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mutable_tree.go
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mutable_tree.go
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package iavl
import (
"bytes"
"crypto/sha256"
"fmt"
"runtime"
"sort"
"sync"
"time"
"github.com/pkg/errors"
dbm "github.com/tendermint/tm-db"
)
// ErrVersionDoesNotExist is returned if a requested version does not exist.
var ErrVersionDoesNotExist = errors.New("version does not exist")
// MutableTree is a persistent tree which keeps track of versions. It is not safe for concurrent
// use, and should be guarded by a Mutex or RWLock as appropriate. An immutable tree at a given
// version can be returned via GetImmutable, which is safe for concurrent access.
//
// Given and returned key/value byte slices must not be modified, since they may point to data
// located inside IAVL which would also be modified.
//
// The inner ImmutableTree should not be used directly by callers.
type MutableTree struct {
*ImmutableTree // The current, working tree.
lastSaved *ImmutableTree // The most recently saved tree.
orphans map[string]int64 // Nodes removed by changes to working tree.
versions map[int64]bool // The previous, saved versions of the tree.
allRootLoaded bool // Whether all roots are loaded or not(by LazyLoadVersion)
unsavedFastNodeAdditions map[string]*FastNode // FastNodes that have not yet been saved to disk
unsavedFastNodeRemovals map[string]interface{} // FastNodes that have not yet been removed from disk
ndb *nodeDB
mtx sync.RWMutex // versions Read/write lock.
}
// NewMutableTree returns a new tree with the specified cache size and datastore.
func NewMutableTree(db dbm.DB, cacheSize int) (*MutableTree, error) {
return NewMutableTreeWithOpts(db, cacheSize, nil)
}
// NewMutableTreeWithOpts returns a new tree with the specified options.
func NewMutableTreeWithOpts(db dbm.DB, cacheSize int, opts *Options) (*MutableTree, error) {
ndb := newNodeDB(db, cacheSize, opts)
head := &ImmutableTree{ndb: ndb}
return &MutableTree{
ImmutableTree: head,
lastSaved: head.clone(),
orphans: map[string]int64{},
versions: map[int64]bool{},
allRootLoaded: false,
unsavedFastNodeAdditions: make(map[string]*FastNode),
unsavedFastNodeRemovals: make(map[string]interface{}),
ndb: ndb,
}, nil
}
// IsEmpty returns whether or not the tree has any keys. Only trees that are
// not empty can be saved.
func (tree *MutableTree) IsEmpty() bool {
return tree.ImmutableTree.Size() == 0
}
// VersionExists returns whether or not a version exists.
func (tree *MutableTree) VersionExists(version int64) bool {
tree.mtx.RLock()
defer tree.mtx.RUnlock()
if tree.allRootLoaded {
return tree.versions[version]
}
has, ok := tree.versions[version]
if ok {
return has
}
has, _ = tree.ndb.HasRoot(version)
tree.versions[version] = has
return has
}
// AvailableVersions returns all available versions in ascending order
func (tree *MutableTree) AvailableVersions() []int {
tree.mtx.RLock()
defer tree.mtx.RUnlock()
res := make([]int, 0, len(tree.versions))
for i, v := range tree.versions {
if v {
res = append(res, int(i))
}
}
sort.Ints(res)
return res
}
// Hash returns the hash of the latest saved version of the tree, as returned
// by SaveVersion. If no versions have been saved, Hash returns nil.
func (tree *MutableTree) Hash() []byte {
return tree.lastSaved.Hash()
}
// WorkingHash returns the hash of the current working tree.
func (tree *MutableTree) WorkingHash() []byte {
return tree.ImmutableTree.Hash()
}
// String returns a string representation of the tree.
func (tree *MutableTree) String() (string, error) {
return tree.ndb.String()
}
// Set/Remove will orphan at most tree.Height nodes,
// balancing the tree after a Set/Remove will orphan at most 3 nodes.
func (tree *MutableTree) prepareOrphansSlice() []*Node {
return make([]*Node, 0, tree.Height()+3)
}
// Set sets a key in the working tree. Nil values are invalid. The given
// key/value byte slices must not be modified after this call, since they point
// to slices stored within IAVL. It returns true when an existing value was
// updated, while false means it was a new key.
func (tree *MutableTree) Set(key, value []byte) (updated bool) {
var orphaned []*Node
orphaned, updated = tree.set(key, value)
tree.addOrphans(orphaned)
return updated
}
// Get returns the value of the specified key if it exists, or nil otherwise.
// The returned value must not be modified, since it may point to data stored within IAVL.
func (t *MutableTree) Get(key []byte) []byte {
if t.root == nil {
return nil
}
if fastNode, ok := t.unsavedFastNodeAdditions[string(key)]; ok {
return fastNode.value
}
return t.ImmutableTree.Get(key)
}
// Import returns an importer for tree nodes previously exported by ImmutableTree.Export(),
// producing an identical IAVL tree. The caller must call Close() on the importer when done.
//
// version should correspond to the version that was initially exported. It must be greater than
// or equal to the highest ExportNode version number given.
//
// Import can only be called on an empty tree. It is the callers responsibility that no other
// modifications are made to the tree while importing.
func (tree *MutableTree) Import(version int64) (*Importer, error) {
return newImporter(tree, version)
}
// Iterate iterates over all keys of the tree. The keys and values must not be modified,
// since they may point to data stored within IAVL. Returns true if stopped by callnack, false otherwise
func (t *MutableTree) Iterate(fn func(key []byte, value []byte) bool) (stopped bool) {
if t.root == nil {
return false
}
if !t.IsFastCacheEnabled() {
return t.ImmutableTree.Iterate(fn)
}
itr := NewUnsavedFastIterator(nil, nil, true, t.ndb, t.unsavedFastNodeAdditions, t.unsavedFastNodeRemovals)
for ; itr.Valid(); itr.Next() {
if fn(itr.Key(), itr.Value()) {
return true
}
}
return false
}
// Iterator returns an iterator over the mutable tree.
// CONTRACT: no updates are made to the tree while an iterator is active.
func (t *MutableTree) Iterator(start, end []byte, ascending bool) dbm.Iterator {
return NewUnsavedFastIterator(start, end, ascending, t.ndb, t.unsavedFastNodeAdditions, t.unsavedFastNodeRemovals)
}
func (tree *MutableTree) set(key []byte, value []byte) (orphans []*Node, updated bool) {
if value == nil {
panic(fmt.Sprintf("Attempt to store nil value at key '%s'", key))
}
if tree.ImmutableTree.root == nil {
tree.addUnsavedAddition(key, NewFastNode(key, value, tree.version+1))
tree.ImmutableTree.root = NewNode(key, value, tree.version+1)
return nil, updated
}
orphans = tree.prepareOrphansSlice()
tree.ImmutableTree.root, updated = tree.recursiveSet(tree.ImmutableTree.root, key, value, &orphans)
return orphans, updated
}
func (tree *MutableTree) recursiveSet(node *Node, key []byte, value []byte, orphans *[]*Node) (
newSelf *Node, updated bool,
) {
version := tree.version + 1
if node.isLeaf() {
tree.addUnsavedAddition(key, NewFastNode(key, value, version))
switch bytes.Compare(key, node.key) {
case -1:
return &Node{
key: node.key,
height: 1,
size: 2,
leftNode: NewNode(key, value, version),
rightNode: node,
version: version,
}, false
case 1:
return &Node{
key: key,
height: 1,
size: 2,
leftNode: node,
rightNode: NewNode(key, value, version),
version: version,
}, false
default:
*orphans = append(*orphans, node)
return NewNode(key, value, version), true
}
} else {
*orphans = append(*orphans, node)
node = node.clone(version)
if bytes.Compare(key, node.key) < 0 {
node.leftNode, updated = tree.recursiveSet(node.getLeftNode(tree.ImmutableTree), key, value, orphans)
node.leftHash = nil // leftHash is yet unknown
} else {
node.rightNode, updated = tree.recursiveSet(node.getRightNode(tree.ImmutableTree), key, value, orphans)
node.rightHash = nil // rightHash is yet unknown
}
if updated {
return node, updated
}
node.calcHeightAndSize(tree.ImmutableTree)
newNode := tree.balance(node, orphans)
return newNode, updated
}
}
// Remove removes a key from the working tree. The given key byte slice should not be modified
// after this call, since it may point to data stored inside IAVL.
func (tree *MutableTree) Remove(key []byte) ([]byte, bool) {
val, orphaned, removed := tree.remove(key)
tree.addOrphans(orphaned)
return val, removed
}
// remove tries to remove a key from the tree and if removed, returns its
// value, nodes orphaned and 'true'.
func (tree *MutableTree) remove(key []byte) (value []byte, orphaned []*Node, removed bool) {
if tree.root == nil {
return nil, nil, false
}
orphaned = tree.prepareOrphansSlice()
newRootHash, newRoot, _, value := tree.recursiveRemove(tree.root, key, &orphaned)
if len(orphaned) == 0 {
return nil, nil, false
}
tree.addUnsavedRemoval(key)
if newRoot == nil && newRootHash != nil {
tree.root = tree.ndb.GetNode(newRootHash)
} else {
tree.root = newRoot
}
return value, orphaned, true
}
// removes the node corresponding to the passed key and balances the tree.
// It returns:
// - the hash of the new node (or nil if the node is the one removed)
// - the node that replaces the orig. node after remove
// - new leftmost leaf key for tree after successfully removing 'key' if changed.
// - the removed value
// - the orphaned nodes.
func (tree *MutableTree) recursiveRemove(node *Node, key []byte, orphans *[]*Node) (newHash []byte, newSelf *Node, newKey []byte, newValue []byte) {
version := tree.version + 1
if node.isLeaf() {
if bytes.Equal(key, node.key) {
*orphans = append(*orphans, node)
return nil, nil, nil, node.value
}
return node.hash, node, nil, nil
}
// node.key < key; we go to the left to find the key:
if bytes.Compare(key, node.key) < 0 {
newLeftHash, newLeftNode, newKey, value := tree.recursiveRemove(node.getLeftNode(tree.ImmutableTree), key, orphans) //nolint:govet
if len(*orphans) == 0 {
return node.hash, node, nil, value
}
*orphans = append(*orphans, node)
if newLeftHash == nil && newLeftNode == nil { // left node held value, was removed
return node.rightHash, node.rightNode, node.key, value
}
newNode := node.clone(version)
newNode.leftHash, newNode.leftNode = newLeftHash, newLeftNode
newNode.calcHeightAndSize(tree.ImmutableTree)
newNode = tree.balance(newNode, orphans)
return newNode.hash, newNode, newKey, value
}
// node.key >= key; either found or look to the right:
newRightHash, newRightNode, newKey, value := tree.recursiveRemove(node.getRightNode(tree.ImmutableTree), key, orphans)
if len(*orphans) == 0 {
return node.hash, node, nil, value
}
*orphans = append(*orphans, node)
if newRightHash == nil && newRightNode == nil { // right node held value, was removed
return node.leftHash, node.leftNode, nil, value
}
newNode := node.clone(version)
newNode.rightHash, newNode.rightNode = newRightHash, newRightNode
if newKey != nil {
newNode.key = newKey
}
newNode.calcHeightAndSize(tree.ImmutableTree)
newNode = tree.balance(newNode, orphans)
return newNode.hash, newNode, nil, value
}
// Load the latest versioned tree from disk.
func (tree *MutableTree) Load() (int64, error) {
return tree.LoadVersion(int64(0))
}
// LazyLoadVersion attempts to lazy load only the specified target version
// without loading previous roots/versions. Lazy loading should be used in cases
// where only reads are expected. Any writes to a lazy loaded tree may result in
// unexpected behavior. If the targetVersion is non-positive, the latest version
// will be loaded by default. If the latest version is non-positive, this method
// performs a no-op. Otherwise, if the root does not exist, an error will be
// returned.
func (tree *MutableTree) LazyLoadVersion(targetVersion int64) (int64, error) {
latestVersion := tree.ndb.getLatestVersion()
if latestVersion < targetVersion {
return latestVersion, fmt.Errorf("wanted to load target %d but only found up to %d", targetVersion, latestVersion)
}
// no versions have been saved if the latest version is non-positive
if latestVersion <= 0 {
if targetVersion <= 0 {
tree.mtx.Lock()
defer tree.mtx.Unlock()
_, err := tree.enableFastStorageAndCommitIfNotEnabled()
return 0, err
}
return 0, fmt.Errorf("no versions found while trying to load %v", targetVersion)
}
// default to the latest version if the targeted version is non-positive
if targetVersion <= 0 {
targetVersion = latestVersion
}
rootHash, err := tree.ndb.getRoot(targetVersion)
if err != nil {
return 0, err
}
if rootHash == nil {
return latestVersion, ErrVersionDoesNotExist
}
tree.mtx.Lock()
defer tree.mtx.Unlock()
tree.versions[targetVersion] = true
iTree := &ImmutableTree{
ndb: tree.ndb,
version: targetVersion,
}
if len(rootHash) > 0 {
// If rootHash is empty then root of tree should be nil
// This makes `LazyLoadVersion` to do the same thing as `LoadVersion`
iTree.root = tree.ndb.GetNode(rootHash)
}
tree.orphans = map[string]int64{}
tree.ImmutableTree = iTree
tree.lastSaved = iTree.clone()
// Attempt to upgrade
if _, err := tree.enableFastStorageAndCommitIfNotEnabled(); err != nil {
return 0, err
}
return targetVersion, nil
}
// Returns the version number of the latest version found
func (tree *MutableTree) LoadVersion(targetVersion int64) (int64, error) {
roots, err := tree.ndb.getRoots()
if err != nil {
return 0, err
}
if len(roots) == 0 {
if targetVersion <= 0 {
tree.mtx.Lock()
defer tree.mtx.Unlock()
_, err := tree.enableFastStorageAndCommitIfNotEnabled()
return 0, err
}
return 0, fmt.Errorf("no versions found while trying to load %v", targetVersion)
}
firstVersion := int64(0)
latestVersion := int64(0)
tree.mtx.Lock()
defer tree.mtx.Unlock()
var latestRoot []byte
for version, r := range roots {
tree.versions[version] = true
if version > latestVersion && (targetVersion == 0 || version <= targetVersion) {
latestVersion = version
latestRoot = r
}
if firstVersion == 0 || version < firstVersion {
firstVersion = version
}
}
if !(targetVersion == 0 || latestVersion == targetVersion) {
return latestVersion, fmt.Errorf("wanted to load target %v but only found up to %v",
targetVersion, latestVersion)
}
if firstVersion > 0 && firstVersion < int64(tree.ndb.opts.InitialVersion) {
return latestVersion, fmt.Errorf("initial version set to %v, but found earlier version %v",
tree.ndb.opts.InitialVersion, firstVersion)
}
t := &ImmutableTree{
ndb: tree.ndb,
version: latestVersion,
}
if len(latestRoot) != 0 {
t.root = tree.ndb.GetNode(latestRoot)
}
tree.orphans = map[string]int64{}
tree.ImmutableTree = t
tree.lastSaved = t.clone()
tree.allRootLoaded = true
// Attempt to upgrade
if _, err := tree.enableFastStorageAndCommitIfNotEnabled(); err != nil {
return 0, err
}
return latestVersion, nil
}
// LoadVersionForOverwriting attempts to load a tree at a previously committed
// version, or the latest version below it. Any versions greater than targetVersion will be deleted.
func (tree *MutableTree) LoadVersionForOverwriting(targetVersion int64) (int64, error) {
latestVersion, err := tree.LoadVersion(targetVersion)
if err != nil {
return latestVersion, err
}
if err = tree.ndb.DeleteVersionsFrom(targetVersion + 1); err != nil {
return latestVersion, err
}
if err := tree.enableFastStorageAndCommitLocked(); err != nil {
return latestVersion, err
}
tree.ndb.resetLatestVersion(latestVersion)
tree.mtx.Lock()
defer tree.mtx.Unlock()
for v := range tree.versions {
if v > targetVersion {
delete(tree.versions, v)
}
}
return latestVersion, nil
}
// Returns true if the tree may be auto-upgraded, false otherwise
// An example of when an upgrade may be performed is when we are enaling fast storage for the first time or
// need to overwrite fast nodes due to mismatch with live state.
func (tree *MutableTree) IsUpgradeable() bool {
return !tree.ndb.hasUpgradedToFastStorage() || tree.ndb.shouldForceFastStorageUpgrade()
}
// enableFastStorageAndCommitIfNotEnabled if nodeDB doesn't mark fast storage as enabled, enable it, and commit the update.
// Checks whether the fast cache on disk matches latest live state. If not, deletes all existing fast nodes and repopulates them
// from latest tree.
func (tree *MutableTree) enableFastStorageAndCommitIfNotEnabled() (bool, error) {
shouldForceUpdate := tree.ndb.shouldForceFastStorageUpgrade()
isFastStorageEnabled := tree.ndb.hasUpgradedToFastStorage()
if !tree.IsUpgradeable() {
return false, nil
}
if isFastStorageEnabled && shouldForceUpdate {
// If there is a mismatch between which fast nodes are on disk and the live state due to temporary
// downgrade and subsequent re-upgrade, we cannot know for sure which fast nodes have been removed while downgraded,
// Therefore, there might exist stale fast nodes on disk. As a result, to avoid persisting the stale state, it might
// be worth to delete the fast nodes from disk.
fastItr := NewFastIterator(nil, nil, true, tree.ndb)
defer fastItr.Close()
for ; fastItr.Valid(); fastItr.Next() {
if err := tree.ndb.DeleteFastNode(fastItr.Key()); err != nil {
return false, err
}
}
}
// Force garbage collection before we proceed to enabling fast storage.
runtime.GC()
if err := tree.enableFastStorageAndCommit(); err != nil {
tree.ndb.storageVersion = defaultStorageVersionValue
return false, err
}
return true, nil
}
func (tree *MutableTree) enableFastStorageAndCommitLocked() error {
tree.mtx.Lock()
defer tree.mtx.Unlock()
return tree.enableFastStorageAndCommit()
}
func (tree *MutableTree) enableFastStorageAndCommit() error {
debug("enabling fast storage, might take a while.")
var err error
defer func() {
if err != nil {
debug("failed to enable fast storage: %v\n", err)
} else {
debug("fast storage is enabled.")
}
}()
// We start a new thread to keep on checking if we are above 4GB, and if so garbage collect.
// This thread only lasts during the fast node migration.
// This is done to keep RAM usage down.
done := make(chan struct{})
defer func() {
done <- struct{}{}
close(done)
}()
go func () {
timer := time.NewTimer(time.Second)
var m runtime.MemStats
for {
// Sample the current memory usage
runtime.ReadMemStats(&m)
if m.Alloc > 4 * 1024 * 1024 * 1024 {
// If we are using more than 4GB of memory, we should trigger garbage collection
// to free up some memory.
runtime.GC()
}
select {
case <-timer.C:
timer.Reset(time.Second)
case <-done:
if !timer.Stop() {
<-timer.C
}
return
}
}
}()
itr := NewIterator(nil, nil, true, tree.ImmutableTree)
defer itr.Close()
for ; itr.Valid(); itr.Next() {
if err = tree.ndb.SaveFastNodeNoCache(NewFastNode(itr.Key(), itr.Value(), tree.version)); err != nil {
return err
}
}
if err = itr.Error(); err != nil {
return err
}
if err = tree.ndb.setFastStorageVersionToBatch(); err != nil {
return err
}
if err = tree.ndb.Commit(); err != nil {
return err
}
return nil
}
// GetImmutable loads an ImmutableTree at a given version for querying. The returned tree is
// safe for concurrent access, provided the version is not deleted, e.g. via `DeleteVersion()`.
func (tree *MutableTree) GetImmutable(version int64) (*ImmutableTree, error) {
rootHash, err := tree.ndb.getRoot(version)
if err != nil {
return nil, err
}
if rootHash == nil {
return nil, ErrVersionDoesNotExist
}
tree.mtx.Lock()
defer tree.mtx.Unlock()
if len(rootHash) == 0 {
tree.versions[version] = true
return &ImmutableTree{
ndb: tree.ndb,
version: version,
}, nil
}
tree.versions[version] = true
return &ImmutableTree{
root: tree.ndb.GetNode(rootHash),
ndb: tree.ndb,
version: version,
}, nil
}
// Rollback resets the working tree to the latest saved version, discarding
// any unsaved modifications.
func (tree *MutableTree) Rollback() {
if tree.version > 0 {
tree.ImmutableTree = tree.lastSaved.clone()
} else {
tree.ImmutableTree = &ImmutableTree{ndb: tree.ndb, version: 0}
}
tree.orphans = map[string]int64{}
tree.unsavedFastNodeAdditions = map[string]*FastNode{}
tree.unsavedFastNodeRemovals = map[string]interface{}{}
}
// GetVersioned gets the value at the specified key and version. The returned value must not be
// modified, since it may point to data stored within IAVL.
func (tree *MutableTree) GetVersioned(key []byte, version int64) []byte {
if tree.VersionExists(version) {
if tree.IsFastCacheEnabled() {
fastNode, _ := tree.ndb.GetFastNode(key)
if fastNode == nil && version == tree.ndb.latestVersion {
return nil
}
if fastNode != nil && fastNode.versionLastUpdatedAt <= version {
return fastNode.value
}
}
t, err := tree.GetImmutable(version)
if err != nil {
return nil
}
value := t.Get(key)
return value
}
return nil
}
// SaveVersion saves a new tree version to disk, based on the current state of
// the tree. Returns the hash and new version number.
func (tree *MutableTree) SaveVersion() ([]byte, int64, error) {
version := tree.version + 1
if version == 1 && tree.ndb.opts.InitialVersion > 0 {
version = int64(tree.ndb.opts.InitialVersion)
}
if tree.VersionExists(version) {
// If the version already exists, return an error as we're attempting to overwrite.
// However, the same hash means idempotent (i.e. no-op).
existingHash, err := tree.ndb.getRoot(version)
if err != nil {
return nil, version, err
}
// If the existing root hash is empty (because the tree is empty), then we need to
// compare with the hash of an empty input which is what `WorkingHash()` returns.
if len(existingHash) == 0 {
existingHash = sha256.New().Sum(nil)
}
var newHash = tree.WorkingHash()
if bytes.Equal(existingHash, newHash) {
tree.version = version
tree.ImmutableTree = tree.ImmutableTree.clone()
tree.lastSaved = tree.ImmutableTree.clone()
tree.orphans = map[string]int64{}
return existingHash, version, nil
}
return nil, version, fmt.Errorf("version %d was already saved to different hash %X (existing hash %X)", version, newHash, existingHash)
}
if tree.root == nil {
// There can still be orphans, for example if the root is the node being
// removed.
debug("SAVE EMPTY TREE %v\n", version)
tree.ndb.SaveOrphans(version, tree.orphans)
if err := tree.ndb.SaveEmptyRoot(version); err != nil {
return nil, 0, err
}
} else {
debug("SAVE TREE %v\n", version)
tree.ndb.SaveBranch(tree.root)
tree.ndb.SaveOrphans(version, tree.orphans)
if err := tree.ndb.SaveRoot(tree.root, version); err != nil {
return nil, 0, err
}
}
if err := tree.saveFastNodeVersion(); err != nil {
return nil, version, err
}
if err := tree.ndb.Commit(); err != nil {
return nil, version, err
}
tree.mtx.Lock()
defer tree.mtx.Unlock()
tree.version = version
tree.versions[version] = true
// set new working tree
tree.ImmutableTree = tree.ImmutableTree.clone()
tree.lastSaved = tree.ImmutableTree.clone()
tree.orphans = map[string]int64{}
tree.unsavedFastNodeAdditions = make(map[string]*FastNode)
tree.unsavedFastNodeRemovals = make(map[string]interface{})
return tree.Hash(), version, nil
}
func (tree *MutableTree) saveFastNodeVersion() error {
if err := tree.saveFastNodeAdditions(); err != nil {
return err
}
if err := tree.saveFastNodeRemovals(); err != nil {
return err
}
if err := tree.ndb.setFastStorageVersionToBatch(); err != nil {
return err
}
return nil
}
func (tree *MutableTree) getUnsavedFastNodeAdditions() map[string]*FastNode {
return tree.unsavedFastNodeAdditions
}
// getUnsavedFastNodeRemovals returns unsaved FastNodes to remove
func (tree *MutableTree) getUnsavedFastNodeRemovals() map[string]interface{} {
return tree.unsavedFastNodeRemovals
}
func (tree *MutableTree) addUnsavedAddition(key []byte, node *FastNode) {
delete(tree.unsavedFastNodeRemovals, string(key))
tree.unsavedFastNodeAdditions[string(key)] = node
}
func (tree *MutableTree) saveFastNodeAdditions() error {
keysToSort := make([]string, 0, len(tree.unsavedFastNodeAdditions))
for key := range tree.unsavedFastNodeAdditions {
keysToSort = append(keysToSort, key)
}
sort.Strings(keysToSort)
for _, key := range keysToSort {
if err := tree.ndb.SaveFastNode(tree.unsavedFastNodeAdditions[key]); err != nil {
return err
}
}
return nil
}
func (tree *MutableTree) addUnsavedRemoval(key []byte) {
delete(tree.unsavedFastNodeAdditions, string(key))
tree.unsavedFastNodeRemovals[string(key)] = true
}
func (tree *MutableTree) saveFastNodeRemovals() error {
keysToSort := make([]string, 0, len(tree.unsavedFastNodeRemovals))
for key := range tree.unsavedFastNodeRemovals {
keysToSort = append(keysToSort, key)
}
sort.Strings(keysToSort)
for _, key := range keysToSort {
tree.ndb.DeleteFastNode([]byte(key))
}
return nil
}
func (tree *MutableTree) deleteVersion(version int64) error {
if version <= 0 {
return errors.New("version must be greater than 0")
}
if version == tree.version {
return errors.Errorf("cannot delete latest saved version (%d)", version)
}
if !tree.VersionExists(version) {
return errors.Wrap(ErrVersionDoesNotExist, "")
}
if err := tree.ndb.DeleteVersion(version, true); err != nil {
return err
}
return nil
}
// SetInitialVersion sets the initial version of the tree, replacing Options.InitialVersion.
// It is only used during the initial SaveVersion() call for a tree with no other versions,
// and is otherwise ignored.
func (tree *MutableTree) SetInitialVersion(version uint64) {
tree.ndb.opts.InitialVersion = version
}
// DeleteVersions deletes a series of versions from the MutableTree.
// Deprecated: please use DeleteVersionsRange instead.
func (tree *MutableTree) DeleteVersions(versions ...int64) error {
debug("DELETING VERSIONS: %v\n", versions)
if len(versions) == 0 {
return nil
}
sort.Slice(versions, func(i, j int) bool {
return versions[i] < versions[j]
})
// Find ordered data and delete by interval
intervals := map[int64]int64{}
var fromVersion int64
for _, version := range versions {
if version-fromVersion != intervals[fromVersion] {
fromVersion = version
}
intervals[fromVersion]++
}
for fromVersion, sortedBatchSize := range intervals {
if err := tree.DeleteVersionsRange(fromVersion, fromVersion+sortedBatchSize); err != nil {
return err
}
}
return nil
}
// DeleteVersionsRange removes versions from an interval from the MutableTree (not inclusive).
// An error is returned if any single version has active readers.
// All writes happen in a single batch with a single commit.
func (tree *MutableTree) DeleteVersionsRange(fromVersion, toVersion int64) error {
if err := tree.ndb.DeleteVersionsRange(fromVersion, toVersion); err != nil {
return err
}
if err := tree.ndb.Commit(); err != nil {
return err
}
tree.mtx.Lock()
defer tree.mtx.Unlock()
for version := fromVersion; version < toVersion; version++ {
delete(tree.versions, version)
}
return nil
}
// DeleteVersion deletes a tree version from disk. The version can then no
// longer be accessed.
func (tree *MutableTree) DeleteVersion(version int64) error {
debug("DELETE VERSION: %d\n", version)
if err := tree.deleteVersion(version); err != nil {
return err
}
if err := tree.ndb.Commit(); err != nil {
return err
}
tree.mtx.Lock()
defer tree.mtx.Unlock()
delete(tree.versions, version)
return nil
}
// Rotate right and return the new node and orphan.
func (tree *MutableTree) rotateRight(node *Node) (*Node, *Node) {
version := tree.version + 1
// TODO: optimize balance & rotate.
node = node.clone(version)
orphaned := node.getLeftNode(tree.ImmutableTree)
newNode := orphaned.clone(version)
newNoderHash, newNoderCached := newNode.rightHash, newNode.rightNode
newNode.rightHash, newNode.rightNode = node.hash, node
node.leftHash, node.leftNode = newNoderHash, newNoderCached
node.calcHeightAndSize(tree.ImmutableTree)
newNode.calcHeightAndSize(tree.ImmutableTree)
return newNode, orphaned
}
// Rotate left and return the new node and orphan.
func (tree *MutableTree) rotateLeft(node *Node) (*Node, *Node) {
version := tree.version + 1
// TODO: optimize balance & rotate.
node = node.clone(version)
orphaned := node.getRightNode(tree.ImmutableTree)
newNode := orphaned.clone(version)
newNodelHash, newNodelCached := newNode.leftHash, newNode.leftNode
newNode.leftHash, newNode.leftNode = node.hash, node
node.rightHash, node.rightNode = newNodelHash, newNodelCached
node.calcHeightAndSize(tree.ImmutableTree)
newNode.calcHeightAndSize(tree.ImmutableTree)
return newNode, orphaned
}
// NOTE: assumes that node can be modified
// TODO: optimize balance & rotate
func (tree *MutableTree) balance(node *Node, orphans *[]*Node) (newSelf *Node) {
if node.persisted {
panic("Unexpected balance() call on persisted node")
}
balance := node.calcBalance(tree.ImmutableTree)
if balance > 1 {
if node.getLeftNode(tree.ImmutableTree).calcBalance(tree.ImmutableTree) >= 0 {
// Left Left Case
newNode, orphaned := tree.rotateRight(node)
*orphans = append(*orphans, orphaned)
return newNode
}
// Left Right Case
var leftOrphaned *Node
left := node.getLeftNode(tree.ImmutableTree)
node.leftHash = nil
node.leftNode, leftOrphaned = tree.rotateLeft(left)
newNode, rightOrphaned := tree.rotateRight(node)
*orphans = append(*orphans, left, leftOrphaned, rightOrphaned)
return newNode
}
if balance < -1 {
if node.getRightNode(tree.ImmutableTree).calcBalance(tree.ImmutableTree) <= 0 {
// Right Right Case
newNode, orphaned := tree.rotateLeft(node)
*orphans = append(*orphans, orphaned)
return newNode
}
// Right Left Case
var rightOrphaned *Node
right := node.getRightNode(tree.ImmutableTree)
node.rightHash = nil
node.rightNode, rightOrphaned = tree.rotateRight(right)
newNode, leftOrphaned := tree.rotateLeft(node)