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prometheus/tsdb/chunks/head_chunks.go

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35 KiB

// Copyright 2020 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 chunks
import (
"bufio"
"encoding/binary"
"errors"
"fmt"
"hash"
"io"
"os"
"path/filepath"
"slices"
"strconv"
"sync"
"github.com/dennwc/varint"
"github.com/prometheus/client_golang/prometheus"
"go.uber.org/atomic"
"github.com/prometheus/prometheus/tsdb/chunkenc"
tsdb_errors "github.com/prometheus/prometheus/tsdb/errors"
"github.com/prometheus/prometheus/tsdb/fileutil"
)
// Head chunk file header fields constants.
const (
// MagicHeadChunks is 4 bytes at the beginning of a head chunk file.
MagicHeadChunks = 0x0130BC91
headChunksFormatV1 = 1
)
// ErrChunkDiskMapperClosed returned by any method indicates
// that the ChunkDiskMapper was closed.
var ErrChunkDiskMapperClosed = errors.New("ChunkDiskMapper closed")
const (
// MintMaxtSize is the size of the mint/maxt for head chunk file and chunks.
MintMaxtSize = 8
// SeriesRefSize is the size of series reference on disk.
SeriesRefSize = 8
// HeadChunkFileHeaderSize is the total size of the header for a head chunk file.
HeadChunkFileHeaderSize = SegmentHeaderSize
// MaxHeadChunkFileSize is the max size of a head chunk file.
MaxHeadChunkFileSize = 128 * 1024 * 1024 // 128 MiB.
// CRCSize is the size of crc32 sum on disk.
CRCSize = 4
// MaxHeadChunkMetaSize is the max size of an mmapped chunks minus the chunks data.
// Max because the uvarint size can be smaller.
MaxHeadChunkMetaSize = SeriesRefSize + 2*MintMaxtSize + ChunkEncodingSize + MaxChunkLengthFieldSize + CRCSize
// MinWriteBufferSize is the minimum write buffer size allowed.
MinWriteBufferSize = 64 * 1024 // 64KB.
// MaxWriteBufferSize is the maximum write buffer size allowed.
MaxWriteBufferSize = 8 * 1024 * 1024 // 8 MiB.
// DefaultWriteBufferSize is the default write buffer size.
DefaultWriteBufferSize = 4 * 1024 * 1024 // 4 MiB.
// DefaultWriteQueueSize is the default size of the in-memory queue used before flushing chunks to the disk.
// A value of 0 completely disables this feature.
DefaultWriteQueueSize = 0
)
// ChunkDiskMapperRef represents the location of a head chunk on disk.
// The upper 4 bytes hold the index of the head chunk file and
// the lower 4 bytes hold the byte offset in the head chunk file where the chunk starts.
type ChunkDiskMapperRef uint64
func newChunkDiskMapperRef(seq, offset uint64) ChunkDiskMapperRef {
return ChunkDiskMapperRef((seq << 32) | offset)
}
func (ref ChunkDiskMapperRef) Unpack() (seq, offset int) {
seq = int(ref >> 32)
offset = int((ref << 32) >> 32)
return seq, offset
}
func (ref ChunkDiskMapperRef) GreaterThanOrEqualTo(r ChunkDiskMapperRef) bool {
s1, o1 := ref.Unpack()
s2, o2 := r.Unpack()
return s1 > s2 || (s1 == s2 && o1 >= o2)
}
func (ref ChunkDiskMapperRef) GreaterThan(r ChunkDiskMapperRef) bool {
s1, o1 := ref.Unpack()
s2, o2 := r.Unpack()
return s1 > s2 || (s1 == s2 && o1 > o2)
}
// CorruptionErr is an error that's returned when corruption is encountered.
type CorruptionErr struct {
Dir string
FileIndex int
Err error
}
func (e *CorruptionErr) Error() string {
return fmt.Errorf("corruption in head chunk file %s: %w", segmentFile(e.Dir, e.FileIndex), e.Err).Error()
}
func (e *CorruptionErr) Unwrap() error {
return e.Err
}
// chunkPos keeps track of the position in the head chunk files.
// chunkPos is not thread-safe, a lock must be used to protect it.
type chunkPos struct {
seq uint64 // Index of chunk file.
offset uint64 // Offset within chunk file.
cutFile bool // When true then the next chunk will be written to a new file.
}
// getNextChunkRef takes a chunk and returns the chunk reference which will refer to it once it has been written.
// getNextChunkRef also decides whether a new file should be cut before writing this chunk, and it returns the decision via the second return value.
// The order of calling getNextChunkRef must be the order in which chunks are written to the disk.
func (f *chunkPos) getNextChunkRef(chk chunkenc.Chunk) (chkRef ChunkDiskMapperRef, cutFile bool) {
chkLen := uint64(len(chk.Bytes()))
bytesToWrite := f.bytesToWriteForChunk(chkLen)
if f.shouldCutNewFile(bytesToWrite) {
f.toNewFile()
f.cutFile = false
cutFile = true
}
chkOffset := f.offset
f.offset += bytesToWrite
return newChunkDiskMapperRef(f.seq, chkOffset), cutFile
}
// toNewFile updates the seq/offset position to point to the beginning of a new chunk file.
func (f *chunkPos) toNewFile() {
f.seq++
f.offset = SegmentHeaderSize
}
// cutFileOnNextChunk triggers that the next chunk will be written in to a new file.
// Not thread safe, a lock must be held when calling this.
func (f *chunkPos) cutFileOnNextChunk() {
f.cutFile = true
}
// setSeq sets the sequence number of the head chunk file.
func (f *chunkPos) setSeq(seq uint64) {
f.seq = seq
}
// shouldCutNewFile returns whether a new file should be cut based on the file size.
// Not thread safe, a lock must be held when calling this.
func (f *chunkPos) shouldCutNewFile(bytesToWrite uint64) bool {
if f.cutFile {
return true
}
return f.offset == 0 || // First head chunk file.
f.offset+bytesToWrite > MaxHeadChunkFileSize // Exceeds the max head chunk file size.
}
// bytesToWriteForChunk returns the number of bytes that will need to be written for the given chunk size,
// including all meta data before and after the chunk data.
// Head chunk format: https://github.com/prometheus/prometheus/blob/main/tsdb/docs/format/head_chunks.md#chunk
func (f *chunkPos) bytesToWriteForChunk(chkLen uint64) uint64 {
// Headers.
bytes := uint64(SeriesRefSize) + 2*MintMaxtSize + ChunkEncodingSize
// Size of chunk length encoded as uvarint.
bytes += uint64(varint.UvarintSize(chkLen))
// Chunk length.
bytes += chkLen
// crc32.
bytes += CRCSize
return bytes
}
// ChunkDiskMapper is for writing the Head block chunks to the disk
// and access chunks via mmapped file.
type ChunkDiskMapper struct {
/// Writer.
dir *os.File
writeBufferSize int
curFile *os.File // File being written to.
curFileSequence int // Index of current open file being appended to. 0 if no file is active.
curFileOffset atomic.Uint64 // Bytes written in current open file.
curFileMaxt int64 // Used for the size retention.
// The values in evtlPos represent the file position which will eventually be
// reached once the content of the write queue has been fully processed.
evtlPosMtx sync.Mutex
evtlPos chunkPos
byteBuf [MaxHeadChunkMetaSize]byte // Buffer used to write the header of the chunk.
chkWriter *bufio.Writer // Writer for the current open file.
crc32 hash.Hash
writePathMtx sync.Mutex
/// Reader.
// The int key in the map is the file number on the disk.
mmappedChunkFiles map[int]*mmappedChunkFile // Contains the m-mapped files for each chunk file mapped with its index.
closers map[int]io.Closer // Closers for resources behind the byte slices.
readPathMtx sync.RWMutex // Mutex used to protect the above 2 maps.
pool chunkenc.Pool // This is used when fetching a chunk from the disk to allocate a chunk.
// Writer and Reader.
// We flush chunks to disk in batches. Hence, we store them in this buffer
// from which chunks are served till they are flushed and are ready for m-mapping.
chunkBuffer *chunkBuffer
// Whether the maxt field is set for all mmapped chunk files tracked within the mmappedChunkFiles map.
// This is done after iterating through all the chunks in those files using the IterateAllChunks method.
fileMaxtSet bool
writeQueue *chunkWriteQueue
closed bool
}
// mmappedChunkFile provides mmapp access to an entire head chunks file that holds many chunks.
type mmappedChunkFile struct {
byteSlice ByteSlice
maxt int64 // Max timestamp among all of this file's chunks.
}
// NewChunkDiskMapper returns a new ChunkDiskMapper against the given directory
// using the default head chunk file duration.
// NOTE: 'IterateAllChunks' method needs to be called at least once after creating ChunkDiskMapper
// to set the maxt of all the file.
func NewChunkDiskMapper(reg prometheus.Registerer, dir string, pool chunkenc.Pool, writeBufferSize, writeQueueSize int) (*ChunkDiskMapper, error) {
// Validate write buffer size.
if writeBufferSize < MinWriteBufferSize || writeBufferSize > MaxWriteBufferSize {
return nil, fmt.Errorf("ChunkDiskMapper write buffer size should be between %d and %d (actual: %d)", MinWriteBufferSize, MaxWriteBufferSize, writeBufferSize)
}
if writeBufferSize%1024 != 0 {
return nil, fmt.Errorf("ChunkDiskMapper write buffer size should be a multiple of 1024 (actual: %d)", writeBufferSize)
}
if err := os.MkdirAll(dir, 0o777); err != nil {
return nil, err
}
dirFile, err := fileutil.OpenDir(dir)
if err != nil {
return nil, err
}
m := &ChunkDiskMapper{
dir: dirFile,
pool: pool,
writeBufferSize: writeBufferSize,
crc32: newCRC32(),
chunkBuffer: newChunkBuffer(),
}
if writeQueueSize > 0 {
m.writeQueue = newChunkWriteQueue(reg, writeQueueSize, m.writeChunk)
}
if m.pool == nil {
m.pool = chunkenc.NewPool()
}
return m, m.openMMapFiles()
}
// Chunk encodings for out-of-order chunks.
// These encodings must be only used by the Head block for its internal bookkeeping.
const (
OutOfOrderMask = uint8(0b10000000)
)
func (cdm *ChunkDiskMapper) ApplyOutOfOrderMask(sourceEncoding chunkenc.Encoding) chunkenc.Encoding {
enc := uint8(sourceEncoding) | OutOfOrderMask
return chunkenc.Encoding(enc)
}
func (cdm *ChunkDiskMapper) IsOutOfOrderChunk(e chunkenc.Encoding) bool {
return (uint8(e) & OutOfOrderMask) != 0
}
func (cdm *ChunkDiskMapper) RemoveMasks(sourceEncoding chunkenc.Encoding) chunkenc.Encoding {
restored := uint8(sourceEncoding) & (^OutOfOrderMask)
return chunkenc.Encoding(restored)
}
// openMMapFiles opens all files within dir for mmapping.
func (cdm *ChunkDiskMapper) openMMapFiles() (returnErr error) {
cdm.mmappedChunkFiles = map[int]*mmappedChunkFile{}
cdm.closers = map[int]io.Closer{}
defer func() {
if returnErr != nil {
returnErr = tsdb_errors.NewMulti(returnErr, closeAllFromMap(cdm.closers)).Err()
cdm.mmappedChunkFiles = nil
cdm.closers = nil
}
}()
files, err := listChunkFiles(cdm.dir.Name())
if err != nil {
return err
}
files, err = repairLastChunkFile(files)
if err != nil {
return err
}
chkFileIndices := make([]int, 0, len(files))
for seq, fn := range files {
f, err := fileutil.OpenMmapFile(fn)
if err != nil {
return fmt.Errorf("mmap files, file: %s: %w", fn, err)
}
cdm.closers[seq] = f
cdm.mmappedChunkFiles[seq] = &mmappedChunkFile{byteSlice: realByteSlice(f.Bytes())}
chkFileIndices = append(chkFileIndices, seq)
}
// Check for gaps in the files.
slices.Sort(chkFileIndices)
if len(chkFileIndices) == 0 {
return nil
}
lastSeq := chkFileIndices[0]
for _, seq := range chkFileIndices[1:] {
if seq != lastSeq+1 {
return fmt.Errorf("found unsequential head chunk files %s (index: %d) and %s (index: %d)", files[lastSeq], lastSeq, files[seq], seq)
}
lastSeq = seq
}
for i, b := range cdm.mmappedChunkFiles {
if b.byteSlice.Len() < HeadChunkFileHeaderSize {
return fmt.Errorf("%s: invalid head chunk file header: %w", files[i], errInvalidSize)
}
// Verify magic number.
if m := binary.BigEndian.Uint32(b.byteSlice.Range(0, MagicChunksSize)); m != MagicHeadChunks {
return fmt.Errorf("%s: invalid magic number %x", files[i], m)
}
// Verify chunk format version.
if v := int(b.byteSlice.Range(MagicChunksSize, MagicChunksSize+ChunksFormatVersionSize)[0]); v != chunksFormatV1 {
return fmt.Errorf("%s: invalid chunk format version %d", files[i], v)
}
}
cdm.evtlPos.setSeq(uint64(lastSeq))
return nil
}
func listChunkFiles(dir string) (map[int]string, error) {
files, err := os.ReadDir(dir)
if err != nil {
return nil, err
}
res := map[int]string{}
for _, fi := range files {
seq, err := strconv.ParseUint(fi.Name(), 10, 64)
if err != nil {
continue
}
res[int(seq)] = filepath.Join(dir, fi.Name())
}
return res, nil
}
// repairLastChunkFile deletes the last file if it's empty.
// Because we don't fsync when creating these files, we could end
// up with an empty file at the end during an abrupt shutdown.
func repairLastChunkFile(files map[int]string) (_ map[int]string, returnErr error) {
lastFile := -1
for seq := range files {
if seq > lastFile {
lastFile = seq
}
}
if lastFile <= 0 {
return files, nil
}
f, err := os.Open(files[lastFile])
if err != nil {
return files, fmt.Errorf("open file during last head chunk file repair: %w", err)
}
buf := make([]byte, MagicChunksSize)
size, err := f.Read(buf)
if err != nil && !errors.Is(err, io.EOF) {
return files, fmt.Errorf("failed to read magic number during last head chunk file repair: %w", err)
}
if err := f.Close(); err != nil {
return files, fmt.Errorf("close file during last head chunk file repair: %w", err)
}
// We either don't have enough bytes for the magic number or the magic number is 0.
// NOTE: we should not check for wrong magic number here because that error
// needs to be sent up the function called (already done elsewhere)
// for proper repair mechanism to happen in the Head.
if size < MagicChunksSize || binary.BigEndian.Uint32(buf) == 0 {
// Corrupt file, hence remove it.
if err := os.RemoveAll(files[lastFile]); err != nil {
return files, fmt.Errorf("delete corrupted, empty head chunk file during last file repair: %w", err)
}
delete(files, lastFile)
}
return files, nil
}
// WriteChunk writes the chunk to the disk.
// The returned chunk ref is the reference from where the chunk encoding starts for the chunk.
func (cdm *ChunkDiskMapper) WriteChunk(seriesRef HeadSeriesRef, mint, maxt int64, chk chunkenc.Chunk, isOOO bool, callback func(err error)) (chkRef ChunkDiskMapperRef) {
// cdm.evtlPosMtx must be held to serialize the calls to cdm.evtlPos.getNextChunkRef() and the writing of the chunk (either with or without queue).
cdm.evtlPosMtx.Lock()
defer cdm.evtlPosMtx.Unlock()
ref, cutFile := cdm.evtlPos.getNextChunkRef(chk)
if cdm.writeQueue != nil {
return cdm.writeChunkViaQueue(ref, isOOO, cutFile, seriesRef, mint, maxt, chk, callback)
}
err := cdm.writeChunk(seriesRef, mint, maxt, chk, ref, isOOO, cutFile)
if callback != nil {
callback(err)
}
return ref
}
func (cdm *ChunkDiskMapper) writeChunkViaQueue(ref ChunkDiskMapperRef, isOOO, cutFile bool, seriesRef HeadSeriesRef, mint, maxt int64, chk chunkenc.Chunk, callback func(err error)) (chkRef ChunkDiskMapperRef) {
var err error
if callback != nil {
defer func() {
if err != nil {
callback(err)
}
}()
}
err = cdm.writeQueue.addJob(chunkWriteJob{
cutFile: cutFile,
seriesRef: seriesRef,
mint: mint,
maxt: maxt,
chk: chk,
ref: ref,
isOOO: isOOO,
callback: callback,
})
return ref
}
func (cdm *ChunkDiskMapper) writeChunk(seriesRef HeadSeriesRef, mint, maxt int64, chk chunkenc.Chunk, ref ChunkDiskMapperRef, isOOO, cutFile bool) (err error) {
cdm.writePathMtx.Lock()
defer cdm.writePathMtx.Unlock()
if cdm.closed {
return ErrChunkDiskMapperClosed
}
if cutFile {
err := cdm.cutAndExpectRef(ref)
if err != nil {
return err
}
}
// if len(chk.Bytes())+MaxHeadChunkMetaSize >= writeBufferSize, it means that chunk >= the buffer size;
// so no need to flush here, as we have to flush at the end (to not keep partial chunks in buffer).
if len(chk.Bytes())+MaxHeadChunkMetaSize < cdm.writeBufferSize && cdm.chkWriter.Available() < MaxHeadChunkMetaSize+len(chk.Bytes()) {
if err := cdm.flushBuffer(); err != nil {
return err
}
}
cdm.crc32.Reset()
bytesWritten := 0
binary.BigEndian.PutUint64(cdm.byteBuf[bytesWritten:], uint64(seriesRef))
bytesWritten += SeriesRefSize
binary.BigEndian.PutUint64(cdm.byteBuf[bytesWritten:], uint64(mint))
bytesWritten += MintMaxtSize
binary.BigEndian.PutUint64(cdm.byteBuf[bytesWritten:], uint64(maxt))
bytesWritten += MintMaxtSize
enc := chk.Encoding()
if isOOO {
enc = cdm.ApplyOutOfOrderMask(enc)
}
cdm.byteBuf[bytesWritten] = byte(enc)
bytesWritten += ChunkEncodingSize
n := binary.PutUvarint(cdm.byteBuf[bytesWritten:], uint64(len(chk.Bytes())))
bytesWritten += n
if err := cdm.writeAndAppendToCRC32(cdm.byteBuf[:bytesWritten]); err != nil {
return err
}
if err := cdm.writeAndAppendToCRC32(chk.Bytes()); err != nil {
return err
}
if err := cdm.writeCRC32(); err != nil {
return err
}
if maxt > cdm.curFileMaxt {
cdm.curFileMaxt = maxt
}
cdm.chunkBuffer.put(ref, chk)
if len(chk.Bytes())+MaxHeadChunkMetaSize >= cdm.writeBufferSize {
// The chunk was bigger than the buffer itself.
// Flushing to not keep partial chunks in buffer.
if err := cdm.flushBuffer(); err != nil {
return err
}
}
return nil
}
// CutNewFile makes that a new file will be created the next time a chunk is written.
func (cdm *ChunkDiskMapper) CutNewFile() {
cdm.evtlPosMtx.Lock()
defer cdm.evtlPosMtx.Unlock()
cdm.evtlPos.cutFileOnNextChunk()
}
func (cdm *ChunkDiskMapper) IsQueueEmpty() bool {
if cdm.writeQueue == nil {
return true
}
return cdm.writeQueue.queueIsEmpty()
}
// cutAndExpectRef creates a new m-mapped file.
// The write lock should be held before calling this.
// It ensures that the position in the new file matches the given chunk reference, if not then it errors.
func (cdm *ChunkDiskMapper) cutAndExpectRef(chkRef ChunkDiskMapperRef) (err error) {
seq, offset, err := cdm.cut()
if err != nil {
return err
}
if expSeq, expOffset := chkRef.Unpack(); seq != expSeq || offset != expOffset {
return fmt.Errorf("expected newly cut file to have sequence:offset %d:%d, got %d:%d", expSeq, expOffset, seq, offset)
}
return nil
}
// cut creates a new m-mapped file. The write lock should be held before calling this.
// It returns the file sequence and the offset in that file to start writing chunks.
func (cdm *ChunkDiskMapper) cut() (seq, offset int, returnErr error) {
// Sync current tail to disk and close.
if err := cdm.finalizeCurFile(); err != nil {
return 0, 0, err
}
offset, newFile, seq, err := cutSegmentFile(cdm.dir, MagicHeadChunks, headChunksFormatV1, HeadChunkFilePreallocationSize)
if err != nil {
return 0, 0, err
}
defer func() {
// The file should not be closed if there is no error,
// its kept open in the ChunkDiskMapper.
if returnErr != nil {
returnErr = tsdb_errors.NewMulti(returnErr, newFile.Close()).Err()
}
}()
cdm.curFileOffset.Store(uint64(offset))
if cdm.curFile != nil {
cdm.readPathMtx.Lock()
cdm.mmappedChunkFiles[cdm.curFileSequence].maxt = cdm.curFileMaxt
cdm.readPathMtx.Unlock()
}
mmapFile, err := fileutil.OpenMmapFileWithSize(newFile.Name(), MaxHeadChunkFileSize)
if err != nil {
return 0, 0, err
}
cdm.readPathMtx.Lock()
cdm.curFileSequence = seq
cdm.curFile = newFile
if cdm.chkWriter != nil {
cdm.chkWriter.Reset(newFile)
} else {
cdm.chkWriter = bufio.NewWriterSize(newFile, cdm.writeBufferSize)
}
cdm.closers[cdm.curFileSequence] = mmapFile
cdm.mmappedChunkFiles[cdm.curFileSequence] = &mmappedChunkFile{byteSlice: realByteSlice(mmapFile.Bytes())}
cdm.readPathMtx.Unlock()
cdm.curFileMaxt = 0
return seq, offset, nil
}
// finalizeCurFile writes all pending data to the current tail file,
// truncates its size, and closes it.
func (cdm *ChunkDiskMapper) finalizeCurFile() error {
if cdm.curFile == nil {
return nil
}
if err := cdm.flushBuffer(); err != nil {
return err
}
if err := cdm.curFile.Sync(); err != nil {
return err
}
return cdm.curFile.Close()
}
func (cdm *ChunkDiskMapper) write(b []byte) error {
n, err := cdm.chkWriter.Write(b)
cdm.curFileOffset.Add(uint64(n))
return err
}
func (cdm *ChunkDiskMapper) writeAndAppendToCRC32(b []byte) error {
if err := cdm.write(b); err != nil {
return err
}
_, err := cdm.crc32.Write(b)
return err
}
func (cdm *ChunkDiskMapper) writeCRC32() error {
return cdm.write(cdm.crc32.Sum(cdm.byteBuf[:0]))
}
// flushBuffer flushes the current in-memory chunks.
// Assumes that writePathMtx is _write_ locked before calling this method.
func (cdm *ChunkDiskMapper) flushBuffer() error {
if err := cdm.chkWriter.Flush(); err != nil {
return err
}
cdm.chunkBuffer.clear()
return nil
}
// Chunk returns a chunk from a given reference.
func (cdm *ChunkDiskMapper) Chunk(ref ChunkDiskMapperRef) (chunkenc.Chunk, error) {
cdm.readPathMtx.RLock()
// We hold this read lock for the entire duration because if Close()
// is called, the data in the byte slice will get corrupted as the mmapped
// file will be closed.
defer cdm.readPathMtx.RUnlock()
if cdm.closed {
return nil, ErrChunkDiskMapperClosed
}
if cdm.writeQueue != nil {
chunk := cdm.writeQueue.get(ref)
if chunk != nil {
return chunk, nil
}
}
sgmIndex, chkStart := ref.Unpack()
// We skip the series ref and the mint/maxt beforehand.
chkStart += SeriesRefSize + (2 * MintMaxtSize)
// If it is the current open file, then the chunks can be in the buffer too.
if sgmIndex == cdm.curFileSequence {
chunk := cdm.chunkBuffer.get(ref)
if chunk != nil {
return chunk, nil
}
}
mmapFile, ok := cdm.mmappedChunkFiles[sgmIndex]
if !ok {
if sgmIndex > cdm.curFileSequence {
return nil, &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: -1,
Err: fmt.Errorf("head chunk file index %d more than current open file", sgmIndex),
}
}
return nil, &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: sgmIndex,
Err: fmt.Errorf("head chunk file index %d does not exist on disk", sgmIndex),
}
}
if chkStart+MaxChunkLengthFieldSize > mmapFile.byteSlice.Len() {
return nil, &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: sgmIndex,
Err: fmt.Errorf("head chunk file doesn't include enough bytes to read the chunk size data field - required:%v, available:%v", chkStart+MaxChunkLengthFieldSize, mmapFile.byteSlice.Len()),
}
}
// Encoding.
chkEnc := mmapFile.byteSlice.Range(chkStart, chkStart+ChunkEncodingSize)[0]
sourceChkEnc := chunkenc.Encoding(chkEnc)
// Extract the encoding from the byte. ChunkDiskMapper uses only the last 7 bits for the encoding.
chkEnc = byte(cdm.RemoveMasks(sourceChkEnc))
// Data length.
// With the minimum chunk length this should never cause us reading
// over the end of the slice.
chkDataLenStart := chkStart + ChunkEncodingSize
c := mmapFile.byteSlice.Range(chkDataLenStart, chkDataLenStart+MaxChunkLengthFieldSize)
chkDataLen, n := binary.Uvarint(c)
if n <= 0 {
return nil, &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: sgmIndex,
Err: fmt.Errorf("reading chunk length failed with %d", n),
}
}
// Verify the chunk data end.
chkDataEnd := chkDataLenStart + n + int(chkDataLen)
if chkDataEnd > mmapFile.byteSlice.Len() {
return nil, &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: sgmIndex,
Err: fmt.Errorf("head chunk file doesn't include enough bytes to read the chunk - required:%v, available:%v", chkDataEnd, mmapFile.byteSlice.Len()),
}
}
// Check the CRC.
sum := mmapFile.byteSlice.Range(chkDataEnd, chkDataEnd+CRCSize)
if err := checkCRC32(mmapFile.byteSlice.Range(chkStart-(SeriesRefSize+2*MintMaxtSize), chkDataEnd), sum); err != nil {
return nil, &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: sgmIndex,
Err: err,
}
}
// The chunk data itself.
chkData := mmapFile.byteSlice.Range(chkDataEnd-int(chkDataLen), chkDataEnd)
// Make a copy of the chunk data to prevent a panic occurring because the returned
// chunk data slice references an mmap-ed file which could be closed after the
// function returns but while the chunk is still in use.
chkDataCopy := make([]byte, len(chkData))
copy(chkDataCopy, chkData)
chk, err := cdm.pool.Get(chunkenc.Encoding(chkEnc), chkDataCopy)
if err != nil {
return nil, &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: sgmIndex,
Err: err,
}
}
return chk, nil
}
// IterateAllChunks iterates all mmappedChunkFiles (in order of head chunk file name/number) and all the chunks within it
// and runs the provided function with information about each chunk. It returns on the first error encountered.
// NOTE: This method needs to be called at least once after creating ChunkDiskMapper
// to set the maxt of all the file.
func (cdm *ChunkDiskMapper) IterateAllChunks(f func(seriesRef HeadSeriesRef, chunkRef ChunkDiskMapperRef, mint, maxt int64, numSamples uint16, encoding chunkenc.Encoding, isOOO bool) error) (err error) {
cdm.writePathMtx.Lock()
defer cdm.writePathMtx.Unlock()
defer func() {
cdm.fileMaxtSet = true
}()
// Iterate files in ascending order.
segIDs := make([]int, 0, len(cdm.mmappedChunkFiles))
for seg := range cdm.mmappedChunkFiles {
segIDs = append(segIDs, seg)
}
slices.Sort(segIDs)
for _, segID := range segIDs {
mmapFile := cdm.mmappedChunkFiles[segID]
fileEnd := mmapFile.byteSlice.Len()
if segID == cdm.curFileSequence {
fileEnd = int(cdm.curFileSize())
}
idx := HeadChunkFileHeaderSize
for idx < fileEnd {
if fileEnd-idx < MaxHeadChunkMetaSize {
// Check for all 0s which marks the end of the file.
allZeros := true
for _, b := range mmapFile.byteSlice.Range(idx, fileEnd) {
if b != byte(0) {
allZeros = false
break
}
}
if allZeros {
// End of segment chunk file content.
break
}
return &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: segID,
Err: fmt.Errorf("head chunk file has some unread data, but doesn't include enough bytes to read the chunk header"+
" - required:%v, available:%v, file:%d", idx+MaxHeadChunkMetaSize, fileEnd, segID),
}
}
chunkRef := newChunkDiskMapperRef(uint64(segID), uint64(idx))
startIdx := idx
seriesRef := HeadSeriesRef(binary.BigEndian.Uint64(mmapFile.byteSlice.Range(idx, idx+SeriesRefSize)))
idx += SeriesRefSize
mint := int64(binary.BigEndian.Uint64(mmapFile.byteSlice.Range(idx, idx+MintMaxtSize)))
idx += MintMaxtSize
maxt := int64(binary.BigEndian.Uint64(mmapFile.byteSlice.Range(idx, idx+MintMaxtSize)))
idx += MintMaxtSize
// We preallocate file to help with m-mapping (especially windows systems).
// As series ref always starts from 1, we assume it being 0 to be the end of the actual file data.
// We are not considering possible file corruption that can cause it to be 0.
// Additionally we are checking mint and maxt just to be sure.
if seriesRef == 0 && mint == 0 && maxt == 0 {
break
}
chkEnc := chunkenc.Encoding(mmapFile.byteSlice.Range(idx, idx+ChunkEncodingSize)[0])
idx += ChunkEncodingSize
dataLen, n := binary.Uvarint(mmapFile.byteSlice.Range(idx, idx+MaxChunkLengthFieldSize))
idx += n
numSamples := binary.BigEndian.Uint16(mmapFile.byteSlice.Range(idx, idx+2))
idx += int(dataLen) // Skip the data.
// In the beginning we only checked for the chunk meta size.
// Now that we have added the chunk data length, we check for sufficient bytes again.
if idx+CRCSize > fileEnd {
return &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: segID,
Err: fmt.Errorf("head chunk file doesn't include enough bytes to read the chunk header - required:%v, available:%v, file:%d", idx+CRCSize, fileEnd, segID),
}
}
// Check CRC.
sum := mmapFile.byteSlice.Range(idx, idx+CRCSize)
if err := checkCRC32(mmapFile.byteSlice.Range(startIdx, idx), sum); err != nil {
return &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: segID,
Err: err,
}
}
idx += CRCSize
if maxt > mmapFile.maxt {
mmapFile.maxt = maxt
}
isOOO := cdm.IsOutOfOrderChunk(chkEnc)
// Extract the encoding from the byte. ChunkDiskMapper uses only the last 7 bits for the encoding.
chkEnc = cdm.RemoveMasks(chkEnc)
if err := f(seriesRef, chunkRef, mint, maxt, numSamples, chkEnc, isOOO); err != nil {
var cerr *CorruptionErr
if errors.As(err, &cerr) {
cerr.Dir = cdm.dir.Name()
cerr.FileIndex = segID
return cerr
}
return err
}
}
if idx > fileEnd {
// It should be equal to the slice length.
return &CorruptionErr{
Dir: cdm.dir.Name(),
FileIndex: segID,
Err: fmt.Errorf("head chunk file doesn't include enough bytes to read the last chunk data - required:%v, available:%v, file:%d", idx, fileEnd, segID),
}
}
}
return nil
}
// Truncate deletes the head chunk files whose file number is less than given fileNo.
func (cdm *ChunkDiskMapper) Truncate(fileNo uint32) error {
cdm.readPathMtx.RLock()
// Sort the file indices, else if files deletion fails in between,
// it can lead to unsequential files as the map is not sorted.
chkFileIndices := make([]int, 0, len(cdm.mmappedChunkFiles))
for seq := range cdm.mmappedChunkFiles {
chkFileIndices = append(chkFileIndices, seq)
}
slices.Sort(chkFileIndices)
var removedFiles []int
for _, seq := range chkFileIndices {
if seq == cdm.curFileSequence || uint32(seq) >= fileNo {
break
}
removedFiles = append(removedFiles, seq)
}
cdm.readPathMtx.RUnlock()
errs := tsdb_errors.NewMulti()
// Cut a new file only if the current file has some chunks.
if cdm.curFileSize() > HeadChunkFileHeaderSize {
// There is a known race condition here because between the check of curFileSize() and the call to CutNewFile()
// a new file could already be cut, this is acceptable because it will simply result in an empty file which
// won't do any harm.
cdm.CutNewFile()
}
pendingDeletes, err := cdm.deleteFiles(removedFiles)
errs.Add(err)
if len(chkFileIndices) == len(removedFiles) {
// All files were deleted. Reset the current sequence.
cdm.evtlPosMtx.Lock()
// We can safely reset the sequence only if the write queue is empty. If it's not empty,
// then there may be a job in the queue that will create a new segment file with an ID
// generated before the sequence reset.
//
// The queueIsEmpty() function must be called while holding the cdm.evtlPosMtx to avoid
// a race condition with WriteChunk().
if cdm.writeQueue == nil || cdm.writeQueue.queueIsEmpty() {
if err == nil {
cdm.evtlPos.setSeq(0)
} else {
// In case of error, set it to the last file number on the disk that was not deleted.
cdm.evtlPos.setSeq(uint64(pendingDeletes[len(pendingDeletes)-1]))
}
}
cdm.evtlPosMtx.Unlock()
}
return errs.Err()
}
// deleteFiles deletes the given file sequences in order of the sequence.
// In case of an error, it returns the sorted file sequences that were not deleted from the _disk_.
func (cdm *ChunkDiskMapper) deleteFiles(removedFiles []int) ([]int, error) {
slices.Sort(removedFiles) // To delete them in order.
cdm.readPathMtx.Lock()
for _, seq := range removedFiles {
if err := cdm.closers[seq].Close(); err != nil {
cdm.readPathMtx.Unlock()
return removedFiles, err
}
delete(cdm.mmappedChunkFiles, seq)
delete(cdm.closers, seq)
}
cdm.readPathMtx.Unlock()
// We actually delete the files separately to not block the readPathMtx for long.
for i, seq := range removedFiles {
if err := os.Remove(segmentFile(cdm.dir.Name(), seq)); err != nil {
return removedFiles[i:], err
}
}
return nil, nil
}
// DeleteCorrupted deletes all the head chunk files after the one which had the corruption
// (including the corrupt file).
func (cdm *ChunkDiskMapper) DeleteCorrupted(originalErr error) error {
var cerr *CorruptionErr
if !errors.As(originalErr, &cerr) {
return fmt.Errorf("cannot handle error: %w", originalErr)
}
// Delete all the head chunk files following the corrupt head chunk file.
segs := []int{}
cdm.readPathMtx.RLock()
lastSeq := 0
for seg := range cdm.mmappedChunkFiles {
switch {
case seg >= cerr.FileIndex:
segs = append(segs, seg)
case seg > lastSeq:
lastSeq = seg
}
}
cdm.readPathMtx.RUnlock()
pendingDeletes, err := cdm.deleteFiles(segs)
cdm.evtlPosMtx.Lock()
if err == nil {
cdm.evtlPos.setSeq(uint64(lastSeq))
} else {
// In case of error, set it to the last file number on the disk that was not deleted.
cdm.evtlPos.setSeq(uint64(pendingDeletes[len(pendingDeletes)-1]))
}
cdm.evtlPosMtx.Unlock()
return err
}
// Size returns the size of the chunk files.
func (cdm *ChunkDiskMapper) Size() (int64, error) {
return fileutil.DirSize(cdm.dir.Name())
}
func (cdm *ChunkDiskMapper) curFileSize() uint64 {
return cdm.curFileOffset.Load()
}
// Close closes all the open files in ChunkDiskMapper.
// It is not longer safe to access chunks from this struct after calling Close.
func (cdm *ChunkDiskMapper) Close() error {
// Locking the eventual position lock blocks WriteChunk()
cdm.evtlPosMtx.Lock()
defer cdm.evtlPosMtx.Unlock()
if cdm.writeQueue != nil {
cdm.writeQueue.stop()
}
// 'WriteChunk' locks writePathMtx first and then readPathMtx for cutting head chunk file.
// The lock order should not be reversed here else it can cause deadlocks.
cdm.writePathMtx.Lock()
defer cdm.writePathMtx.Unlock()
cdm.readPathMtx.Lock()
defer cdm.readPathMtx.Unlock()
if cdm.closed {
return nil
}
cdm.closed = true
errs := tsdb_errors.NewMulti(
closeAllFromMap(cdm.closers),
cdm.finalizeCurFile(),
cdm.dir.Close(),
)
cdm.mmappedChunkFiles = map[int]*mmappedChunkFile{}
cdm.closers = map[int]io.Closer{}
return errs.Err()
}
func closeAllFromMap(cs map[int]io.Closer) error {
errs := tsdb_errors.NewMulti()
for _, c := range cs {
errs.Add(c.Close())
}
return errs.Err()
}
const inBufferShards = 128 // 128 is a randomly chosen number.
// chunkBuffer is a thread safe lookup table for chunks by their ref.
type chunkBuffer struct {
inBufferChunks [inBufferShards]map[ChunkDiskMapperRef]chunkenc.Chunk
inBufferChunksMtxs [inBufferShards]sync.RWMutex
}
func newChunkBuffer() *chunkBuffer {
cb := &chunkBuffer{}
for i := 0; i < inBufferShards; i++ {
cb.inBufferChunks[i] = make(map[ChunkDiskMapperRef]chunkenc.Chunk)
}
return cb
}
func (cb *chunkBuffer) put(ref ChunkDiskMapperRef, chk chunkenc.Chunk) {
shardIdx := ref % inBufferShards
cb.inBufferChunksMtxs[shardIdx].Lock()
cb.inBufferChunks[shardIdx][ref] = chk
cb.inBufferChunksMtxs[shardIdx].Unlock()
}
func (cb *chunkBuffer) get(ref ChunkDiskMapperRef) chunkenc.Chunk {
shardIdx := ref % inBufferShards
cb.inBufferChunksMtxs[shardIdx].RLock()
defer cb.inBufferChunksMtxs[shardIdx].RUnlock()
return cb.inBufferChunks[shardIdx][ref]
}
func (cb *chunkBuffer) clear() {
for i := 0; i < inBufferShards; i++ {
cb.inBufferChunksMtxs[i].Lock()
cb.inBufferChunks[i] = make(map[ChunkDiskMapperRef]chunkenc.Chunk)
cb.inBufferChunksMtxs[i].Unlock()
}
}