadable {
if err := b . Close ( ) ; err != nil {
level . Warn ( db . logger ) . Log ( "msg" , "Closing block failed" , "err" , err , "block" , b )
}
}
errs := tsdb_errors . NewMulti ( )
for ulid , err := range corrupted {
errs . Add ( errors . Wrapf ( err , "corrupted block %s" , ulid . String ( ) ) )
}
return nil , errs . Err ( )
}
if len ( loadable ) == 0 {
return nil , nil
}
sort . Slice ( loadable , func ( i , j int ) bool {
return loadable [ i ] . Meta ( ) . MinTime < loadable [ j ] . Meta ( ) . MinTime
} )
blockMetas := make ( [ ] BlockMeta , 0 , len ( loadable ) )
for _ , b := range loadable {
blockMetas = append ( blockMetas , b . Meta ( ) )
}
if overlaps := OverlappingBlocks ( blockMetas ) ; len ( overlaps ) > 0 {
level . Warn ( db . logger ) . Log ( "msg" , "Overlapping blocks found during opening" , "detail" , overlaps . String ( ) )
}
// Close all previously open readers and add the new ones to the cache.
for _ , closer := range db . closers {
closer . Close ( )
}
blockClosers := make ( [ ] io . Closer , len ( loadable ) )
blockReaders := make ( [ ] BlockReader , len ( loadable ) )
for i , b := range loadable {
blockClosers [ i ] = b
blockReaders [ i ] = b
}
db . closers = blockClosers
return blockReaders , nil
}
// Close all block readers.
func ( db * DBReadOnly ) Close ( ) error {
select {
case <- db . closed :
return ErrClosed
default :
}
close ( db . closed )
return tsdb_errors . CloseAll ( db . closers )
}
// Open returns a new DB in the given directory. If options are empty, DefaultOptions will be used.
func Open ( dir string , l log . Logger , r prometheus . Registerer , opts * Options , stats * DBStats ) ( db * DB , err error ) {
var rngs [ ] int64
opts , rngs = validateOpts ( opts , nil )
return open ( dir , l , r , opts , rngs , stats )
}
func validateOpts ( opts * Options , rngs [ ] int64 ) ( * Options , [ ] int64 ) {
if opts == nil {
opts = DefaultOptions ( )
}
if opts . StripeSize <= 0 {
opts . StripeSize = DefaultStripeSize
}
if opts . HeadChunksWriteBufferSize <= 0 {
opts . HeadChunksWriteBufferSize = chunks . DefaultWriteBufferSize
}
if opts . MaxBlockChunkSegmentSize <= 0 {
opts . MaxBlockChunkSegmentSize = chunks . DefaultChunkSegmentSize
}
if opts . MinBlockDuration <= 0 {
opts . MinBlockDuration = DefaultBlockDuration
}
if opts . MinBlockDuration > opts . MaxBlockDuration {
opts . MaxBlockDuration = opts . MinBlockDuration
}
if len ( rngs ) == 0 {
// Start with smallest block duration and create exponential buckets until the exceed the
// configured maximum block duration.
rngs = ExponentialBlockRanges ( opts . MinBlockDuration , 10 , 3 )
}
return opts , rngs
}
func open ( dir string , l log . Logger , r prometheus . Registerer , opts * Options , rngs [ ] int64 , stats * DBStats ) ( _ * DB , returnedErr error ) {
if err := os . MkdirAll ( dir , 0777 ) ; err != nil {
return nil , err
}
if l == nil {
l = log . NewNopLogger ( )
}
if stats == nil {
stats = NewDBStats ( )
}
for i , v := range rngs {
if v > opts . MaxBlockDuration {
rngs = rngs [ : i ]
break
}
}
// Fixup bad format written by Prometheus 2.1.
if err := repairBadIndexVersion ( l , dir ) ; err != nil {
return nil , errors . Wrap ( err , "repair bad index version" )
}
walDir := filepath . Join ( dir , "wal" )
// Migrate old WAL if one exists.
if err := MigrateWAL ( l , walDir ) ; err != nil {
return nil , errors . Wrap ( err , "migrate WAL" )
}
// Remove garbage, tmp blocks.
if err := removeBestEffortTmpDirs ( l , dir ) ; err != nil {
return nil , errors . Wrap ( err , "remove tmp dirs" )
}
db := & DB {
dir : dir ,
logger : l ,
opts : opts ,
compactc : make ( chan struct { } , 1 ) ,
donec : make ( chan struct { } ) ,
stopc : make ( chan struct { } ) ,
autoCompact : true ,
chunkPool : chunkenc . NewPool ( ) ,
blocksToDelete : opts . BlocksToDelete ,
}
defer func ( ) {
// Close files if startup fails somewhere.
if returnedErr == nil {
return
}
close ( db . donec ) // DB is never run if it was an error, so close this channel here.
returnedErr = tsdb_errors . NewMulti (
returnedErr ,
errors . Wrap ( db . Close ( ) , "close DB after failed startup" ) ,
) . Err ( )
} ( )
if db . blocksToDelete == nil {
db . blocksToDelete = DefaultBlocksToDelete ( db )
}
lockfileCreationStatus := lockfileDisabled
if ! opts . NoLockfile {
absdir , err := filepath . Abs ( dir )
if err != nil {
return nil , err
}
db . lockfPath = filepath . Join ( absdir , "lock" )
if _ , err := os . Stat ( db . lockfPath ) ; err == nil {
level . Warn ( db . logger ) . Log ( "msg" , "A TSDB lockfile from a previous execution already existed. It was replaced" , "file" , db . lockfPath )
lockfileCreationStatus = lockfileReplaced
} else {
lockfileCreationStatus = lockfileCreatedCleanly
}
lockf , _ , err := fileutil . Flock ( db . lockfPath )
if err != nil {
return nil , errors . Wrap ( err , "lock DB directory" )
}
db . lockf = lockf
}
var err error
ctx , cancel := context . WithCancel ( context . Background ( ) )
db . compactor , err = NewLeveledCompactorWithChunkSize ( ctx , r , l , rngs , db . chunkPool , opts . MaxBlockChunkSegmentSize , nil )
if err != nil {
cancel ( )
return nil , errors . Wrap ( err , "create leveled compactor" )
}
db . compactCancel = cancel
var wlog * wal . WAL
segmentSize := wal . DefaultSegmentSize
// Wal is enabled.
if opts . WALSegmentSize >= 0 {
// Wal is set to a custom size.
if opts . WALSegmentSize > 0 {
segmentSize = opts . WALSegmentSize
}
wlog , err = wal . NewSize ( l , r , walDir , segmentSize , opts . WALCompression )
if err != nil {
return nil , err
}
}
headOpts := DefaultHeadOptions ( )
headOpts . ChunkRange = rngs [ 0 ]
headOpts . ChunkDirRoot = dir
headOpts . ChunkPool = db . chunkPool
headOpts . ChunkWriteBufferSize = opts . HeadChunksWriteBufferSize
headOpts . StripeSize = opts . StripeSize
headOpts . SeriesCallback = opts . SeriesLifecycleCallback
headOpts . NumExemplars = opts . MaxExemplars
db . head , err = NewHead ( r , l , wlog , headOpts , stats . Head )
if err != nil {
return nil , err
}
// Register metrics after assigning the head block.
db . metrics = newDBMetrics ( db , r )
maxBytes := opts . MaxBytes
if maxBytes < 0 {
maxBytes = 0
}
db . metrics . lockfileCreatedCleanly . Set ( float64 ( lockfileCreationStatus ) )
db . metrics . maxBytes . Set ( float64 ( maxBytes ) )
if err := db . reload ( ) ; err != nil {
return nil , err
}
// Set the min valid time for the ingested samples
// to be no lower than the maxt of the last block.
blocks := db . Blocks ( )
minValidTime := int64 ( math . MinInt64 )
if len ( blocks ) > 0 {
minValidTime = blocks [ len ( blocks ) - 1 ] . Meta ( ) . MaxTime
}
if initErr := db . head . Init ( minValidTime ) ; initErr != nil {
db . head . metrics . walCorruptionsTotal . Inc ( )
level . Warn ( db . logger ) . Log ( "msg" , "Encountered WAL read error, attempting repair" , "err" , initErr )
if err := wlog . Repair ( initErr ) ; err != nil {
return nil , errors . Wrap ( err , "repair corrupted WAL" )
}
}
go db . run ( )
return db , nil
}
func removeBestEffortTmpDirs ( l log . Logger , dir string ) error {
files , err := ioutil . ReadDir ( dir )
if err != nil {
return err
}
for _ , fi := range files {
if isTmpBlockDir ( fi ) {
if err := os . RemoveAll ( filepath . Join ( dir , fi . Name ( ) ) ) ; err != nil {
level . Error ( l ) . Log ( "msg" , "failed to delete tmp block dir" , "dir" , filepath . Join ( dir , fi . Name ( ) ) , "err" , err )
continue
}
level . Info ( l ) . Log ( "msg" , "Found and deleted tmp block dir" , "dir" , filepath . Join ( dir , fi . Name ( ) ) )
}
}
return nil
}
// StartTime implements the Storage interface.
func ( db * DB ) StartTime ( ) ( int64 , error ) {
db . mtx . RLock ( )
defer db . mtx . RUnlock ( )
if len ( db . blocks ) > 0 {
return db . blocks [ 0 ] . Meta ( ) . MinTime , nil
}
return db . head . MinTime ( ) , nil
}
// Dir returns the directory of the database.
func ( db * DB ) Dir ( ) string {
return db . dir
}
func ( db * DB ) run ( ) {
defer close ( db . donec )
backoff := time . Duration ( 0 )
for {
select {
case <- db . stopc :
return
case <- time . After ( backoff ) :
}
select {
case <- time . After ( 1 * time . Minute ) :
db . cmtx . Lock ( )
if err := db . reloadBlocks ( ) ; err != nil {
level . Error ( db . logger ) . Log ( "msg" , "reloadBlocks" , "err" , err )
}
db . cmtx . Unlock ( )
select {
case db . compactc <- struct { } { } :
default :
}
case <- db . compactc :
db . metrics . compactionsTriggered . Inc ( )
db . autoCompactMtx . Lock ( )
if db . autoCompact {
if err := db . Compact ( ) ; err != nil {
level . Error ( db . logger ) . Log ( "msg" , "compaction failed" , "err" , err )
backoff = exponential ( backoff , 1 * time . Second , 1 * time . Minute )
} else {
backoff = 0
}
} else {
db . metrics . compactionsSkipped . Inc ( )
}
db . autoCompactMtx . Unlock ( )
case <- db . stopc :
return
}
}
}
// Appender opens a new appender against the database.
func ( db * DB ) Appender ( ctx context . Context ) storage . Appender {
return dbAppender { db : db , Appender : db . head . Appender ( ctx ) }
}
// dbAppender wraps the DB's head appender and triggers compactions on commit
// if necessary.
type dbAppender struct {
storage . Appender
db * DB
}
var _ storage . GetRef = dbAppender { }
func ( a dbAppender ) GetRef ( lset labels . Labels ) ( uint64 , labels . Labels ) {
if g , ok := a . Appender . ( storage . GetRef ) ; ok {
return g . GetRef ( lset )
}
return 0 , nil
}
func ( a dbAppender ) Commit ( ) error {
err := a . Appender . Commit ( )
// We could just run this check every few minutes practically. But for benchmarks
// and high frequency use cases this is the safer way.
if a . db . head . compactable ( ) {
select {
case a . db . compactc <- struct { } { } :
default :
}
}
return err
}
// Compact data if possible. After successful compaction blocks are reloaded
// which will also delete the blocks that fall out of the retention window.
// Old blocks are only deleted on reloadBlocks based on the new block's parent information.
// See DB.reloadBlocks documentation for further information.
func ( db * DB ) Compact ( ) ( returnErr error ) {
db . cmtx . Lock ( )
defer db . cmtx . Unlock ( )
defer func ( ) {
if returnErr != nil {
db . metrics . compactionsFailed . Inc ( )
}
} ( )
lastBlockMaxt := int64 ( math . MinInt64 )
defer func ( ) {
returnErr = tsdb_errors . NewMulti (
returnErr ,
errors . Wrap ( db . head . truncateWAL ( lastBlockMaxt ) , "WAL truncation in Compact defer" ) ,
) . Err ( )
} ( )
start := time . Now ( )
// Check whether we have pending head blocks that are ready to be persisted.
// They have the highest priority.
for {
select {
case <- db . stopc :
return nil
default :
}
if ! db . head . compactable ( ) {
break
}
mint := db . head . MinTime ( )
maxt := rangeForTimestamp ( mint , db . head . chunkRange . Load ( ) )
// Wrap head into a range that bounds all reads to it.
// We remove 1 millisecond from maxt because block
// intervals are half-open: [b.MinTime, b.MaxTime). But
// chunk intervals are closed: [c.MinTime, c.MaxTime];
// so in order to make sure that overlaps are evaluated
// consistently, we explicitly remove the last value
// from the block interval here.
if err := db . compactHead ( NewRangeHead ( db . head , mint , maxt - 1 ) ) ; err != nil {
return errors . Wrap ( err , "compact head" )
}
// Consider only successful compactions for WAL truncation.
lastBlockMaxt = maxt
}
// Clear some disk space before compacting blocks, especially important
// when Head compaction happened over a long time range.
if err := db . head . truncateWAL ( lastBlockMaxt ) ; err != nil {
return errors . Wrap ( err , "WAL truncation in Compact" )
}
compactionDuration := time . Since ( start )
if compactionDuration . Milliseconds ( ) > db . head . chunkRange . Load ( ) {
level . Warn ( db . logger ) . Log (
"msg" , "Head compaction took longer than the block time range, compactions are falling behind and won't be able to catch up" ,
"duration" , compactionDuration . String ( ) ,
"block_range" , db . head . chunkRange . Load ( ) ,
)
}
return db . compactBlocks ( )
}
// CompactHead compacts the given RangeHead.
func ( db * DB ) CompactHead ( head * RangeHead ) error {
db . cmtx . Lock ( )
defer db . cmtx . Unlock ( )
if err := db . compactHead ( head ) ; err != nil {
return errors . Wrap ( err , "compact head" )
}
if err := db . head . truncateWAL ( head . BlockMaxTime ( ) ) ; err != nil {
return errors . Wrap ( err , "WAL truncation" )
}
return nil
}
// compactHead compacts the given RangeHead.
// The compaction mutex should be held before calling this method.
func ( db * DB ) compactHead ( head * RangeHead ) error {
uid , err := db . compactor . Write ( db . dir , head , head . MinTime ( ) , head . BlockMaxTime ( ) , nil )
if err != nil {
return errors . Wrap ( err , "persist head block" )
}
if err := db . reloadBlocks ( ) ; err != nil {
if errRemoveAll := os . RemoveAll ( filepath . Join ( db . dir , uid . String ( ) ) ) ; errRemoveAll != nil {
return tsdb_errors . NewMulti (
errors . Wrap ( err , "reloadBlocks blocks" ) ,
errors . Wrapf ( errRemoveAll , "delete persisted head block after failed db reloadBlocks:%s" , uid ) ,
) . Err ( )
}
return errors . Wrap ( err , "reloadBlocks blocks" )
}
if err = db . head . truncateMemory ( head . BlockMaxTime ( ) ) ; err != nil {
return errors . Wrap ( err , "head memory truncate" )
}
return nil
}
// compactBlocks compacts all the eligible on-disk blocks.
// The compaction mutex should be held before calling this method.
func ( db * DB ) compactBlocks ( ) ( err error ) {
// Check for compactions of multiple blocks.
for {
plan , err := db . compactor . Plan ( db . dir )
if err != nil {
return errors . Wrap ( err , "plan compaction" )
}
if len ( plan ) == 0 {
break
}
select {
case <- db . stopc :
return nil
default :
}
uid , err := db . compactor . Compact ( db . dir , plan , db . blocks )
if err != nil {
return errors . Wrapf ( err , "compact %s" , plan )
}
if err := db . reloadBlocks ( ) ; err != nil {
if err := os . RemoveAll ( filepath . Join ( db . dir , uid . String ( ) ) ) ; err != nil {
return errors . Wrapf ( err , "delete compacted block after failed db reloadBlocks:%s" , uid )
}
return errors . Wrap ( err , "reloadBlocks blocks" )
}
}
return nil
}
// getBlock iterates a given block range to find a block by a given id.
// If found it returns the block itself and a boolean to indicate that it was found.
func getBlock ( allBlocks [ ] * Block , id ulid . ULID ) ( * Block , bool ) {
for _ , b := range allBlocks {
if b . Meta ( ) . ULID == id {
return b , true
}
}
return nil , false
}
// reload reloads blocks and truncates the head and its WAL.
func ( db * DB ) reload ( ) error {
if err := db . reloadBlocks ( ) ; err != nil {
return errors . Wrap ( err , "reloadBlocks" )
}
if len ( db . blocks ) == 0 {
return nil
}
if err := db . head . Truncate ( db . blocks [ len ( db . blocks ) - 1 ] . MaxTime ( ) ) ; err != nil {
return errors . Wrap ( err , "head truncate" )
}
return nil
}
// reloadBlocks reloads blocks without touching head.
// Blocks that are obsolete due to replacement or retention will be deleted.
func ( db * DB ) reloadBlocks ( ) ( err error ) {
defer func ( ) {
if err != nil {
db . metrics . reloadsFailed . Inc ( )
}
db . metrics . reloads . Inc ( )
} ( )
// Now that we reload TSDB every minute, there is high chance for race condition with a reload
// triggered by CleanTombstones(). We need to lock the reload to avoid the situation where
// a normal reload and CleanTombstones try to delete the same block.
db . mtx . Lock ( )
defer db . mtx . Unlock ( )
loadable , corrupted , err := openBlocks ( db . logger , db . dir , db . blocks , db . chunkPool )
if err != nil {
return err
}
deletableULIDs := db . blocksToDelete ( loadable )
deletable := make ( map [ ulid . ULID ] * Block , len ( deletableULIDs ) )
// Mark all parents of loaded blocks as deletable (no matter if they exists). This makes it resilient against the process
// crashing towards the end of a compaction but before deletions. By doing that, we can pick up the deletion where it left off during a crash.
for _ , block := range loadable {
if _ , ok := deletableULIDs [ block . meta . ULID ] ; ok {
deletable [ block . meta . ULID ] = block
}
for _ , b := range block . Meta ( ) . Compaction . Parents {
if _ , ok := corrupted [ b . ULID ] ; ok {
delete ( corrupted , b . ULID )
level . Warn ( db . logger ) . Log ( "msg" , "Found corrupted block, but replaced by compacted one so it's safe to delete. This should not happen with atomic deletes." , "block" , b . ULID )
}
deletable [ b . ULID ] = nil
}
}
if len ( corrupted ) > 0 {
// Corrupted but no child loaded for it.
// Close all new blocks to release the lock for windows.
for _ , block := range loadable {
if _ , open := getBlock ( db . blocks , block . Meta ( ) . ULID ) ; ! open {
block . Close ( )
}
}
errs := tsdb_errors . NewMulti ( )
for ulid , err := range corrupted {
errs . Add ( errors . Wrapf ( err , "corrupted block %s" , ulid . String ( ) ) )
}
return errs . Err ( )
}
var (
toLoad [ ] * Block
blocksSize int64
)
// All deletable blocks should be unloaded.
// NOTE: We need to loop through loadable one more time as there might be loadable ready to be removed (replaced by compacted block).
for _ , block := range loadable {
if _ , ok := deletable [ block . Meta ( ) . ULID ] ; ok {
deletable [ block . Meta ( ) . ULID ] = block
continue
}
toLoad = append ( toLoad , block )
blocksSize += block . Size ( )
}
db . metrics . blocksBytes . Set ( float64 ( blocksSize ) )
sort . Slice ( toLoad , func ( i , j int ) bool {
return toLoad [ i ] . Meta ( ) . MinTime < toLoad [ j ] . Meta ( ) . MinTime
} )
if ! db . opts . AllowOverlappingBlocks {
if err := validateBlockSequence ( toLoad ) ; err != nil {
return errors . Wrap ( err , "invalid block sequence" )
}
}
// Swap new blocks first for subsequently created readers to be seen.
oldBlocks := db . blocks
db . blocks = toLoad
blockMetas := make ( [ ] BlockMeta , 0 , len ( toLoad ) )
for _ , b := range toLoad {
blockMetas = append ( blockMetas , b . Meta ( ) )
}
if overlaps := OverlappingBlocks ( blockMetas ) ; len ( overlaps ) > 0 {
level . Warn ( db . logger ) . Log ( "msg" , "Overlapping blocks found during reloadBlocks" , "detail" , overlaps . String ( ) )
}
// Append blocks to old, deletable blocks, so we can close them.
for _ , b := range oldBlocks {
if _ , ok := deletable [ b . Meta ( ) . ULID ] ; ok {
deletable [ b . Meta ( ) . ULID ] = b
}
}
if err := db . deleteBlocks ( deletable ) ; err != nil {
return errors . Wrapf ( err , "delete %v blocks" , len ( deletable ) )
}
return nil
}
func openBlocks ( l log . Logger , dir string , loaded [ ] * Block , chunkPool chunkenc . Pool ) ( blocks [ ] * Block , corrupted map [ ulid . ULID ] error , err error ) {
bDirs , err := blockDirs ( dir )
if err != nil {
return nil , nil , errors . Wrap ( err , "find blocks" )
}
corrupted = make ( map [ ulid . ULID ] error )
for _ , bDir := range bDirs {
meta , _ , err := readMetaFile ( bDir )
if err != nil {
level . Error ( l ) . Log ( "msg" , "Failed to read meta.json for a block during reloadBlocks. Skipping" , "dir" , bDir , "err" , err )
continue
}
// See if we already have the block in memory or open it otherwise.
block , open := getBlock ( loaded , meta . ULID )
if ! open {
block , err = OpenBlock ( l , bDir , chunkPool )
if err != nil {
corrupted [ meta . ULID ] = err
continue
}
}
blocks = append ( blocks , block )
}
return blocks , corrupted , nil
}
// DefaultBlocksToDelete returns a filter which decides time based and size based
// retention from the options of the db.
func DefaultBlocksToDelete ( db * DB ) BlocksToDeleteFunc {
return func ( blocks [ ] * Block ) map [ ulid . ULID ] struct { } {
return deletableBlocks ( db , blocks )
}
}
// deletableBlocks returns all currently loaded blocks past retention policy or already compacted into a new block.
func deletableBlocks ( db * DB , blocks [ ] * Block ) map [ ulid . ULID ] struct { } {
deletable := make ( map [ ulid . ULID ] struct { } )
// Sort the blocks by time - newest to oldest (largest to smallest timestamp).
// This ensures that the retentions will remove the oldest blocks.
sort . Slice ( blocks , func ( i , j int ) bool {
return blocks [ i ] . Meta ( ) . MaxTime > blocks [ j ] . Meta ( ) . MaxTime
} )
for _ , block := range blocks {
if block . Meta ( ) . Compaction . Deletable {
deletable [ block . Meta ( ) . ULID ] = struct { } { }
}
}
for ulid := range BeyondTimeRetention ( db , blocks ) {
deletable [ ulid ] = struct { } { }
}
for ulid := range BeyondSizeRetention ( db , blocks ) {
deletable [ ulid ] = struct { } { }
}
return deletable
}
// BeyondTimeRetention returns those blocks which are beyond the time retention
// set in the db options.
func BeyondTimeRetention ( db * DB , blocks [ ] * Block ) ( deletable map [ ulid . ULID ] struct { } ) {
// Time retention is disabled or no blocks to work with.
if len ( blocks ) == 0 || db . opts . RetentionDuration == 0 {
return
}
deletable = make ( map [ ulid . ULID ] struct { } )
for i , block := range blocks {
// The difference between the first block and this block is larger than
// the retention period so any blocks after that are added as deletable.
if i > 0 && blocks [ 0 ] . Meta ( ) . MaxTime - block . Meta ( ) . MaxTime > db . opts . RetentionDuration {
for _ , b := range blocks [ i : ] {
deletable [ b . meta . ULID ] = struct { } { }
}
db . metrics . timeRetentionCount . Inc ( )
break
}
}
return deletable
}
// BeyondSizeRetention returns those blocks which are beyond the size retention
// set in the db options.
func BeyondSizeRetention ( db * DB , blocks [ ] * Block ) ( deletable map [ ulid . ULID ] struct { } ) {
// Size retention is disabled or no blocks to work with.
if len ( blocks ) == 0 || db . opts . MaxBytes <= 0 {
return
}
deletable = make ( map [ ulid . ULID ] struct { } )
// Initializing size counter with WAL size and Head chunks
// written to disk, as that is part of the retention strategy.
blocksSize := db . Head ( ) . Size ( )
for i , block := range blocks {
blocksSize += block . Size ( )
if blocksSize > int64 ( db . opts . MaxBytes ) {
// Add this and all following blocks for deletion.
for _ , b := range blocks [ i : ] {
deletable [ b . meta . ULID ] = struct { } { }
}
db . metrics . sizeRetentionCount . Inc ( )
break
}
}
return deletable
}
// deleteBlocks closes the block if loaded and deletes blocks from the disk if exists.
// When the map contains a non nil block object it means it is loaded in memory
// so needs to be closed first as it might need to wait for pending readers to complete.
func ( db * DB ) deleteBlocks ( blocks map [ ulid . ULID ] * Block ) error {
for ulid , block := range blocks {
if block != nil {
if err := block . Close ( ) ; err != nil {
level . Warn ( db . logger ) . Log ( "msg" , "Closing block failed" , "err" , err , "block" , ulid )
}
}
toDelete := filepath . Join ( db . dir , ulid . String ( ) )
if _ , err := os . Stat ( toDelete ) ; os . IsNotExist ( err ) {
// Noop.
continue
} else if err != nil {
return errors . Wrapf ( err , "stat dir %v" , toDelete )
}
// Replace atomically to avoid partial block when process would crash during deletion.
tmpToDelete := filepath . Join ( db . dir , fmt . Sprintf ( "%s%s" , ulid , tmpForDeletionBlockDirSuffix ) )
if err := fileutil . Replace ( toDelete , tmpToDelete ) ; err != nil {
return errors . Wrapf ( err , "replace of obsolete block for deletion %s" , ulid )
}
if err := os . RemoveAll ( tmpToDelete ) ; err != nil {
return errors . Wrapf ( err , "delete obsolete block %s" , ulid )
}
level . Info ( db . logger ) . Log ( "msg" , "Deleting obsolete block" , "block" , ulid )
}
return nil
}
// validateBlockSequence returns error if given block meta files indicate that some blocks overlaps within sequence.
func validateBlockSequence ( bs [ ] * Block ) error {
if len ( bs ) <= 1 {
return nil
}
var metas [ ] BlockMeta
for _ , b := range bs {
metas = append ( metas , b . meta )
}
overlaps := OverlappingBlocks ( metas )
if len ( overlaps ) > 0 {
return errors . Errorf ( "block time ranges overlap: %s" , overlaps )
}
return nil
}
// TimeRange specifies minTime and maxTime range.
type TimeRange struct {
Min , Max int64
}
// Overlaps contains overlapping blocks aggregated by overlapping range.
type Overlaps map [ TimeRange ] [ ] BlockMeta
// String returns human readable string form of overlapped blocks.
func ( o Overlaps ) String ( ) string {
var res [ ] string
for r , overlaps := range o {
var groups [ ] string
for _ , m := range overlaps {
groups = append ( groups , fmt . Sprintf (
"<ulid: %s, mint: %d, maxt: %d, range: %s>" ,
m . ULID . String ( ) ,
m . MinTime ,
m . MaxTime ,
( time . Duration ( ( m . MaxTime - m . MinTime ) / 1000 ) * time . Second ) . String ( ) ,
) )
}
res = append ( res , fmt . Sprintf (
"[mint: %d, maxt: %d, range: %s, blocks: %d]: %s" ,
r . Min , r . Max ,
( time . Duration ( ( r . Max - r . Min ) / 1000 ) * time . Second ) . String ( ) ,
len ( overlaps ) ,
strings . Join ( groups , ", " ) ) ,
)
}
return strings . Join ( res , "\n" )
}
// OverlappingBlocks returns all overlapping blocks from given meta files.
func OverlappingBlocks ( bm [ ] BlockMeta ) Overlaps {
if len ( bm ) <= 1 {
return nil
}
var (
overlaps [ ] [ ] BlockMeta
// pending contains not ended blocks in regards to "current" timestamp.
pending = [ ] BlockMeta { bm [ 0 ] }
// continuousPending helps to aggregate same overlaps to single group.
continuousPending = true
)
// We have here blocks sorted by minTime. We iterate over each block and treat its minTime as our "current" timestamp.
// We check if any of the pending block finished (blocks that we have seen before, but their maxTime was still ahead current
// timestamp). If not, it means they overlap with our current block. In the same time current block is assumed pending.
for _ , b := range bm [ 1 : ] {
var newPending [ ] BlockMeta
for _ , p := range pending {
// "b.MinTime" is our current time.
if b . MinTime >= p . MaxTime {
continuousPending = false
continue
}
// "p" overlaps with "b" and "p" is still pending.
newPending = append ( newPending , p )
}
// Our block "b" is now pending.
pending = append ( newPending , b )
if len ( newPending ) == 0 {
// No overlaps.
continue
}
if continuousPending && len ( overlaps ) > 0 {
overlaps [ len ( overlaps ) - 1 ] = append ( overlaps [ len ( overlaps ) - 1 ] , b )
continue
}
overlaps = append ( overlaps , append ( newPending , b ) )
// Start new pendings.
continuousPending = true
}
// Fetch the critical overlapped time range foreach overlap groups.
overlapGroups := Overlaps { }
for _ , overlap := range overlaps {
minRange := TimeRange { Min : 0 , Max : math . MaxInt64 }
for _ , b := range overlap {
if minRange . Max > b . MaxTime {
minRange . Max = b . MaxTime
}
if minRange . Min < b . MinTime {
minRange . Min = b . MinTime
}
}
overlapGroups [ minRange ] = overlap
}
return overlapGroups
}
func ( db * DB ) String ( ) string {
return "HEAD"
}
// Blocks returns the databases persisted blocks.
func ( db * DB ) Blocks ( ) [ ] * Block {
db . mtx . RLock ( )
defer db . mtx . RUnlock ( )
return db . blocks
}
// Head returns the databases's head.
func ( db * DB ) Head ( ) * Head {
return db . head
}
// Close the partition.
func ( db * DB ) Close ( ) error {
close ( db . stopc )
if db . compactCancel != nil {
db . compactCancel ( )
}
<- db . donec
db . mtx . Lock ( )
defer db . mtx . Unlock ( )
var g errgroup . Group
// blocks also contains all head blocks.
for _ , pb := range db . blocks {
g . Go ( pb . Close )
}
errs := tsdb_errors . NewMulti ( g . Wait ( ) )
if db . lockf != nil {
errs . Add ( db . lockf . Release ( ) )
errs . Add ( os . Remove ( db . lockfPath ) )
}
if db . head != nil {
errs . Add ( db . head . Close ( ) )
}
return errs . Err ( )
}
// DisableCompactions disables auto compactions.
func ( db * DB ) DisableCompactions ( ) {
db . autoCompactMtx . Lock ( )
defer db . autoCompactMtx . Unlock ( )
db . autoCompact = false
level . Info ( db . logger ) . Log ( "msg" , "Compactions disabled" )
}
// EnableCompactions enables auto compactions.
func ( db * DB ) EnableCompactions ( ) {
db . autoCompactMtx . Lock ( )
defer db . autoCompactMtx . Unlock ( )
db . autoCompact = true
level . Info ( db . logger ) . Log ( "msg" , "Compactions enabled" )
}
// Snapshot writes the current data to the directory. If withHead is set to true it
// will create a new block containing all data that's currently in the memory buffer/WAL.
func ( db * DB ) Snapshot ( dir string , withHead bool ) error {
if dir == db . dir {
return errors . Errorf ( "cannot snapshot into base directory" )
}
if _ , err := ulid . ParseStrict ( dir ) ; err == nil {
return errors . Errorf ( "dir must not be a valid ULID" )
}
db . cmtx . Lock ( )
defer db . cmtx . Unlock ( )
db . mtx . RLock ( )
defer db . mtx . RUnlock ( )
for _ , b := range db . blocks {
level . Info ( db . logger ) . Log ( "msg" , "Snapshotting block" , "block" , b )
if err := b . Snapshot ( dir ) ; err != nil {
return errors . Wrapf ( err , "error snapshotting block: %s" , b . Dir ( ) )
}
}
if ! withHead {
return nil
}
mint := db . head . MinTime ( )
maxt := db . head . MaxTime ( )
head := NewRangeHead ( db . head , mint , maxt )
// Add +1 millisecond to block maxt because block intervals are half-open: [b.MinTime, b.MaxTime).
// Because of this block intervals are always +1 than the total samples it includes.
if _ , err := db . compactor . Write ( dir , head , mint , maxt + 1 , nil ) ; err != nil {
return errors . Wrap ( err , "snapshot head block" )
}
return nil
}
// Querier returns a new querier over the data partition for the given time range.
func ( db * DB ) Querier ( _ context . Context , mint , maxt int64 ) ( storage . Querier , error ) {
var blocks [ ] BlockReader
db . mtx . RLock ( )
defer db . mtx . RUnlock ( )
for _ , b := range db . blocks {
if b . OverlapsClosedInterval ( mint , maxt ) {
blocks = append ( blocks , b )
}
}
if maxt >= db . head . MinTime ( ) {
blocks = append ( blocks , NewRangeHead ( db . head , mint , maxt ) )
}
blockQueriers := make ( [ ] storage . Querier , 0 , len ( blocks ) )
for _ , b := range blocks {
q , err := NewBlockQuerier ( b , mint , maxt )
if err == nil {
blockQueriers = append ( blockQueriers , q )
continue
}
// If we fail, all previously opened queriers must be closed.
for _ , q := range blockQueriers {
// TODO(bwplotka): Handle error.
_ = q . Close ( )
}
return nil , errors . Wrapf ( err , "open querier for block %s" , b )
}
return storage . NewMergeQuerier ( blockQueriers , nil , storage . ChainedSeriesMerge ) , nil
}
// ChunkQuerier returns a new chunk querier over the data partition for the given time range.
func ( db * DB ) ChunkQuerier ( _ context . Context , mint , maxt int64 ) ( storage . ChunkQuerier , error ) {
var blocks [ ] BlockReader
db . mtx . RLock ( )
defer db . mtx . RUnlock ( )
for _ , b := range db . blocks {
if b . OverlapsClosedInterval ( mint , maxt ) {
blocks = append ( blocks , b )
}
}
if maxt >= db . head . MinTime ( ) {
blocks = append ( blocks , NewRangeHead ( db . head , mint , maxt ) )
}
blockQueriers := make ( [ ] storage . ChunkQuerier , 0 , len ( blocks ) )
for _ , b := range blocks {
q , err := NewBlockChunkQuerier ( b , mint , maxt )
if err == nil {
blockQueriers = append ( blockQueriers , q )
continue
}
// If we fail, all previously opened queriers must be closed.
for _ , q := range blockQueriers {
// TODO(bwplotka): Handle error.
_ = q . Close ( )
}
return nil , errors . Wrapf ( err , "open querier for block %s" , b )
}
return storage . NewMergeChunkQuerier ( blockQueriers , nil , storage . NewCompactingChunkSeriesMerger ( storage . ChainedSeriesMerge ) ) , nil
}
func ( db * DB ) ExemplarQuerier ( ctx context . Context ) ( storage . ExemplarQuerier , error ) {
return db . head . exemplars . ExemplarQuerier ( ctx )
}
func rangeForTimestamp ( t int64 , width int64 ) ( maxt int64 ) {
return ( t / width ) * width + width
}
// Delete implements deletion of metrics. It only has atomicity guarantees on a per-block basis.
func ( db * DB ) Delete ( mint , maxt int64 , ms ... * labels . Matcher ) error {
db . cmtx . Lock ( )
defer db . cmtx . Unlock ( )
var g errgroup . Group
db . mtx . RLock ( )
defer db . mtx . RUnlock ( )
for _ , b := range db . blocks {
if b . OverlapsClosedInterval ( mint , maxt ) {
g . Go ( func ( b * Block ) func ( ) error {
return func ( ) error { return b . Delete ( mint , maxt , ms ... ) }
} ( b ) )
}
}
g . Go ( func ( ) error {
return db . head . Delete ( mint , maxt , ms ... )
} )
return g . Wait ( )
}
// CleanTombstones re-writes any blocks with tombstones.
func ( db * DB ) CleanTombstones ( ) ( err error ) {
db . cmtx . Lock ( )
defer db . cmtx . Unlock ( )
start := time . Now ( )
defer db . metrics . tombCleanTimer . Observe ( time . Since ( start ) . Seconds ( ) )
cleanUpCompleted := false
// Repeat cleanup until there is no tombstones left.
for ! cleanUpCompleted {
cleanUpCompleted = true
for _ , pb := range db . Blocks ( ) {
uid , safeToDelete , cleanErr := pb . CleanTombstones ( db . Dir ( ) , db . compactor )
if cleanErr != nil {
return errors . Wrapf ( cleanErr , "clean tombstones: %s" , pb . Dir ( ) )
}
if ! safeToDelete {
// There was nothing to clean.
continue
}
// In case tombstones of the old block covers the whole block,
// then there would be no resultant block to tell the parent.
// The lock protects against race conditions when deleting blocks
// during an already running reload.
db . mtx . Lock ( )
pb . meta . Compaction . Deletable = safeToDelete
db . mtx . Unlock ( )
cleanUpCompleted = false
if err = db . reloadBlocks ( ) ; err == nil { // Will try to delete old block.
// Successful reload will change the existing blocks.
// We need to loop over the new set of blocks.
break
}
// Delete new block if it was created.
if uid != nil && * uid != ( ulid . ULID { } ) {
dir := filepath . Join ( db . Dir ( ) , uid . String ( ) )
if err := os . RemoveAll ( dir ) ; err != nil {
level . Error ( db . logger ) . Log ( "msg" , "failed to delete block after failed `CleanTombstones`" , "dir" , dir , "err" , err )
}
}
return errors . Wrap ( err , "reload blocks" )
}
}
return nil
}
func isBlockDir ( fi os . FileInfo ) bool {
if ! fi . IsDir ( ) {
return false
}
_ , err := ulid . ParseStrict ( fi . Name ( ) )
return err == nil
}
// isTmpBlockDir returns dir that consists of block dir ULID and tmp extension.
func isTmpBlockDir ( fi os . FileInfo ) bool {
if ! fi . IsDir ( ) {
return false
}
fn := fi . Name ( )
ext := filepath . Ext ( fn )
if ext == tmpForDeletionBlockDirSuffix || ext == tmpForCreationBlockDirSuffix || ext == tmpLegacy {
if _ , err := ulid . ParseStrict ( fn [ : len ( fn ) - len ( ext ) ] ) ; err == nil {
return true
}
}
return false
}
func blockDirs ( dir string ) ( [ ] string , error ) {
files , err := ioutil . ReadDir ( dir )
if err != nil {
return nil , err
}
var dirs [ ] string
for _ , fi := range files {
if isBlockDir ( fi ) {
dirs = append ( dirs , filepath . Join ( dir , fi . Name ( ) ) )
}
}
return dirs , nil
}
func sequenceFiles ( dir string ) ( [ ] string , error ) {
files , err := ioutil . ReadDir ( dir )
if err != nil {
return nil , err
}
var res [ ] string
for _ , fi := range files {
if _ , err := strconv . ParseUint ( fi . Name ( ) , 10 , 64 ) ; err != nil {
continue
}
res = append ( res , filepath . Join ( dir , fi . Name ( ) ) )
}
return res , nil
}
func nextSequenceFile ( dir string ) ( string , int , error ) {
files , err := ioutil . ReadDir ( dir )
if err != nil {
return "" , 0 , err
}
i := uint64 ( 0 )
for _ , f := range files {
j , err := strconv . ParseUint ( f . Name ( ) , 10 , 64 )
if err != nil {
continue
}
i = j
}
return filepath . Join ( dir , fmt . Sprintf ( "%0.6d" , i + 1 ) ) , int ( i + 1 ) , nil
}
func exponential ( d , min , max time . Duration ) time . Duration {
d *= 2
if d < min {
d = min
}
if d > max {
d = max
}
return d
}