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iterator.go
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/*
* Copyright 2017 Dgraph Labs, Inc. and Contributors
*
* 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 badger
import (
"bytes"
"fmt"
"hash/crc32"
"math"
"sort"
"sync"
"time"
"github.com/dgraph-io/badger/v4/table"
"github.com/dgraph-io/badger/v4/y"
"github.com/dgraph-io/ristretto/z"
)
type prefetchStatus uint8
const (
prefetched prefetchStatus = iota + 1
)
// Item is returned during iteration. Both the Key() and Value() output is only valid until
// iterator.Next() is called.
type Item struct {
key []byte
vptr []byte
val []byte
version uint64
expiresAt uint64
slice *y.Slice // Used only during prefetching.
next *Item
txn *Txn
err error
wg sync.WaitGroup
status prefetchStatus
meta byte // We need to store meta to know about bitValuePointer.
userMeta byte
}
// String returns a string representation of Item
func (item *Item) String() string {
return fmt.Sprintf("key=%q, version=%d, meta=%x", item.Key(), item.Version(), item.meta)
}
// Key returns the key.
//
// Key is only valid as long as item is valid, or transaction is valid. If you need to use it
// outside its validity, please use KeyCopy.
func (item *Item) Key() []byte {
return item.key
}
// KeyCopy returns a copy of the key of the item, writing it to dst slice.
// If nil is passed, or capacity of dst isn't sufficient, a new slice would be allocated and
// returned.
func (item *Item) KeyCopy(dst []byte) []byte {
return y.SafeCopy(dst, item.key)
}
// Version returns the commit timestamp of the item.
func (item *Item) Version() uint64 {
return item.version
}
// Value retrieves the value of the item from the value log.
//
// This method must be called within a transaction. Calling it outside a
// transaction is considered undefined behavior. If an iterator is being used,
// then Item.Value() is defined in the current iteration only, because items are
// reused.
//
// If you need to use a value outside a transaction, please use Item.ValueCopy
// instead, or copy it yourself. Value might change once discard or commit is called.
// Use ValueCopy if you want to do a Set after Get.
func (item *Item) Value(fn func(val []byte) error) error {
item.wg.Wait()
if item.status == prefetched {
if item.err == nil && fn != nil {
if err := fn(item.val); err != nil {
return err
}
}
return item.err
}
buf, cb, err := item.yieldItemValue()
defer runCallback(cb)
if err != nil {
return err
}
if fn != nil {
return fn(buf)
}
return nil
}
// ValueCopy returns a copy of the value of the item from the value log, writing it to dst slice.
// If nil is passed, or capacity of dst isn't sufficient, a new slice would be allocated and
// returned. Tip: It might make sense to reuse the returned slice as dst argument for the next call.
//
// This function is useful in long running iterate/update transactions to avoid a write deadlock.
// See Github issue: https://github.com/dgraph-io/badger/issues/315
func (item *Item) ValueCopy(dst []byte) ([]byte, error) {
item.wg.Wait()
if item.status == prefetched {
return y.SafeCopy(dst, item.val), item.err
}
buf, cb, err := item.yieldItemValue()
defer runCallback(cb)
return y.SafeCopy(dst, buf), err
}
func (item *Item) hasValue() bool {
if item.meta == 0 && item.vptr == nil {
// key not found
return false
}
return true
}
// IsDeletedOrExpired returns true if item contains deleted or expired value.
func (item *Item) IsDeletedOrExpired() bool {
return isDeletedOrExpired(item.meta, item.expiresAt)
}
// DiscardEarlierVersions returns whether the item was created with the
// option to discard earlier versions of a key when multiple are available.
func (item *Item) DiscardEarlierVersions() bool {
return item.meta&bitDiscardEarlierVersions > 0
}
func (item *Item) yieldItemValue() ([]byte, func(), error) {
key := item.Key() // No need to copy.
if !item.hasValue() {
return nil, nil, nil
}
if item.slice == nil {
item.slice = new(y.Slice)
}
if (item.meta & bitValuePointer) == 0 {
val := item.slice.Resize(len(item.vptr))
copy(val, item.vptr)
return val, nil, nil
}
var vp valuePointer
vp.Decode(item.vptr)
db := item.txn.db
result, cb, err := db.vlog.Read(vp, item.slice)
if err != nil {
db.opt.Errorf("Unable to read: Key: %v, Version : %v, meta: %v, userMeta: %v"+
" Error: %v", key, item.version, item.meta, item.userMeta, err)
var txn *Txn
if db.opt.managedTxns {
txn = db.NewTransactionAt(math.MaxUint64, false)
} else {
txn = db.NewTransaction(false)
}
defer txn.Discard()
iopt := DefaultIteratorOptions
iopt.AllVersions = true
iopt.InternalAccess = true
iopt.PrefetchValues = false
it := txn.NewKeyIterator(item.Key(), iopt)
defer it.Close()
for it.Rewind(); it.Valid(); it.Next() {
item := it.Item()
var vp valuePointer
if item.meta&bitValuePointer > 0 {
vp.Decode(item.vptr)
}
db.opt.Errorf("Key: %v, Version : %v, meta: %v, userMeta: %v valuePointer: %+v",
item.Key(), item.version, item.meta, item.userMeta, vp)
}
}
// Don't return error if we cannot read the value. Just log the error.
return result, cb, nil
}
func runCallback(cb func()) {
if cb != nil {
cb()
}
}
func (item *Item) prefetchValue() {
val, cb, err := item.yieldItemValue()
defer runCallback(cb)
item.err = err
item.status = prefetched
if val == nil {
return
}
buf := item.slice.Resize(len(val))
copy(buf, val)
item.val = buf
}
// EstimatedSize returns the approximate size of the key-value pair.
//
// This can be called while iterating through a store to quickly estimate the
// size of a range of key-value pairs (without fetching the corresponding
// values).
func (item *Item) EstimatedSize() int64 {
if !item.hasValue() {
return 0
}
if (item.meta & bitValuePointer) == 0 {
return int64(len(item.key) + len(item.vptr))
}
var vp valuePointer
vp.Decode(item.vptr)
return int64(vp.Len) // includes key length.
}
// KeySize returns the size of the key.
// Exact size of the key is key + 8 bytes of timestamp
func (item *Item) KeySize() int64 {
return int64(len(item.key))
}
// ValueSize returns the approximate size of the value.
//
// This can be called to quickly estimate the size of a value without fetching
// it.
func (item *Item) ValueSize() int64 {
if !item.hasValue() {
return 0
}
if (item.meta & bitValuePointer) == 0 {
return int64(len(item.vptr))
}
var vp valuePointer
vp.Decode(item.vptr)
klen := int64(len(item.key) + 8) // 8 bytes for timestamp.
// 6 bytes are for the approximate length of the header. Since header is encoded in varint, we
// cannot find the exact length of header without fetching it.
return int64(vp.Len) - klen - 6 - crc32.Size
}
// UserMeta returns the userMeta set by the user. Typically, this byte, optionally set by the user
// is used to interpret the value.
func (item *Item) UserMeta() byte {
return item.userMeta
}
// ExpiresAt returns a Unix time value indicating when the item will be
// considered expired. 0 indicates that the item will never expire.
func (item *Item) ExpiresAt() uint64 {
return item.expiresAt
}
// TODO: Switch this to use linked list container in Go.
type list struct {
head *Item
tail *Item
}
func (l *list) push(i *Item) {
i.next = nil
if l.tail == nil {
l.head = i
l.tail = i
return
}
l.tail.next = i
l.tail = i
}
func (l *list) pop() *Item {
if l.head == nil {
return nil
}
i := l.head
if l.head == l.tail {
l.tail = nil
l.head = nil
} else {
l.head = i.next
}
i.next = nil
return i
}
// IteratorOptions is used to set options when iterating over Badger key-value
// stores.
//
// This package provides DefaultIteratorOptions which contains options that
// should work for most applications. Consider using that as a starting point
// before customizing it for your own needs.
type IteratorOptions struct {
// PrefetchSize is the number of KV pairs to prefetch while iterating.
// Valid only if PrefetchValues is true.
PrefetchSize int
// PrefetchValues Indicates whether we should prefetch values during
// iteration and store them.
PrefetchValues bool
Reverse bool // Direction of iteration. False is forward, true is backward.
AllVersions bool // Fetch all valid versions of the same key.
InternalAccess bool // Used to allow internal access to badger keys.
// The following option is used to narrow down the SSTables that iterator
// picks up. If Prefix is specified, only tables which could have this
// prefix are picked based on their range of keys.
prefixIsKey bool // If set, use the prefix for bloom filter lookup.
Prefix []byte // Only iterate over this given prefix.
SinceTs uint64 // Only read data that has version > SinceTs.
}
func (opt *IteratorOptions) compareToPrefix(key []byte) int {
// We should compare key without timestamp. For example key - a[TS] might be > "aa" prefix.
key = y.ParseKey(key)
if len(key) > len(opt.Prefix) {
key = key[:len(opt.Prefix)]
}
return bytes.Compare(key, opt.Prefix)
}
func (opt *IteratorOptions) pickTable(t table.TableInterface) bool {
// Ignore this table if its max version is less than the sinceTs.
if t.MaxVersion() < opt.SinceTs {
return false
}
if len(opt.Prefix) == 0 {
return true
}
if opt.compareToPrefix(t.Smallest()) > 0 {
return false
}
if opt.compareToPrefix(t.Biggest()) < 0 {
return false
}
// Bloom filter lookup would only work if opt.Prefix does NOT have the read
// timestamp as part of the key.
if opt.prefixIsKey && t.DoesNotHave(y.Hash(opt.Prefix)) {
return false
}
return true
}
// pickTables picks the necessary table for the iterator. This function also assumes
// that the tables are sorted in the right order.
func (opt *IteratorOptions) pickTables(all []*table.Table) []*table.Table {
filterTables := func(tables []*table.Table) []*table.Table {
if opt.SinceTs > 0 {
tmp := tables[:0]
for _, t := range tables {
if t.MaxVersion() < opt.SinceTs {
continue
}
tmp = append(tmp, t)
}
tables = tmp
}
return tables
}
if len(opt.Prefix) == 0 {
out := make([]*table.Table, len(all))
copy(out, all)
return filterTables(out)
}
sIdx := sort.Search(len(all), func(i int) bool {
// table.Biggest >= opt.prefix
// if opt.Prefix < table.Biggest, then surely it is not in any of the preceding tables.
return opt.compareToPrefix(all[i].Biggest()) >= 0
})
if sIdx == len(all) {
// Not found.
return []*table.Table{}
}
filtered := all[sIdx:]
if !opt.prefixIsKey {
eIdx := sort.Search(len(filtered), func(i int) bool {
return opt.compareToPrefix(filtered[i].Smallest()) > 0
})
out := make([]*table.Table, len(filtered[:eIdx]))
copy(out, filtered[:eIdx])
return filterTables(out)
}
// opt.prefixIsKey == true. This code is optimizing for opt.prefixIsKey part.
var out []*table.Table
hash := y.Hash(opt.Prefix)
for _, t := range filtered {
// When we encounter the first table whose smallest key is higher than opt.Prefix, we can
// stop. This is an IMPORTANT optimization, just considering how often we call
// NewKeyIterator.
if opt.compareToPrefix(t.Smallest()) > 0 {
// if table.Smallest > opt.Prefix, then this and all tables after this can be ignored.
break
}
// opt.Prefix is actually the key. So, we can run bloom filter checks
// as well.
if t.DoesNotHave(hash) {
continue
}
out = append(out, t)
}
return filterTables(out)
}
// DefaultIteratorOptions contains default options when iterating over Badger key-value stores.
var DefaultIteratorOptions = IteratorOptions{
PrefetchValues: true,
PrefetchSize: 100,
Reverse: false,
AllVersions: false,
}
// Iterator helps iterating over the KV pairs in a lexicographically sorted order.
type Iterator struct {
iitr y.Iterator
txn *Txn
readTs uint64
opt IteratorOptions
item *Item
data list
waste list
lastKey []byte // Used to skip over multiple versions of the same key.
closed bool
scanned int // Used to estimate the size of data scanned by iterator.
// ThreadId is an optional value that can be set to identify which goroutine created
// the iterator. It can be used, for example, to uniquely identify each of the
// iterators created by the stream interface
ThreadId int
Alloc *z.Allocator
}
// NewIterator returns a new iterator. Depending upon the options, either only keys, or both
// key-value pairs would be fetched. The keys are returned in lexicographically sorted order.
// Using prefetch is recommended if you're doing a long running iteration, for performance.
//
// Multiple Iterators:
// For a read-only txn, multiple iterators can be running simultaneously. However, for a read-write
// txn, iterators have the nuance of being a snapshot of the writes for the transaction at the time
// iterator was created. If writes are performed after an iterator is created, then that iterator
// will not be able to see those writes. Only writes performed before an iterator was created can be
// viewed.
func (txn *Txn) NewIterator(opt IteratorOptions) *Iterator {
if txn.discarded {
panic(ErrDiscardedTxn)
}
if txn.db.IsClosed() {
panic(ErrDBClosed)
}
y.NumIteratorsCreatedAdd(txn.db.opt.MetricsEnabled, 1)
// Keep track of the number of active iterators.
txn.numIterators.Add(1)
// TODO: If Prefix is set, only pick those memtables which have keys with the prefix.
tables, decr := txn.db.getMemTables()
defer decr()
txn.db.vlog.incrIteratorCount()
var iters []y.Iterator
if itr := txn.newPendingWritesIterator(opt.Reverse); itr != nil {
iters = append(iters, itr)
}
for i := 0; i < len(tables); i++ {
iters = append(iters, tables[i].sl.NewUniIterator(opt.Reverse))
}
iters = txn.db.lc.appendIterators(iters, &opt) // This will increment references.
res := &Iterator{
txn: txn,
iitr: table.NewMergeIterator(iters, opt.Reverse),
opt: opt,
readTs: txn.readTs,
}
return res
}
// NewKeyIterator is just like NewIterator, but allows the user to iterate over all versions of a
// single key. Internally, it sets the Prefix option in provided opt, and uses that prefix to
// additionally run bloom filter lookups before picking tables from the LSM tree.
func (txn *Txn) NewKeyIterator(key []byte, opt IteratorOptions) *Iterator {
if len(opt.Prefix) > 0 {
panic("opt.Prefix should be nil for NewKeyIterator.")
}
opt.Prefix = key // This key must be without the timestamp.
opt.prefixIsKey = true
opt.AllVersions = true
return txn.NewIterator(opt)
}
func (it *Iterator) newItem() *Item {
item := it.waste.pop()
if item == nil {
item = &Item{slice: new(y.Slice), txn: it.txn}
}
return item
}
// Item returns pointer to the current key-value pair.
// This item is only valid until it.Next() gets called.
func (it *Iterator) Item() *Item {
tx := it.txn
tx.addReadKey(it.item.Key())
return it.item
}
// Valid returns false when iteration is done.
func (it *Iterator) Valid() bool {
if it.item == nil {
return false
}
if it.opt.prefixIsKey {
return bytes.Equal(it.item.key, it.opt.Prefix)
}
return bytes.HasPrefix(it.item.key, it.opt.Prefix)
}
// ValidForPrefix returns false when iteration is done
// or when the current key is not prefixed by the specified prefix.
func (it *Iterator) ValidForPrefix(prefix []byte) bool {
return it.Valid() && bytes.HasPrefix(it.item.key, prefix)
}
// Close would close the iterator. It is important to call this when you're done with iteration.
func (it *Iterator) Close() {
if it.closed {
return
}
it.closed = true
if it.iitr == nil {
it.txn.numIterators.Add(-1)
return
}
it.iitr.Close()
// It is important to wait for the fill goroutines to finish. Otherwise, we might leave zombie
// goroutines behind, which are waiting to acquire file read locks after DB has been closed.
waitFor := func(l list) {
item := l.pop()
for item != nil {
item.wg.Wait()
item = l.pop()
}
}
waitFor(it.waste)
waitFor(it.data)
// TODO: We could handle this error.
_ = it.txn.db.vlog.decrIteratorCount()
it.txn.numIterators.Add(-1)
}
// Next would advance the iterator by one. Always check it.Valid() after a Next()
// to ensure you have access to a valid it.Item().
func (it *Iterator) Next() {
if it.iitr == nil {
return
}
// Reuse current item
it.item.wg.Wait() // Just cleaner to wait before pushing to avoid doing ref counting.
it.scanned += len(it.item.key) + len(it.item.val) + len(it.item.vptr) + 2
it.waste.push(it.item)
// Set next item to current
it.item = it.data.pop()
for it.iitr.Valid() && hasPrefix(it) {
if it.parseItem() {
// parseItem calls one extra next.
// This is used to deal with the complexity of reverse iteration.
break
}
}
}
func isDeletedOrExpired(meta byte, expiresAt uint64) bool {
if meta&bitDelete > 0 {
return true
}
if expiresAt == 0 {
return false
}
return expiresAt <= uint64(time.Now().Unix())
}
// parseItem is a complex function because it needs to handle both forward and reverse iteration
// implementation. We store keys such that their versions are sorted in descending order. This makes
// forward iteration efficient, but revese iteration complicated. This tradeoff is better because
// forward iteration is more common than reverse. It returns true, if either the iterator is invalid
// or it has pushed an item into it.data list, else it returns false.
//
// This function advances the iterator.
func (it *Iterator) parseItem() bool {
mi := it.iitr
key := mi.Key()
setItem := func(item *Item) {
if it.item == nil {
it.item = item
} else {
it.data.push(item)
}
}
isInternalKey := bytes.HasPrefix(key, badgerPrefix)
// Skip badger keys.
if !it.opt.InternalAccess && isInternalKey {
mi.Next()
return false
}
// Skip any versions which are beyond the readTs.
version := y.ParseTs(key)
// Ignore everything that is above the readTs and below or at the sinceTs.
if version > it.readTs || (it.opt.SinceTs > 0 && version <= it.opt.SinceTs) {
mi.Next()
return false
}
// Skip banned keys only if it does not have badger internal prefix.
if !isInternalKey && it.txn.db.isBanned(key) != nil {
mi.Next()
return false
}
if it.opt.AllVersions {
// Return deleted or expired values also, otherwise user can't figure out
// whether the key was deleted.
item := it.newItem()
it.fill(item)
setItem(item)
mi.Next()
return true
}
// If iterating in forward direction, then just checking the last key against current key would
// be sufficient.
if !it.opt.Reverse {
if y.SameKey(it.lastKey, key) {
mi.Next()
return false
}
// Only track in forward direction.
// We should update lastKey as soon as we find a different key in our snapshot.
// Consider keys: a 5, b 7 (del), b 5. When iterating, lastKey = a.
// Then we see b 7, which is deleted. If we don't store lastKey = b, we'll then return b 5,
// which is wrong. Therefore, update lastKey here.
it.lastKey = y.SafeCopy(it.lastKey, mi.Key())
}
FILL:
// If deleted, advance and return.
vs := mi.Value()
if isDeletedOrExpired(vs.Meta, vs.ExpiresAt) {
mi.Next()
return false
}
item := it.newItem()
it.fill(item)
// fill item based on current cursor position. All Next calls have returned, so reaching here
// means no Next was called.
mi.Next() // Advance but no fill item yet.
if !it.opt.Reverse || !mi.Valid() { // Forward direction, or invalid.
setItem(item)
return true
}
// Reverse direction.
nextTs := y.ParseTs(mi.Key())
mik := y.ParseKey(mi.Key())
if nextTs <= it.readTs && bytes.Equal(mik, item.key) {
// This is a valid potential candidate.
goto FILL
}
// Ignore the next candidate. Return the current one.
setItem(item)
return true
}
func (it *Iterator) fill(item *Item) {
vs := it.iitr.Value()
item.meta = vs.Meta
item.userMeta = vs.UserMeta
item.expiresAt = vs.ExpiresAt
item.version = y.ParseTs(it.iitr.Key())
item.key = y.SafeCopy(item.key, y.ParseKey(it.iitr.Key()))
item.vptr = y.SafeCopy(item.vptr, vs.Value)
item.val = nil
if it.opt.PrefetchValues {
item.wg.Add(1)
go func() {
// FIXME we are not handling errors here.
item.prefetchValue()
item.wg.Done()
}()
}
}
func hasPrefix(it *Iterator) bool {
// We shouldn't check prefix in case the iterator is going in reverse. Since in reverse we expect
// people to append items to the end of prefix.
if !it.opt.Reverse && len(it.opt.Prefix) > 0 {
return bytes.HasPrefix(y.ParseKey(it.iitr.Key()), it.opt.Prefix)
}
return true
}
func (it *Iterator) prefetch() {
prefetchSize := 2
if it.opt.PrefetchValues && it.opt.PrefetchSize > 1 {
prefetchSize = it.opt.PrefetchSize
}
i := it.iitr
var count int
it.item = nil
for i.Valid() && hasPrefix(it) {
if !it.parseItem() {
continue
}
count++
if count == prefetchSize {
break
}
}
}
// Seek would seek to the provided key if present. If absent, it would seek to the next
// smallest key greater than the provided key if iterating in the forward direction.
// Behavior would be reversed if iterating backwards.
func (it *Iterator) Seek(key []byte) {
if it.iitr == nil {
return
}
if len(key) > 0 {
it.txn.addReadKey(key)
}
for i := it.data.pop(); i != nil; i = it.data.pop() {
i.wg.Wait()
it.waste.push(i)
}
it.lastKey = it.lastKey[:0]
if len(key) == 0 {
key = it.opt.Prefix
}
if len(key) == 0 {
it.iitr.Rewind()
it.prefetch()
return
}
if !it.opt.Reverse {
key = y.KeyWithTs(key, it.txn.readTs)
} else {
key = y.KeyWithTs(key, 0)
}
it.iitr.Seek(key)
it.prefetch()
}
// Rewind would rewind the iterator cursor all the way to zero-th position, which would be the
// smallest key if iterating forward, and largest if iterating backward. It does not keep track of
// whether the cursor started with a Seek().
func (it *Iterator) Rewind() {
it.Seek(nil)
}