package mergeset import ( "fmt" "os" "reflect" "sort" "strings" "sync" "unsafe" "github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil" "github.com/VictoriaMetrics/VictoriaMetrics/lib/cgroup" "github.com/VictoriaMetrics/VictoriaMetrics/lib/encoding" "github.com/VictoriaMetrics/VictoriaMetrics/lib/logger" ) // Item represents a single item for storing in a mergeset. type Item struct { // Start is start offset for the item in data. Start uint32 // End is end offset for the item in data. End uint32 } // Bytes returns bytes representation of it obtained from data. // // The returned bytes representation belongs to data. func (it Item) Bytes(data []byte) []byte { sh := (*reflect.SliceHeader)(unsafe.Pointer(&data)) sh.Cap = int(it.End - it.Start) sh.Len = int(it.End - it.Start) sh.Data += uintptr(it.Start) return data } // String returns string represetnation of it obtained from data. // // The returned string representation belongs to data. func (it Item) String(data []byte) string { sh := (*reflect.SliceHeader)(unsafe.Pointer(&data)) sh.Data += uintptr(it.Start) sh.Len = int(it.End - it.Start) return *(*string)(unsafe.Pointer(sh)) } func (ib *inmemoryBlock) Len() int { return len(ib.items) } func (ib *inmemoryBlock) Less(i, j int) bool { data := ib.data items := ib.items return string(items[i].Bytes(data)) < string(items[j].Bytes(data)) } func (ib *inmemoryBlock) Swap(i, j int) { items := ib.items items[i], items[j] = items[j], items[i] } type inmemoryBlock struct { commonPrefix []byte data []byte items []Item } func (ib *inmemoryBlock) SizeBytes() int { return int(unsafe.Sizeof(*ib)) + cap(ib.commonPrefix) + cap(ib.data) + cap(ib.items)*int(unsafe.Sizeof(Item{})) } func (ib *inmemoryBlock) Reset() { ib.commonPrefix = ib.commonPrefix[:0] ib.data = ib.data[:0] ib.items = ib.items[:0] } func (ib *inmemoryBlock) updateCommonPrefix() { ib.commonPrefix = ib.commonPrefix[:0] if len(ib.items) == 0 { return } items := ib.items data := ib.data cp := items[0].Bytes(data) if len(cp) == 0 { return } for _, it := range items[1:] { cpLen := commonPrefixLen(cp, it.Bytes(data)) if cpLen == 0 { return } cp = cp[:cpLen] } ib.commonPrefix = append(ib.commonPrefix[:0], cp...) } func commonPrefixLen(a, b []byte) int { i := 0 if len(a) > len(b) { for i < len(b) && a[i] == b[i] { i++ } } else { for i < len(a) && a[i] == b[i] { i++ } } return i } // Add adds x to the end of ib. // // false is returned if x isn't added to ib due to block size contraints. func (ib *inmemoryBlock) Add(x []byte) bool { data := ib.data if len(x)+len(data) > maxInmemoryBlockSize { return false } if cap(data) < maxInmemoryBlockSize { dataLen := len(data) data = bytesutil.Resize(data, maxInmemoryBlockSize)[:dataLen] } dataLen := len(data) data = append(data, x...) ib.items = append(ib.items, Item{ Start: uint32(dataLen), End: uint32(len(data)), }) ib.data = data return true } // maxInmemoryBlockSize is the maximum inmemoryBlock.data size. // // It must fit CPU cache size, i.e. 64KB for the current CPUs. const maxInmemoryBlockSize = 64 * 1024 func (ib *inmemoryBlock) sort() { sort.Sort(ib) data := ib.data items := ib.items bb := bbPool.Get() b := bytesutil.Resize(bb.B, len(data)) b = b[:0] for i, it := range items { bLen := len(b) b = append(b, it.String(data)...) items[i] = Item{ Start: uint32(bLen), End: uint32(len(b)), } } bb.B, ib.data = data, b bbPool.Put(bb) } // storageBlock represents a block of data on the storage. type storageBlock struct { itemsData []byte lensData []byte } func (sb *storageBlock) Reset() { sb.itemsData = sb.itemsData[:0] sb.lensData = sb.lensData[:0] } type marshalType uint8 const ( marshalTypePlain = marshalType(0) marshalTypeZSTD = marshalType(1) ) func checkMarshalType(mt marshalType) error { if mt < 0 || mt > 1 { return fmt.Errorf("marshalType must be in the range [0..1]; got %d", mt) } return nil } func (ib *inmemoryBlock) isSorted() bool { // Use sort.IsSorted instead of sort.SliceIsSorted in order to eliminate memory allocation. return sort.IsSorted(ib) } // MarshalUnsortedData marshals unsorted items from ib to sb. // // It also: // - appends first item to firstItemDst and returns the result. // - appends common prefix for all the items to commonPrefixDst and returns the result. // - returns the number of items encoded including the first item. // - returns the marshal type used for the encoding. func (ib *inmemoryBlock) MarshalUnsortedData(sb *storageBlock, firstItemDst, commonPrefixDst []byte, compressLevel int) ([]byte, []byte, uint32, marshalType) { if !ib.isSorted() { ib.sort() } ib.updateCommonPrefix() return ib.marshalData(sb, firstItemDst, commonPrefixDst, compressLevel) } var isInTest = func() bool { return strings.HasSuffix(os.Args[0], ".test") }() // MarshalSortedData marshals sorted items from ib to sb. // // It also: // - appends first item to firstItemDst and returns the result. // - appends common prefix for all the items to commonPrefixDst and returns the result. // - returns the number of items encoded including the first item. // - returns the marshal type used for the encoding. func (ib *inmemoryBlock) MarshalSortedData(sb *storageBlock, firstItemDst, commonPrefixDst []byte, compressLevel int) ([]byte, []byte, uint32, marshalType) { if isInTest && !ib.isSorted() { logger.Panicf("BUG: %d items must be sorted; items:\n%s", len(ib.items), ib.debugItemsString()) } ib.updateCommonPrefix() return ib.marshalData(sb, firstItemDst, commonPrefixDst, compressLevel) } func (ib *inmemoryBlock) debugItemsString() string { var sb strings.Builder var prevItem string data := ib.data for i, it := range ib.items { item := it.String(data) if item < prevItem { fmt.Fprintf(&sb, "!!! the next item is smaller than the previous item !!!\n") } fmt.Fprintf(&sb, "%05d %X\n", i, item) prevItem = item } return sb.String() } // Preconditions: // - ib.items must be sorted. // - updateCommonPrefix must be called. func (ib *inmemoryBlock) marshalData(sb *storageBlock, firstItemDst, commonPrefixDst []byte, compressLevel int) ([]byte, []byte, uint32, marshalType) { if len(ib.items) <= 0 { logger.Panicf("BUG: inmemoryBlock.marshalData must be called on non-empty blocks only") } if uint64(len(ib.items)) >= 1<<32 { logger.Panicf("BUG: the number of items in the block must be smaller than %d; got %d items", uint64(1<<32), len(ib.items)) } data := ib.data firstItem := ib.items[0].Bytes(data) firstItemDst = append(firstItemDst, firstItem...) commonPrefixDst = append(commonPrefixDst, ib.commonPrefix...) if len(ib.data)-len(ib.commonPrefix)*len(ib.items) < 64 || len(ib.items) < 2 { // Use plain encoding form small block, since it is cheaper. ib.marshalDataPlain(sb) return firstItemDst, commonPrefixDst, uint32(len(ib.items)), marshalTypePlain } bbItems := bbPool.Get() bItems := bbItems.B[:0] bbLens := bbPool.Get() bLens := bbLens.B[:0] // Marshal items data. xs := encoding.GetUint64s(len(ib.items) - 1) defer encoding.PutUint64s(xs) cpLen := len(ib.commonPrefix) prevItem := firstItem[cpLen:] prevPrefixLen := uint64(0) for i, it := range ib.items[1:] { it.Start += uint32(cpLen) item := it.Bytes(data) prefixLen := uint64(commonPrefixLen(prevItem, item)) bItems = append(bItems, item[prefixLen:]...) xLen := prefixLen ^ prevPrefixLen prevItem = item prevPrefixLen = prefixLen xs.A[i] = xLen } bLens = encoding.MarshalVarUint64s(bLens, xs.A) sb.itemsData = encoding.CompressZSTDLevel(sb.itemsData[:0], bItems, compressLevel) bbItems.B = bItems bbPool.Put(bbItems) // Marshal lens data. prevItemLen := uint64(len(firstItem) - cpLen) for i, it := range ib.items[1:] { itemLen := uint64(int(it.End-it.Start) - cpLen) xLen := itemLen ^ prevItemLen prevItemLen = itemLen xs.A[i] = xLen } bLens = encoding.MarshalVarUint64s(bLens, xs.A) sb.lensData = encoding.CompressZSTDLevel(sb.lensData[:0], bLens, compressLevel) bbLens.B = bLens bbPool.Put(bbLens) if float64(len(sb.itemsData)) > 0.9*float64(len(ib.data)-len(ib.commonPrefix)*len(ib.items)) { // Bad compression rate. It is cheaper to use plain encoding. ib.marshalDataPlain(sb) return firstItemDst, commonPrefixDst, uint32(len(ib.items)), marshalTypePlain } // Good compression rate. return firstItemDst, commonPrefixDst, uint32(len(ib.items)), marshalTypeZSTD } // UnmarshalData decodes itemsCount items from sb and firstItem and stores // them to ib. func (ib *inmemoryBlock) UnmarshalData(sb *storageBlock, firstItem, commonPrefix []byte, itemsCount uint32, mt marshalType) error { ib.Reset() if itemsCount <= 0 { logger.Panicf("BUG: cannot unmarshal zero items") } ib.commonPrefix = append(ib.commonPrefix[:0], commonPrefix...) switch mt { case marshalTypePlain: if err := ib.unmarshalDataPlain(sb, firstItem, itemsCount); err != nil { return fmt.Errorf("cannot unmarshal plain data: %w", err) } if !ib.isSorted() { return fmt.Errorf("plain data block contains unsorted items; items:\n%s", ib.debugItemsString()) } return nil case marshalTypeZSTD: // it is handled below. default: return fmt.Errorf("unknown marshalType=%d", mt) } // Unmarshal mt = marshalTypeZSTD bb := bbPool.Get() defer bbPool.Put(bb) var err error // Unmarshal lens data. bb.B, err = encoding.DecompressZSTD(bb.B[:0], sb.lensData) if err != nil { return fmt.Errorf("cannot decompress lensData: %w", err) } lb := getLensBuffer(int(2 * itemsCount)) defer putLensBuffer(lb) prefixLens := lb.lens[:itemsCount] lens := lb.lens[itemsCount:] is := encoding.GetUint64s(int(itemsCount) - 1) defer encoding.PutUint64s(is) // Unmarshal prefixLens tail, err := encoding.UnmarshalVarUint64s(is.A, bb.B) if err != nil { return fmt.Errorf("cannot unmarshal prefixLens from lensData: %w", err) } prefixLens[0] = 0 for i, xLen := range is.A { prefixLens[i+1] = xLen ^ prefixLens[i] } // Unmarshal lens tail, err = encoding.UnmarshalVarUint64s(is.A, tail) if err != nil { return fmt.Errorf("cannot unmarshal lens from lensData: %w", err) } if len(tail) > 0 { return fmt.Errorf("unexpected tail left unmarshaling %d lens; tail size=%d; contents=%X", itemsCount, len(tail), tail) } lens[0] = uint64(len(firstItem) - len(commonPrefix)) dataLen := uint64(len(commonPrefix) * int(itemsCount)) dataLen += lens[0] for i, xLen := range is.A { itemLen := xLen ^ lens[i] lens[i+1] = itemLen dataLen += itemLen } // Unmarshal items data. bb.B, err = encoding.DecompressZSTD(bb.B[:0], sb.itemsData) if err != nil { return fmt.Errorf("cannot decompress lensData: %w", err) } data := bytesutil.Resize(ib.data, maxInmemoryBlockSize) if n := int(itemsCount) - cap(ib.items); n > 0 { ib.items = append(ib.items[:cap(ib.items)], make([]Item, n)...) } ib.items = ib.items[:itemsCount] data = append(data[:0], firstItem...) items := ib.items items[0] = Item{ Start: 0, End: uint32(len(data)), } prevItem := data[len(commonPrefix):] b := bb.B for i := 1; i < int(itemsCount); i++ { itemLen := lens[i] prefixLen := prefixLens[i] if prefixLen > itemLen { return fmt.Errorf("prefixLen=%d exceeds itemLen=%d", prefixLen, itemLen) } suffixLen := itemLen - prefixLen if uint64(len(b)) < suffixLen { return fmt.Errorf("not enough data for decoding item from itemsData; want %d bytes; remained %d bytes", suffixLen, len(b)) } if prefixLen > uint64(len(prevItem)) { return fmt.Errorf("prefixLen cannot exceed %d; got %d", len(prevItem), prefixLen) } dataLen := len(data) data = append(data, commonPrefix...) data = append(data, prevItem[:prefixLen]...) data = append(data, b[:suffixLen]...) items[i] = Item{ Start: uint32(dataLen), End: uint32(len(data)), } b = b[suffixLen:] prevItem = data[len(data)-int(itemLen):] } if len(b) > 0 { return fmt.Errorf("unexpected tail left after itemsData with len %d: %q", len(b), b) } if uint64(len(data)) != dataLen { return fmt.Errorf("unexpected data len; got %d; want %d", len(data), dataLen) } ib.data = data if !ib.isSorted() { return fmt.Errorf("decoded data block contains unsorted items; items:\n%s", ib.debugItemsString()) } return nil } var bbPool bytesutil.ByteBufferPool func (ib *inmemoryBlock) marshalDataPlain(sb *storageBlock) { data := ib.data // Marshal items data. // There is no need in marshaling the first item, since it is returned // to the caller in marshalData. cpLen := len(ib.commonPrefix) b := sb.itemsData[:0] for _, it := range ib.items[1:] { it.Start += uint32(cpLen) b = append(b, it.String(data)...) } sb.itemsData = b // Marshal length data. b = sb.lensData[:0] for _, it := range ib.items[1:] { b = encoding.MarshalUint64(b, uint64(int(it.End-it.Start)-cpLen)) } sb.lensData = b } func (ib *inmemoryBlock) unmarshalDataPlain(sb *storageBlock, firstItem []byte, itemsCount uint32) error { commonPrefix := ib.commonPrefix // Unmarshal lens data. lb := getLensBuffer(int(itemsCount)) defer putLensBuffer(lb) lb.lens[0] = uint64(len(firstItem) - len(commonPrefix)) b := sb.lensData for i := 1; i < int(itemsCount); i++ { if len(b) < 8 { return fmt.Errorf("too short tail for decoding len from lensData; got %d bytes; want at least %d bytes", len(b), 8) } iLen := encoding.UnmarshalUint64(b) b = b[8:] lb.lens[i] = iLen } if len(b) > 0 { return fmt.Errorf("unexpected tail left after lensData with len %d: %q", len(b), b) } // Unmarshal items data. data := ib.data items := ib.items data = bytesutil.Resize(data, len(firstItem)+len(sb.itemsData)+len(commonPrefix)*int(itemsCount)) data = append(data[:0], firstItem...) items = append(items[:0], Item{ Start: 0, End: uint32(len(data)), }) b = sb.itemsData for i := 1; i < int(itemsCount); i++ { itemLen := lb.lens[i] if uint64(len(b)) < itemLen { return fmt.Errorf("not enough data for decoding item from itemsData; want %d bytes; remained %d bytes", itemLen, len(b)) } dataLen := len(data) data = append(data, commonPrefix...) data = append(data, b[:itemLen]...) items = append(items, Item{ Start: uint32(dataLen), End: uint32(len(data)), }) b = b[itemLen:] } ib.data = data ib.items = items if len(b) > 0 { return fmt.Errorf("unexpected tail left after itemsData with len %d: %q", len(b), b) } return nil } type lensBuffer struct { lens []uint64 } var lensBufferPool sync.Pool func getLensBuffer(n int) *lensBuffer { v := lensBufferPool.Get() if v == nil { v = &lensBuffer{} } lb := v.(*lensBuffer) if nn := n - cap(lb.lens); nn > 0 { lb.lens = append(lb.lens[:cap(lb.lens)], make([]uint64, nn)...) } lb.lens = lb.lens[:n] return lb } func putLensBuffer(lb *lensBuffer) { lensBufferPool.Put(lb) } func getInmemoryBlock() *inmemoryBlock { select { case ib := <-ibPoolCh: return ib default: return &inmemoryBlock{} } } func putInmemoryBlock(ib *inmemoryBlock) { ib.Reset() select { case ibPoolCh <- ib: default: // drop ib in order to reduce memory usage on systems with big number of CPU cores } } // Every inmemoryBlock struct occupies at least 64KB of memory, e.g. quite big amounts of memory. // Use a chan instead of sync.Pool in order to reduce memory usage on systems // with big number of CPU cores. var ibPoolCh = make(chan *inmemoryBlock, cgroup.AvailableCPUs())