562 lines
15 KiB
Go
562 lines
15 KiB
Go
package iradix
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import (
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"bytes"
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"strings"
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"github.com/hashicorp/golang-lru/simplelru"
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)
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const (
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// defaultModifiedCache is the default size of the modified node
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// cache used per transaction. This is used to cache the updates
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// to the nodes near the root, while the leaves do not need to be
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// cached. This is important for very large transactions to prevent
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// the modified cache from growing to be enormous. This is also used
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// to set the max size of the mutation notify maps since those should
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// also be bounded in a similar way.
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defaultModifiedCache = 8192
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)
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// Tree implements an immutable radix tree. This can be treated as a
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// Dictionary abstract data type. The main advantage over a standard
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// hash map is prefix-based lookups and ordered iteration. The immutability
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// means that it is safe to concurrently read from a Tree without any
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// coordination.
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type Tree struct {
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root *Node
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size int
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}
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// New returns an empty Tree
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func New() *Tree {
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t := &Tree{
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root: &Node{
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mutateCh: make(chan struct{}),
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},
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}
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return t
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}
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// Len is used to return the number of elements in the tree
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func (t *Tree) Len() int {
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return t.size
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}
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// Txn is a transaction on the tree. This transaction is applied
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// atomically and returns a new tree when committed. A transaction
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// is not thread safe, and should only be used by a single goroutine.
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type Txn struct {
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// root is the modified root for the transaction.
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root *Node
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// snap is a snapshot of the root node for use if we have to run the
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// slow notify algorithm.
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snap *Node
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// size tracks the size of the tree as it is modified during the
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// transaction.
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size int
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// writable is a cache of writable nodes that have been created during
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// the course of the transaction. This allows us to re-use the same
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// nodes for further writes and avoid unnecessary copies of nodes that
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// have never been exposed outside the transaction. This will only hold
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// up to defaultModifiedCache number of entries.
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writable *simplelru.LRU
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// trackChannels is used to hold channels that need to be notified to
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// signal mutation of the tree. This will only hold up to
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// defaultModifiedCache number of entries, after which we will set the
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// trackOverflow flag, which will cause us to use a more expensive
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// algorithm to perform the notifications. Mutation tracking is only
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// performed if trackMutate is true.
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trackChannels map[chan struct{}]struct{}
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trackOverflow bool
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trackMutate bool
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}
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// Txn starts a new transaction that can be used to mutate the tree
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func (t *Tree) Txn() *Txn {
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txn := &Txn{
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root: t.root,
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snap: t.root,
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size: t.size,
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}
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return txn
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}
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// TrackMutate can be used to toggle if mutations are tracked. If this is enabled
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// then notifications will be issued for affected internal nodes and leaves when
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// the transaction is committed.
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func (t *Txn) TrackMutate(track bool) {
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t.trackMutate = track
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}
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// trackChannel safely attempts to track the given mutation channel, setting the
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// overflow flag if we can no longer track any more. This limits the amount of
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// state that will accumulate during a transaction and we have a slower algorithm
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// to switch to if we overflow.
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func (t *Txn) trackChannel(ch chan struct{}) {
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// In overflow, make sure we don't store any more objects.
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if t.trackOverflow {
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return
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}
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// If this would overflow the state we reject it and set the flag (since
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// we aren't tracking everything that's required any longer).
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if len(t.trackChannels) >= defaultModifiedCache {
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// Mark that we are in the overflow state
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t.trackOverflow = true
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// Clear the map so that the channels can be garbage collected. It is
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// safe to do this since we have already overflowed and will be using
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// the slow notify algorithm.
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t.trackChannels = nil
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return
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}
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// Create the map on the fly when we need it.
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if t.trackChannels == nil {
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t.trackChannels = make(map[chan struct{}]struct{})
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}
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// Otherwise we are good to track it.
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t.trackChannels[ch] = struct{}{}
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}
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// writeNode returns a node to be modified, if the current node has already been
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// modified during the course of the transaction, it is used in-place. Set
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// forLeafUpdate to true if you are getting a write node to update the leaf,
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// which will set leaf mutation tracking appropriately as well.
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func (t *Txn) writeNode(n *Node, forLeafUpdate bool) *Node {
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// Ensure the writable set exists.
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if t.writable == nil {
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lru, err := simplelru.NewLRU(defaultModifiedCache, nil)
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if err != nil {
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panic(err)
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}
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t.writable = lru
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}
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// If this node has already been modified, we can continue to use it
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// during this transaction. We know that we don't need to track it for
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// a node update since the node is writable, but if this is for a leaf
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// update we track it, in case the initial write to this node didn't
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// update the leaf.
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if _, ok := t.writable.Get(n); ok {
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if t.trackMutate && forLeafUpdate && n.leaf != nil {
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t.trackChannel(n.leaf.mutateCh)
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}
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return n
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}
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// Mark this node as being mutated.
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if t.trackMutate {
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t.trackChannel(n.mutateCh)
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}
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// Mark its leaf as being mutated, if appropriate.
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if t.trackMutate && forLeafUpdate && n.leaf != nil {
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t.trackChannel(n.leaf.mutateCh)
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}
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// Copy the existing node. If you have set forLeafUpdate it will be
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// safe to replace this leaf with another after you get your node for
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// writing. You MUST replace it, because the channel associated with
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// this leaf will be closed when this transaction is committed.
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nc := &Node{
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mutateCh: make(chan struct{}),
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leaf: n.leaf,
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}
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if n.prefix != nil {
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nc.prefix = make([]byte, len(n.prefix))
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copy(nc.prefix, n.prefix)
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}
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if len(n.edges) != 0 {
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nc.edges = make([]edge, len(n.edges))
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copy(nc.edges, n.edges)
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}
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// Mark this node as writable.
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t.writable.Add(nc, nil)
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return nc
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}
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// mergeChild is called to collapse the given node with its child. This is only
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// called when the given node is not a leaf and has a single edge.
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func (t *Txn) mergeChild(n *Node) {
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// Mark the child node as being mutated since we are about to abandon
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// it. We don't need to mark the leaf since we are retaining it if it
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// is there.
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e := n.edges[0]
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child := e.node
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if t.trackMutate {
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t.trackChannel(child.mutateCh)
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}
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// Merge the nodes.
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n.prefix = concat(n.prefix, child.prefix)
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n.leaf = child.leaf
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if len(child.edges) != 0 {
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n.edges = make([]edge, len(child.edges))
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copy(n.edges, child.edges)
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} else {
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n.edges = nil
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}
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}
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// insert does a recursive insertion
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func (t *Txn) insert(n *Node, k, search []byte, v interface{}) (*Node, interface{}, bool) {
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// Handle key exhaustion
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if len(search) == 0 {
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var oldVal interface{}
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didUpdate := false
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if n.isLeaf() {
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oldVal = n.leaf.val
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didUpdate = true
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}
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nc := t.writeNode(n, true)
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nc.leaf = &leafNode{
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mutateCh: make(chan struct{}),
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key: k,
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val: v,
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}
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return nc, oldVal, didUpdate
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}
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// Look for the edge
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idx, child := n.getEdge(search[0])
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// No edge, create one
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if child == nil {
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e := edge{
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label: search[0],
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node: &Node{
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mutateCh: make(chan struct{}),
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leaf: &leafNode{
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mutateCh: make(chan struct{}),
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key: k,
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val: v,
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},
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prefix: search,
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},
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}
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nc := t.writeNode(n, false)
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nc.addEdge(e)
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return nc, nil, false
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}
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// Determine longest prefix of the search key on match
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commonPrefix := longestPrefix(search, child.prefix)
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if commonPrefix == len(child.prefix) {
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search = search[commonPrefix:]
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newChild, oldVal, didUpdate := t.insert(child, k, search, v)
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if newChild != nil {
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nc := t.writeNode(n, false)
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nc.edges[idx].node = newChild
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return nc, oldVal, didUpdate
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}
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return nil, oldVal, didUpdate
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}
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// Split the node
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nc := t.writeNode(n, false)
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splitNode := &Node{
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mutateCh: make(chan struct{}),
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prefix: search[:commonPrefix],
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}
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nc.replaceEdge(edge{
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label: search[0],
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node: splitNode,
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})
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// Restore the existing child node
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modChild := t.writeNode(child, false)
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splitNode.addEdge(edge{
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label: modChild.prefix[commonPrefix],
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node: modChild,
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})
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modChild.prefix = modChild.prefix[commonPrefix:]
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// Create a new leaf node
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leaf := &leafNode{
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mutateCh: make(chan struct{}),
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key: k,
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val: v,
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}
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// If the new key is a subset, add to to this node
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search = search[commonPrefix:]
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if len(search) == 0 {
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splitNode.leaf = leaf
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return nc, nil, false
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}
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// Create a new edge for the node
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splitNode.addEdge(edge{
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label: search[0],
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node: &Node{
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mutateCh: make(chan struct{}),
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leaf: leaf,
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prefix: search,
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},
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})
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return nc, nil, false
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}
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// delete does a recursive deletion
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func (t *Txn) delete(parent, n *Node, search []byte) (*Node, *leafNode) {
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// Check for key exhaustion
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if len(search) == 0 {
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if !n.isLeaf() {
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return nil, nil
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}
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// Remove the leaf node
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nc := t.writeNode(n, true)
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nc.leaf = nil
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// Check if this node should be merged
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if n != t.root && len(nc.edges) == 1 {
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t.mergeChild(nc)
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}
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return nc, n.leaf
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}
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// Look for an edge
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label := search[0]
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idx, child := n.getEdge(label)
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if child == nil || !bytes.HasPrefix(search, child.prefix) {
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return nil, nil
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}
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// Consume the search prefix
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search = search[len(child.prefix):]
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newChild, leaf := t.delete(n, child, search)
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if newChild == nil {
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return nil, nil
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}
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// Copy this node. WATCH OUT - it's safe to pass "false" here because we
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// will only ADD a leaf via nc.mergeChild() if there isn't one due to
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// the !nc.isLeaf() check in the logic just below. This is pretty subtle,
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// so be careful if you change any of the logic here.
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nc := t.writeNode(n, false)
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// Delete the edge if the node has no edges
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if newChild.leaf == nil && len(newChild.edges) == 0 {
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nc.delEdge(label)
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if n != t.root && len(nc.edges) == 1 && !nc.isLeaf() {
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t.mergeChild(nc)
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}
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} else {
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nc.edges[idx].node = newChild
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}
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return nc, leaf
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}
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// Insert is used to add or update a given key. The return provides
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// the previous value and a bool indicating if any was set.
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func (t *Txn) Insert(k []byte, v interface{}) (interface{}, bool) {
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newRoot, oldVal, didUpdate := t.insert(t.root, k, k, v)
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if newRoot != nil {
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t.root = newRoot
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}
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if !didUpdate {
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t.size++
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}
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return oldVal, didUpdate
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}
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// Delete is used to delete a given key. Returns the old value if any,
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// and a bool indicating if the key was set.
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func (t *Txn) Delete(k []byte) (interface{}, bool) {
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newRoot, leaf := t.delete(nil, t.root, k)
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if newRoot != nil {
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t.root = newRoot
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}
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if leaf != nil {
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t.size--
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return leaf.val, true
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}
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return nil, false
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}
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// Root returns the current root of the radix tree within this
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// transaction. The root is not safe across insert and delete operations,
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// but can be used to read the current state during a transaction.
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func (t *Txn) Root() *Node {
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return t.root
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}
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// Get is used to lookup a specific key, returning
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// the value and if it was found
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func (t *Txn) Get(k []byte) (interface{}, bool) {
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return t.root.Get(k)
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}
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// GetWatch is used to lookup a specific key, returning
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// the watch channel, value and if it was found
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func (t *Txn) GetWatch(k []byte) (<-chan struct{}, interface{}, bool) {
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return t.root.GetWatch(k)
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}
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// Commit is used to finalize the transaction and return a new tree. If mutation
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// tracking is turned on then notifications will also be issued.
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func (t *Txn) Commit() *Tree {
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nt := t.CommitOnly()
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if t.trackMutate {
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t.Notify()
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}
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return nt
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}
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// CommitOnly is used to finalize the transaction and return a new tree, but
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// does not issue any notifications until Notify is called.
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func (t *Txn) CommitOnly() *Tree {
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nt := &Tree{t.root, t.size}
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t.writable = nil
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return nt
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}
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// slowNotify does a complete comparison of the before and after trees in order
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// to trigger notifications. This doesn't require any additional state but it
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// is very expensive to compute.
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func (t *Txn) slowNotify() {
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snapIter := t.snap.rawIterator()
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rootIter := t.root.rawIterator()
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for snapIter.Front() != nil || rootIter.Front() != nil {
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// If we've exhausted the nodes in the old snapshot, we know
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// there's nothing remaining to notify.
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if snapIter.Front() == nil {
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return
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}
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snapElem := snapIter.Front()
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// If we've exhausted the nodes in the new root, we know we need
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// to invalidate everything that remains in the old snapshot. We
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// know from the loop condition there's something in the old
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// snapshot.
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if rootIter.Front() == nil {
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close(snapElem.mutateCh)
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if snapElem.isLeaf() {
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close(snapElem.leaf.mutateCh)
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}
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snapIter.Next()
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continue
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}
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// Do one string compare so we can check the various conditions
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// below without repeating the compare.
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cmp := strings.Compare(snapIter.Path(), rootIter.Path())
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// If the snapshot is behind the root, then we must have deleted
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// this node during the transaction.
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if cmp < 0 {
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close(snapElem.mutateCh)
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if snapElem.isLeaf() {
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close(snapElem.leaf.mutateCh)
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}
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snapIter.Next()
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continue
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}
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// If the snapshot is ahead of the root, then we must have added
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// this node during the transaction.
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if cmp > 0 {
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rootIter.Next()
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continue
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}
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// If we have the same path, then we need to see if we mutated a
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// node and possibly the leaf.
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rootElem := rootIter.Front()
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if snapElem != rootElem {
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close(snapElem.mutateCh)
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if snapElem.leaf != nil && (snapElem.leaf != rootElem.leaf) {
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close(snapElem.leaf.mutateCh)
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}
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}
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snapIter.Next()
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rootIter.Next()
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}
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}
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// Notify is used along with TrackMutate to trigger notifications. This must
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// only be done once a transaction is committed via CommitOnly, and it is called
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// automatically by Commit.
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func (t *Txn) Notify() {
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if !t.trackMutate {
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return
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}
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// If we've overflowed the tracking state we can't use it in any way and
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// need to do a full tree compare.
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if t.trackOverflow {
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t.slowNotify()
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} else {
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for ch := range t.trackChannels {
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close(ch)
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}
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}
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// Clean up the tracking state so that a re-notify is safe (will trigger
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// the else clause above which will be a no-op).
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t.trackChannels = nil
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t.trackOverflow = false
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}
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// Insert is used to add or update a given key. The return provides
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// the new tree, previous value and a bool indicating if any was set.
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func (t *Tree) Insert(k []byte, v interface{}) (*Tree, interface{}, bool) {
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txn := t.Txn()
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old, ok := txn.Insert(k, v)
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return txn.Commit(), old, ok
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}
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// Delete is used to delete a given key. Returns the new tree,
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// old value if any, and a bool indicating if the key was set.
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func (t *Tree) Delete(k []byte) (*Tree, interface{}, bool) {
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txn := t.Txn()
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old, ok := txn.Delete(k)
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return txn.Commit(), old, ok
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}
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// Root returns the root node of the tree which can be used for richer
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// query operations.
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func (t *Tree) Root() *Node {
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return t.root
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}
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// Get is used to lookup a specific key, returning
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// the value and if it was found
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func (t *Tree) Get(k []byte) (interface{}, bool) {
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return t.root.Get(k)
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}
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// longestPrefix finds the length of the shared prefix
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// of two strings
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func longestPrefix(k1, k2 []byte) int {
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max := len(k1)
|
|
if l := len(k2); l < max {
|
|
max = l
|
|
}
|
|
var i int
|
|
for i = 0; i < max; i++ {
|
|
if k1[i] != k2[i] {
|
|
break
|
|
}
|
|
}
|
|
return i
|
|
}
|
|
|
|
// concat two byte slices, returning a third new copy
|
|
func concat(a, b []byte) []byte {
|
|
c := make([]byte, len(a)+len(b))
|
|
copy(c, a)
|
|
copy(c[len(a):], b)
|
|
return c
|
|
}
|