189 lines
4.1 KiB
Go
189 lines
4.1 KiB
Go
package iradix
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import (
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"bytes"
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)
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// Iterator is used to iterate over a set of nodes
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// in pre-order
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type Iterator struct {
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node *Node
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stack []edges
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}
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// SeekPrefixWatch is used to seek the iterator to a given prefix
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// and returns the watch channel of the finest granularity
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func (i *Iterator) SeekPrefixWatch(prefix []byte) (watch <-chan struct{}) {
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// Wipe the stack
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i.stack = nil
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n := i.node
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watch = n.mutateCh
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search := prefix
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for {
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// Check for key exhaution
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if len(search) == 0 {
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i.node = n
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return
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}
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// Look for an edge
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_, n = n.getEdge(search[0])
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if n == nil {
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i.node = nil
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return
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}
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// Update to the finest granularity as the search makes progress
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watch = n.mutateCh
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// Consume the search prefix
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if bytes.HasPrefix(search, n.prefix) {
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search = search[len(n.prefix):]
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} else if bytes.HasPrefix(n.prefix, search) {
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i.node = n
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return
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} else {
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i.node = nil
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return
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}
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}
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}
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// SeekPrefix is used to seek the iterator to a given prefix
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func (i *Iterator) SeekPrefix(prefix []byte) {
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i.SeekPrefixWatch(prefix)
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}
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func (i *Iterator) recurseMin(n *Node) *Node {
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// Traverse to the minimum child
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if n.leaf != nil {
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return n
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}
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if len(n.edges) > 0 {
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// Add all the other edges to the stack (the min node will be added as
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// we recurse)
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i.stack = append(i.stack, n.edges[1:])
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return i.recurseMin(n.edges[0].node)
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}
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// Shouldn't be possible
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return nil
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}
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// SeekLowerBound is used to seek the iterator to the smallest key that is
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// greater or equal to the given key. There is no watch variant as it's hard to
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// predict based on the radix structure which node(s) changes might affect the
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// result.
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func (i *Iterator) SeekLowerBound(key []byte) {
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// Wipe the stack. Unlike Prefix iteration, we need to build the stack as we
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// go because we need only a subset of edges of many nodes in the path to the
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// leaf with the lower bound.
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i.stack = []edges{}
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n := i.node
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search := key
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found := func(n *Node) {
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i.node = n
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i.stack = append(i.stack, edges{edge{node: n}})
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}
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for {
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// Compare current prefix with the search key's same-length prefix.
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var prefixCmp int
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if len(n.prefix) < len(search) {
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prefixCmp = bytes.Compare(n.prefix, search[0:len(n.prefix)])
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} else {
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prefixCmp = bytes.Compare(n.prefix, search)
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}
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if prefixCmp > 0 {
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// Prefix is larger, that means the lower bound is greater than the search
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// and from now on we need to follow the minimum path to the smallest
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// leaf under this subtree.
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n = i.recurseMin(n)
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if n != nil {
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found(n)
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}
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return
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}
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if prefixCmp < 0 {
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// Prefix is smaller than search prefix, that means there is no lower
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// bound
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i.node = nil
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return
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}
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// Prefix is equal, we are still heading for an exact match. If this is a
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// leaf we're done.
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if n.leaf != nil {
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if bytes.Compare(n.leaf.key, key) < 0 {
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i.node = nil
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return
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}
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found(n)
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return
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}
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// Consume the search prefix
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if len(n.prefix) > len(search) {
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search = []byte{}
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} else {
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search = search[len(n.prefix):]
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}
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// Otherwise, take the lower bound next edge.
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idx, lbNode := n.getLowerBoundEdge(search[0])
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if lbNode == nil {
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i.node = nil
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return
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}
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// Create stack edges for the all strictly higher edges in this node.
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if idx+1 < len(n.edges) {
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i.stack = append(i.stack, n.edges[idx+1:])
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}
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i.node = lbNode
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// Recurse
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n = lbNode
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}
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}
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// Next returns the next node in order
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func (i *Iterator) Next() ([]byte, interface{}, bool) {
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// Initialize our stack if needed
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if i.stack == nil && i.node != nil {
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i.stack = []edges{
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{
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edge{node: i.node},
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},
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}
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}
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for len(i.stack) > 0 {
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// Inspect the last element of the stack
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n := len(i.stack)
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last := i.stack[n-1]
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elem := last[0].node
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// Update the stack
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if len(last) > 1 {
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i.stack[n-1] = last[1:]
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} else {
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i.stack = i.stack[:n-1]
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}
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// Push the edges onto the frontier
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if len(elem.edges) > 0 {
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i.stack = append(i.stack, elem.edges)
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}
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// Return the leaf values if any
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if elem.leaf != nil {
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return elem.leaf.key, elem.leaf.val, true
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}
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}
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return nil, nil, false
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}
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