// Copyright (c) 2012, Suryandaru Triandana // All rights reserved. // // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. package table import ( "encoding/binary" "fmt" "io" "sort" "strings" "sync" "github.com/golang/snappy" "github.com/syndtr/goleveldb/leveldb/cache" "github.com/syndtr/goleveldb/leveldb/comparer" "github.com/syndtr/goleveldb/leveldb/errors" "github.com/syndtr/goleveldb/leveldb/filter" "github.com/syndtr/goleveldb/leveldb/iterator" "github.com/syndtr/goleveldb/leveldb/opt" "github.com/syndtr/goleveldb/leveldb/storage" "github.com/syndtr/goleveldb/leveldb/util" ) // Reader errors. var ( ErrNotFound = errors.ErrNotFound ErrReaderReleased = errors.New("leveldb/table: reader released") ErrIterReleased = errors.New("leveldb/table: iterator released") ) // ErrCorrupted describes error due to corruption. This error will be wrapped // with errors.ErrCorrupted. type ErrCorrupted struct { Pos int64 Size int64 Kind string Reason string } func (e *ErrCorrupted) Error() string { return fmt.Sprintf("leveldb/table: corruption on %s (pos=%d): %s", e.Kind, e.Pos, e.Reason) } func max(x, y int) int { if x > y { return x } return y } type block struct { bpool *util.BufferPool bh blockHandle data []byte restartsLen int restartsOffset int } func (b *block) seek(cmp comparer.Comparer, rstart, rlimit int, key []byte) (index, offset int, err error) { index = sort.Search(b.restartsLen-rstart-(b.restartsLen-rlimit), func(i int) bool { offset := int(binary.LittleEndian.Uint32(b.data[b.restartsOffset+4*(rstart+i):])) offset++ // shared always zero, since this is a restart point v1, n1 := binary.Uvarint(b.data[offset:]) // key length _, n2 := binary.Uvarint(b.data[offset+n1:]) // value length m := offset + n1 + n2 return cmp.Compare(b.data[m:m+int(v1)], key) > 0 }) + rstart - 1 if index < rstart { // The smallest key is greater-than key sought. index = rstart } offset = int(binary.LittleEndian.Uint32(b.data[b.restartsOffset+4*index:])) return } func (b *block) restartIndex(rstart, rlimit, offset int) int { return sort.Search(b.restartsLen-rstart-(b.restartsLen-rlimit), func(i int) bool { return int(binary.LittleEndian.Uint32(b.data[b.restartsOffset+4*(rstart+i):])) > offset }) + rstart - 1 } func (b *block) restartOffset(index int) int { return int(binary.LittleEndian.Uint32(b.data[b.restartsOffset+4*index:])) } func (b *block) entry(offset int) (key, value []byte, nShared, n int, err error) { if offset >= b.restartsOffset { if offset != b.restartsOffset { err = &ErrCorrupted{Reason: "entries offset not aligned"} } return } v0, n0 := binary.Uvarint(b.data[offset:]) // Shared prefix length v1, n1 := binary.Uvarint(b.data[offset+n0:]) // Key length v2, n2 := binary.Uvarint(b.data[offset+n0+n1:]) // Value length m := n0 + n1 + n2 n = m + int(v1) + int(v2) if n0 <= 0 || n1 <= 0 || n2 <= 0 || offset+n > b.restartsOffset { err = &ErrCorrupted{Reason: "entries corrupted"} return } key = b.data[offset+m : offset+m+int(v1)] value = b.data[offset+m+int(v1) : offset+n] nShared = int(v0) return } func (b *block) Release() { b.bpool.Put(b.data) b.bpool = nil b.data = nil } type dir int const ( dirReleased dir = iota - 1 dirSOI dirEOI dirBackward dirForward ) type blockIter struct { tr *Reader block *block blockReleaser util.Releaser releaser util.Releaser key, value []byte offset int // Previous offset, only filled by Next. prevOffset int prevNode []int prevKeys []byte restartIndex int // Iterator direction. dir dir // Restart index slice range. riStart int riLimit int // Offset slice range. offsetStart int offsetRealStart int offsetLimit int // Error. err error } func (i *blockIter) sErr(err error) { i.err = err i.key = nil i.value = nil i.prevNode = nil i.prevKeys = nil } func (i *blockIter) reset() { if i.dir == dirBackward { i.prevNode = i.prevNode[:0] i.prevKeys = i.prevKeys[:0] } i.restartIndex = i.riStart i.offset = i.offsetStart i.dir = dirSOI i.key = i.key[:0] i.value = nil } func (i *blockIter) isFirst() bool { switch i.dir { case dirForward: return i.prevOffset == i.offsetRealStart case dirBackward: return len(i.prevNode) == 1 && i.restartIndex == i.riStart } return false } func (i *blockIter) isLast() bool { switch i.dir { case dirForward, dirBackward: return i.offset == i.offsetLimit } return false } func (i *blockIter) First() bool { if i.err != nil { return false } else if i.dir == dirReleased { i.err = ErrIterReleased return false } if i.dir == dirBackward { i.prevNode = i.prevNode[:0] i.prevKeys = i.prevKeys[:0] } i.dir = dirSOI return i.Next() } func (i *blockIter) Last() bool { if i.err != nil { return false } else if i.dir == dirReleased { i.err = ErrIterReleased return false } if i.dir == dirBackward { i.prevNode = i.prevNode[:0] i.prevKeys = i.prevKeys[:0] } i.dir = dirEOI return i.Prev() } func (i *blockIter) Seek(key []byte) bool { if i.err != nil { return false } else if i.dir == dirReleased { i.err = ErrIterReleased return false } ri, offset, err := i.block.seek(i.tr.cmp, i.riStart, i.riLimit, key) if err != nil { i.sErr(err) return false } i.restartIndex = ri i.offset = max(i.offsetStart, offset) if i.dir == dirSOI || i.dir == dirEOI { i.dir = dirForward } for i.Next() { if i.tr.cmp.Compare(i.key, key) >= 0 { return true } } return false } func (i *blockIter) Next() bool { if i.dir == dirEOI || i.err != nil { return false } else if i.dir == dirReleased { i.err = ErrIterReleased return false } if i.dir == dirSOI { i.restartIndex = i.riStart i.offset = i.offsetStart } else if i.dir == dirBackward { i.prevNode = i.prevNode[:0] i.prevKeys = i.prevKeys[:0] } for i.offset < i.offsetRealStart { key, value, nShared, n, err := i.block.entry(i.offset) if err != nil { i.sErr(i.tr.fixErrCorruptedBH(i.block.bh, err)) return false } if n == 0 { i.dir = dirEOI return false } i.key = append(i.key[:nShared], key...) i.value = value i.offset += n } if i.offset >= i.offsetLimit { i.dir = dirEOI if i.offset != i.offsetLimit { i.sErr(i.tr.newErrCorruptedBH(i.block.bh, "entries offset not aligned")) } return false } key, value, nShared, n, err := i.block.entry(i.offset) if err != nil { i.sErr(i.tr.fixErrCorruptedBH(i.block.bh, err)) return false } if n == 0 { i.dir = dirEOI return false } i.key = append(i.key[:nShared], key...) i.value = value i.prevOffset = i.offset i.offset += n i.dir = dirForward return true } func (i *blockIter) Prev() bool { if i.dir == dirSOI || i.err != nil { return false } else if i.dir == dirReleased { i.err = ErrIterReleased return false } var ri int if i.dir == dirForward { // Change direction. i.offset = i.prevOffset if i.offset == i.offsetRealStart { i.dir = dirSOI return false } ri = i.block.restartIndex(i.restartIndex, i.riLimit, i.offset) i.dir = dirBackward } else if i.dir == dirEOI { // At the end of iterator. i.restartIndex = i.riLimit i.offset = i.offsetLimit if i.offset == i.offsetRealStart { i.dir = dirSOI return false } ri = i.riLimit - 1 i.dir = dirBackward } else if len(i.prevNode) == 1 { // This is the end of a restart range. i.offset = i.prevNode[0] i.prevNode = i.prevNode[:0] if i.restartIndex == i.riStart { i.dir = dirSOI return false } i.restartIndex-- ri = i.restartIndex } else { // In the middle of restart range, get from cache. n := len(i.prevNode) - 3 node := i.prevNode[n:] i.prevNode = i.prevNode[:n] // Get the key. ko := node[0] i.key = append(i.key[:0], i.prevKeys[ko:]...) i.prevKeys = i.prevKeys[:ko] // Get the value. vo := node[1] vl := vo + node[2] i.value = i.block.data[vo:vl] i.offset = vl return true } // Build entries cache. i.key = i.key[:0] i.value = nil offset := i.block.restartOffset(ri) if offset == i.offset { ri-- if ri < 0 { i.dir = dirSOI return false } offset = i.block.restartOffset(ri) } i.prevNode = append(i.prevNode, offset) for { key, value, nShared, n, err := i.block.entry(offset) if err != nil { i.sErr(i.tr.fixErrCorruptedBH(i.block.bh, err)) return false } if offset >= i.offsetRealStart { if i.value != nil { // Appends 3 variables: // 1. Previous keys offset // 2. Value offset in the data block // 3. Value length i.prevNode = append(i.prevNode, len(i.prevKeys), offset-len(i.value), len(i.value)) i.prevKeys = append(i.prevKeys, i.key...) } i.value = value } i.key = append(i.key[:nShared], key...) offset += n // Stop if target offset reached. if offset >= i.offset { if offset != i.offset { i.sErr(i.tr.newErrCorruptedBH(i.block.bh, "entries offset not aligned")) return false } break } } i.restartIndex = ri i.offset = offset return true } func (i *blockIter) Key() []byte { if i.err != nil || i.dir <= dirEOI { return nil } return i.key } func (i *blockIter) Value() []byte { if i.err != nil || i.dir <= dirEOI { return nil } return i.value } func (i *blockIter) Release() { if i.dir != dirReleased { i.tr = nil i.block = nil i.prevNode = nil i.prevKeys = nil i.key = nil i.value = nil i.dir = dirReleased if i.blockReleaser != nil { i.blockReleaser.Release() i.blockReleaser = nil } if i.releaser != nil { i.releaser.Release() i.releaser = nil } } } func (i *blockIter) SetReleaser(releaser util.Releaser) { if i.dir == dirReleased { panic(util.ErrReleased) } if i.releaser != nil && releaser != nil { panic(util.ErrHasReleaser) } i.releaser = releaser } func (i *blockIter) Valid() bool { return i.err == nil && (i.dir == dirBackward || i.dir == dirForward) } func (i *blockIter) Error() error { return i.err } type filterBlock struct { bpool *util.BufferPool data []byte oOffset int baseLg uint filtersNum int } func (b *filterBlock) contains(filter filter.Filter, offset uint64, key []byte) bool { i := int(offset >> b.baseLg) if i < b.filtersNum { o := b.data[b.oOffset+i*4:] n := int(binary.LittleEndian.Uint32(o)) m := int(binary.LittleEndian.Uint32(o[4:])) if n < m && m <= b.oOffset { return filter.Contains(b.data[n:m], key) } else if n == m { return false } } return true } func (b *filterBlock) Release() { b.bpool.Put(b.data) b.bpool = nil b.data = nil } type indexIter struct { *blockIter tr *Reader slice *util.Range // Options fillCache bool } func (i *indexIter) Get() iterator.Iterator { value := i.Value() if value == nil { return nil } dataBH, n := decodeBlockHandle(value) if n == 0 { return iterator.NewEmptyIterator(i.tr.newErrCorruptedBH(i.tr.indexBH, "bad data block handle")) } var slice *util.Range if i.slice != nil && (i.blockIter.isFirst() || i.blockIter.isLast()) { slice = i.slice } return i.tr.getDataIterErr(dataBH, slice, i.tr.verifyChecksum, i.fillCache) } // Reader is a table reader. type Reader struct { mu sync.RWMutex fd storage.FileDesc reader io.ReaderAt cache *cache.NamespaceGetter err error bpool *util.BufferPool // Options o *opt.Options cmp comparer.Comparer filter filter.Filter verifyChecksum bool dataEnd int64 metaBH, indexBH, filterBH blockHandle indexBlock *block filterBlock *filterBlock } func (r *Reader) blockKind(bh blockHandle) string { switch bh.offset { case r.metaBH.offset: return "meta-block" case r.indexBH.offset: return "index-block" case r.filterBH.offset: if r.filterBH.length > 0 { return "filter-block" } } return "data-block" } func (r *Reader) newErrCorrupted(pos, size int64, kind, reason string) error { return &errors.ErrCorrupted{Fd: r.fd, Err: &ErrCorrupted{Pos: pos, Size: size, Kind: kind, Reason: reason}} } func (r *Reader) newErrCorruptedBH(bh blockHandle, reason string) error { return r.newErrCorrupted(int64(bh.offset), int64(bh.length), r.blockKind(bh), reason) } func (r *Reader) fixErrCorruptedBH(bh blockHandle, err error) error { if cerr, ok := err.(*ErrCorrupted); ok { cerr.Pos = int64(bh.offset) cerr.Size = int64(bh.length) cerr.Kind = r.blockKind(bh) return &errors.ErrCorrupted{Fd: r.fd, Err: cerr} } return err } func (r *Reader) readRawBlock(bh blockHandle, verifyChecksum bool) ([]byte, error) { data := r.bpool.Get(int(bh.length + blockTrailerLen)) if _, err := r.reader.ReadAt(data, int64(bh.offset)); err != nil && err != io.EOF { return nil, err } if verifyChecksum { n := bh.length + 1 checksum0 := binary.LittleEndian.Uint32(data[n:]) checksum1 := util.NewCRC(data[:n]).Value() if checksum0 != checksum1 { r.bpool.Put(data) return nil, r.newErrCorruptedBH(bh, fmt.Sprintf("checksum mismatch, want=%#x got=%#x", checksum0, checksum1)) } } switch data[bh.length] { case blockTypeNoCompression: data = data[:bh.length] case blockTypeSnappyCompression: decLen, err := snappy.DecodedLen(data[:bh.length]) if err != nil { r.bpool.Put(data) return nil, r.newErrCorruptedBH(bh, err.Error()) } decData := r.bpool.Get(decLen) decData, err = snappy.Decode(decData, data[:bh.length]) r.bpool.Put(data) if err != nil { r.bpool.Put(decData) return nil, r.newErrCorruptedBH(bh, err.Error()) } data = decData default: r.bpool.Put(data) return nil, r.newErrCorruptedBH(bh, fmt.Sprintf("unknown compression type %#x", data[bh.length])) } return data, nil } func (r *Reader) readBlock(bh blockHandle, verifyChecksum bool) (*block, error) { data, err := r.readRawBlock(bh, verifyChecksum) if err != nil { return nil, err } restartsLen := int(binary.LittleEndian.Uint32(data[len(data)-4:])) b := &block{ bpool: r.bpool, bh: bh, data: data, restartsLen: restartsLen, restartsOffset: len(data) - (restartsLen+1)*4, } return b, nil } func (r *Reader) readBlockCached(bh blockHandle, verifyChecksum, fillCache bool) (*block, util.Releaser, error) { if r.cache != nil { var ( err error ch *cache.Handle ) if fillCache { ch = r.cache.Get(bh.offset, func() (size int, value cache.Value) { var b *block b, err = r.readBlock(bh, verifyChecksum) if err != nil { return 0, nil } return cap(b.data), b }) } else { ch = r.cache.Get(bh.offset, nil) } if ch != nil { b, ok := ch.Value().(*block) if !ok { ch.Release() return nil, nil, errors.New("leveldb/table: inconsistent block type") } return b, ch, err } else if err != nil { return nil, nil, err } } b, err := r.readBlock(bh, verifyChecksum) return b, b, err } func (r *Reader) readFilterBlock(bh blockHandle) (*filterBlock, error) { data, err := r.readRawBlock(bh, true) if err != nil { return nil, err } n := len(data) if n < 5 { return nil, r.newErrCorruptedBH(bh, "too short") } m := n - 5 oOffset := int(binary.LittleEndian.Uint32(data[m:])) if oOffset > m { return nil, r.newErrCorruptedBH(bh, "invalid data-offsets offset") } b := &filterBlock{ bpool: r.bpool, data: data, oOffset: oOffset, baseLg: uint(data[n-1]), filtersNum: (m - oOffset) / 4, } return b, nil } func (r *Reader) readFilterBlockCached(bh blockHandle, fillCache bool) (*filterBlock, util.Releaser, error) { if r.cache != nil { var ( err error ch *cache.Handle ) if fillCache { ch = r.cache.Get(bh.offset, func() (size int, value cache.Value) { var b *filterBlock b, err = r.readFilterBlock(bh) if err != nil { return 0, nil } return cap(b.data), b }) } else { ch = r.cache.Get(bh.offset, nil) } if ch != nil { b, ok := ch.Value().(*filterBlock) if !ok { ch.Release() return nil, nil, errors.New("leveldb/table: inconsistent block type") } return b, ch, err } else if err != nil { return nil, nil, err } } b, err := r.readFilterBlock(bh) return b, b, err } func (r *Reader) getIndexBlock(fillCache bool) (b *block, rel util.Releaser, err error) { if r.indexBlock == nil { return r.readBlockCached(r.indexBH, true, fillCache) } return r.indexBlock, util.NoopReleaser{}, nil } func (r *Reader) getFilterBlock(fillCache bool) (*filterBlock, util.Releaser, error) { if r.filterBlock == nil { return r.readFilterBlockCached(r.filterBH, fillCache) } return r.filterBlock, util.NoopReleaser{}, nil } func (r *Reader) newBlockIter(b *block, bReleaser util.Releaser, slice *util.Range, inclLimit bool) *blockIter { bi := &blockIter{ tr: r, block: b, blockReleaser: bReleaser, // Valid key should never be nil. key: make([]byte, 0), dir: dirSOI, riStart: 0, riLimit: b.restartsLen, offsetStart: 0, offsetRealStart: 0, offsetLimit: b.restartsOffset, } if slice != nil { if slice.Start != nil { if bi.Seek(slice.Start) { bi.riStart = b.restartIndex(bi.restartIndex, b.restartsLen, bi.prevOffset) bi.offsetStart = b.restartOffset(bi.riStart) bi.offsetRealStart = bi.prevOffset } else { bi.riStart = b.restartsLen bi.offsetStart = b.restartsOffset bi.offsetRealStart = b.restartsOffset } } if slice.Limit != nil { if bi.Seek(slice.Limit) && (!inclLimit || bi.Next()) { bi.offsetLimit = bi.prevOffset bi.riLimit = bi.restartIndex + 1 } } bi.reset() if bi.offsetStart > bi.offsetLimit { bi.sErr(errors.New("leveldb/table: invalid slice range")) } } return bi } func (r *Reader) getDataIter(dataBH blockHandle, slice *util.Range, verifyChecksum, fillCache bool) iterator.Iterator { b, rel, err := r.readBlockCached(dataBH, verifyChecksum, fillCache) if err != nil { return iterator.NewEmptyIterator(err) } return r.newBlockIter(b, rel, slice, false) } func (r *Reader) getDataIterErr(dataBH blockHandle, slice *util.Range, verifyChecksum, fillCache bool) iterator.Iterator { r.mu.RLock() defer r.mu.RUnlock() if r.err != nil { return iterator.NewEmptyIterator(r.err) } return r.getDataIter(dataBH, slice, verifyChecksum, fillCache) } // NewIterator creates an iterator from the table. // // Slice allows slicing the iterator to only contains keys in the given // range. A nil Range.Start is treated as a key before all keys in the // table. And a nil Range.Limit is treated as a key after all keys in // the table. // // The returned iterator is not safe for concurrent use and should be released // after use. // // Also read Iterator documentation of the leveldb/iterator package. func (r *Reader) NewIterator(slice *util.Range, ro *opt.ReadOptions) iterator.Iterator { r.mu.RLock() defer r.mu.RUnlock() if r.err != nil { return iterator.NewEmptyIterator(r.err) } fillCache := !ro.GetDontFillCache() indexBlock, rel, err := r.getIndexBlock(fillCache) if err != nil { return iterator.NewEmptyIterator(err) } index := &indexIter{ blockIter: r.newBlockIter(indexBlock, rel, slice, true), tr: r, slice: slice, fillCache: !ro.GetDontFillCache(), } return iterator.NewIndexedIterator(index, opt.GetStrict(r.o, ro, opt.StrictReader)) } func (r *Reader) find(key []byte, filtered bool, ro *opt.ReadOptions, noValue bool) (rkey, value []byte, err error) { r.mu.RLock() defer r.mu.RUnlock() if r.err != nil { err = r.err return } indexBlock, rel, err := r.getIndexBlock(true) if err != nil { return } defer rel.Release() index := r.newBlockIter(indexBlock, nil, nil, true) defer index.Release() if !index.Seek(key) { if err = index.Error(); err == nil { err = ErrNotFound } return } dataBH, n := decodeBlockHandle(index.Value()) if n == 0 { r.err = r.newErrCorruptedBH(r.indexBH, "bad data block handle") return nil, nil, r.err } // The filter should only used for exact match. if filtered && r.filter != nil { filterBlock, frel, ferr := r.getFilterBlock(true) if ferr == nil { if !filterBlock.contains(r.filter, dataBH.offset, key) { frel.Release() return nil, nil, ErrNotFound } frel.Release() } else if !errors.IsCorrupted(ferr) { return nil, nil, ferr } } data := r.getDataIter(dataBH, nil, r.verifyChecksum, !ro.GetDontFillCache()) if !data.Seek(key) { data.Release() if err = data.Error(); err != nil { return } // The nearest greater-than key is the first key of the next block. if !index.Next() { if err = index.Error(); err == nil { err = ErrNotFound } return } dataBH, n = decodeBlockHandle(index.Value()) if n == 0 { r.err = r.newErrCorruptedBH(r.indexBH, "bad data block handle") return nil, nil, r.err } data = r.getDataIter(dataBH, nil, r.verifyChecksum, !ro.GetDontFillCache()) if !data.Next() { data.Release() if err = data.Error(); err == nil { err = ErrNotFound } return } } // Key doesn't use block buffer, no need to copy the buffer. rkey = data.Key() if !noValue { if r.bpool == nil { value = data.Value() } else { // Value does use block buffer, and since the buffer will be // recycled, it need to be copied. value = append([]byte{}, data.Value()...) } } data.Release() return } // Find finds key/value pair whose key is greater than or equal to the // given key. It returns ErrNotFound if the table doesn't contain // such pair. // If filtered is true then the nearest 'block' will be checked against // 'filter data' (if present) and will immediately return ErrNotFound if // 'filter data' indicates that such pair doesn't exist. // // The caller may modify the contents of the returned slice as it is its // own copy. // It is safe to modify the contents of the argument after Find returns. func (r *Reader) Find(key []byte, filtered bool, ro *opt.ReadOptions) (rkey, value []byte, err error) { return r.find(key, filtered, ro, false) } // FindKey finds key that is greater than or equal to the given key. // It returns ErrNotFound if the table doesn't contain such key. // If filtered is true then the nearest 'block' will be checked against // 'filter data' (if present) and will immediately return ErrNotFound if // 'filter data' indicates that such key doesn't exist. // // The caller may modify the contents of the returned slice as it is its // own copy. // It is safe to modify the contents of the argument after Find returns. func (r *Reader) FindKey(key []byte, filtered bool, ro *opt.ReadOptions) (rkey []byte, err error) { rkey, _, err = r.find(key, filtered, ro, true) return } // Get gets the value for the given key. It returns errors.ErrNotFound // if the table does not contain the key. // // The caller may modify the contents of the returned slice as it is its // own copy. // It is safe to modify the contents of the argument after Find returns. func (r *Reader) Get(key []byte, ro *opt.ReadOptions) (value []byte, err error) { r.mu.RLock() defer r.mu.RUnlock() if r.err != nil { err = r.err return } rkey, value, err := r.find(key, false, ro, false) if err == nil && r.cmp.Compare(rkey, key) != 0 { value = nil err = ErrNotFound } return } // OffsetOf returns approximate offset for the given key. // // It is safe to modify the contents of the argument after Get returns. func (r *Reader) OffsetOf(key []byte) (offset int64, err error) { r.mu.RLock() defer r.mu.RUnlock() if r.err != nil { err = r.err return } indexBlock, rel, err := r.readBlockCached(r.indexBH, true, true) if err != nil { return } defer rel.Release() index := r.newBlockIter(indexBlock, nil, nil, true) defer index.Release() if index.Seek(key) { dataBH, n := decodeBlockHandle(index.Value()) if n == 0 { r.err = r.newErrCorruptedBH(r.indexBH, "bad data block handle") return } offset = int64(dataBH.offset) return } err = index.Error() if err == nil { offset = r.dataEnd } return } // Release implements util.Releaser. // It also close the file if it is an io.Closer. func (r *Reader) Release() { r.mu.Lock() defer r.mu.Unlock() if closer, ok := r.reader.(io.Closer); ok { closer.Close() } if r.indexBlock != nil { r.indexBlock.Release() r.indexBlock = nil } if r.filterBlock != nil { r.filterBlock.Release() r.filterBlock = nil } r.reader = nil r.cache = nil r.bpool = nil r.err = ErrReaderReleased } // NewReader creates a new initialized table reader for the file. // The fi, cache and bpool is optional and can be nil. // // The returned table reader instance is safe for concurrent use. func NewReader(f io.ReaderAt, size int64, fd storage.FileDesc, cache *cache.NamespaceGetter, bpool *util.BufferPool, o *opt.Options) (*Reader, error) { if f == nil { return nil, errors.New("leveldb/table: nil file") } r := &Reader{ fd: fd, reader: f, cache: cache, bpool: bpool, o: o, cmp: o.GetComparer(), verifyChecksum: o.GetStrict(opt.StrictBlockChecksum), } if size < footerLen { r.err = r.newErrCorrupted(0, size, "table", "too small") return r, nil } footerPos := size - footerLen var footer [footerLen]byte if _, err := r.reader.ReadAt(footer[:], footerPos); err != nil && err != io.EOF { return nil, err } if string(footer[footerLen-len(magic):footerLen]) != magic { r.err = r.newErrCorrupted(footerPos, footerLen, "table-footer", "bad magic number") return r, nil } var n int // Decode the metaindex block handle. r.metaBH, n = decodeBlockHandle(footer[:]) if n == 0 { r.err = r.newErrCorrupted(footerPos, footerLen, "table-footer", "bad metaindex block handle") return r, nil } // Decode the index block handle. r.indexBH, n = decodeBlockHandle(footer[n:]) if n == 0 { r.err = r.newErrCorrupted(footerPos, footerLen, "table-footer", "bad index block handle") return r, nil } // Read metaindex block. metaBlock, err := r.readBlock(r.metaBH, true) if err != nil { if errors.IsCorrupted(err) { r.err = err return r, nil } return nil, err } // Set data end. r.dataEnd = int64(r.metaBH.offset) // Read metaindex. metaIter := r.newBlockIter(metaBlock, nil, nil, true) for metaIter.Next() { key := string(metaIter.Key()) if !strings.HasPrefix(key, "filter.") { continue } fn := key[7:] if f0 := o.GetFilter(); f0 != nil && f0.Name() == fn { r.filter = f0 } else { for _, f0 := range o.GetAltFilters() { if f0.Name() == fn { r.filter = f0 break } } } if r.filter != nil { filterBH, n := decodeBlockHandle(metaIter.Value()) if n == 0 { continue } r.filterBH = filterBH // Update data end. r.dataEnd = int64(filterBH.offset) break } } metaIter.Release() metaBlock.Release() // Cache index and filter block locally, since we don't have global cache. if cache == nil { r.indexBlock, err = r.readBlock(r.indexBH, true) if err != nil { if errors.IsCorrupted(err) { r.err = err return r, nil } return nil, err } if r.filter != nil { r.filterBlock, err = r.readFilterBlock(r.filterBH) if err != nil { if !errors.IsCorrupted(err) { return nil, err } // Don't use filter then. r.filter = nil } } } return r, nil }