moby--moby/vendor/github.com/armon/go-radix/radix.go

package radix

import (
	"sort"
	"strings"
)

// WalkFn is used when walking the tree. Takes a
// key and value, returning if iteration should
// be terminated.
type WalkFn func(s string, v interface{}) bool

// leafNode is used to represent a value
type leafNode struct {
	key string
	val interface{}
}

// edge is used to represent an edge node
type edge struct {
	label byte
	node  *node
}

type node struct {
	// leaf is used to store possible leaf
	leaf *leafNode

	// prefix is the common prefix we ignore
	prefix string

	// Edges should be stored in-order for iteration.
	// We avoid a fully materialized slice to save memory,
	// since in most cases we expect to be sparse
	edges edges
}

func (n *node) isLeaf() bool {
	return n.leaf != nil
}

func (n *node) addEdge(e edge) {
	n.edges = append(n.edges, e)
	n.edges.Sort()
}

func (n *node) replaceEdge(e edge) {
	num := len(n.edges)
	idx := sort.Search(num, func(i int) bool {
		return n.edges[i].label >= e.label
	})
	if idx < num && n.edges[idx].label == e.label {
		n.edges[idx].node = e.node
		return
	}
	panic("replacing missing edge")
}

func (n *node) getEdge(label byte) *node {
	num := len(n.edges)
	idx := sort.Search(num, func(i int) bool {
		return n.edges[i].label >= label
	})
	if idx < num && n.edges[idx].label == label {
		return n.edges[idx].node
	}
	return nil
}

type edges []edge

func (e edges) Len() int {
	return len(e)
}

func (e edges) Less(i, j int) bool {
	return e[i].label < e[j].label
}

func (e edges) Swap(i, j int) {
	e[i], e[j] = e[j], e[i]
}

func (e edges) Sort() {
	sort.Sort(e)
}

// Tree implements a radix tree. This can be treated as a
// Dictionary abstract data type. The main advantage over
// a standard hash map is prefix-based lookups and
// ordered iteration,
type Tree struct {
	root *node
	size int
}

// New returns an empty Tree
func New() *Tree {
	return NewFromMap(nil)
}

// NewFromMap returns a new tree containing the keys
// from an existing map
func NewFromMap(m map[string]interface{}) *Tree {
	t := &Tree{root: &node{}}
	for k, v := range m {
		t.Insert(k, v)
	}
	return t
}

// Len is used to return the number of elements in the tree
func (t *Tree) Len() int {
	return t.size
}

// longestPrefix finds the length of the shared prefix
// of two strings
func longestPrefix(k1, k2 string) int {
	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
}

// Insert is used to add a newentry or update
// an existing entry. Returns if updated.
func (t *Tree) Insert(s string, v interface{}) (interface{}, bool) {
	var parent *node
	n := t.root
	search := s
	for {
		// Handle key exhaution
		if len(search) == 0 {
			if n.isLeaf() {
				old := n.leaf.val
				n.leaf.val = v
				return old, true
			} else {
				n.leaf = &leafNode{
					key: s,
					val: v,
				}
				t.size++
				return nil, false
			}
		}

		// Look for the edge
		parent = n
		n = n.getEdge(search[0])

		// No edge, create one
		if n == nil {
			e := edge{
				label: search[0],
				node: &node{
					leaf: &leafNode{
						key: s,
						val: v,
					},
					prefix: search,
				},
			}
			parent.addEdge(e)
			t.size++
			return nil, false
		}

		// Determine longest prefix of the search key on match
		commonPrefix := longestPrefix(search, n.prefix)
		if commonPrefix == len(n.prefix) {
			search = search[commonPrefix:]
			continue
		}

		// Split the node
		t.size++
		child := &node{
			prefix: search[:commonPrefix],
		}
		parent.replaceEdge(edge{
			label: search[0],
			node:  child,
		})

		// Restore the existing node
		child.addEdge(edge{
			label: n.prefix[commonPrefix],
			node:  n,
		})
		n.prefix = n.prefix[commonPrefix:]

		// Create a new leaf node
		leaf := &leafNode{
			key: s,
			val: v,
		}

		// If the new key is a subset, add to to this node
		search = search[commonPrefix:]
		if len(search) == 0 {
			child.leaf = leaf
			return nil, false
		}

		// Create a new edge for the node
		child.addEdge(edge{
			label: search[0],
			node: &node{
				leaf:   leaf,
				prefix: search,
			},
		})
		return nil, false
	}
	return nil, false
}

// Delete is used to delete a key, returning the previous
// value and if it was deleted
func (t *Tree) Delete(s string) (interface{}, bool) {
	n := t.root
	search := s
	for {
		// Check for key exhaution
		if len(search) == 0 {
			if !n.isLeaf() {
				break
			}
			goto DELETE
		}

		// Look for an edge
		n = n.getEdge(search[0])
		if n == nil {
			break
		}

		// Consume the search prefix
		if strings.HasPrefix(search, n.prefix) {
			search = search[len(n.prefix):]
		} else {
			break
		}
	}
	return nil, false

DELETE:
	// Delete the leaf
	leaf := n.leaf
	n.leaf = nil
	t.size--

	// Check if we should merge this node
	if len(n.edges) == 1 {
		e := n.edges[0]
		child := e.node
		n.prefix = n.prefix + child.prefix
		n.leaf = child.leaf
		n.edges = child.edges
	}
	return leaf.val, true
}

// Get is used to lookup a specific key, returning
// the value and if it was found
func (t *Tree) Get(s string) (interface{}, bool) {
	n := t.root
	search := s
	for {
		// Check for key exhaution
		if len(search) == 0 {
			if n.isLeaf() {
				return n.leaf.val, true
			}
			break
		}

		// Look for an edge
		n = n.getEdge(search[0])
		if n == nil {
			break
		}

		// Consume the search prefix
		if strings.HasPrefix(search, n.prefix) {
			search = search[len(n.prefix):]
		} else {
			break
		}
	}
	return nil, false
}

// LongestPrefix is like Get, but instead of an
// exact match, it will return the longest prefix match.
func (t *Tree) LongestPrefix(s string) (string, interface{}, bool) {
	var last *leafNode
	n := t.root
	search := s
	for {
		// Look for a leaf node
		if n.isLeaf() {
			last = n.leaf
		}

		// Check for key exhaution
		if len(search) == 0 {
			break
		}

		// Look for an edge
		n = n.getEdge(search[0])
		if n == nil {
			break
		}

		// Consume the search prefix
		if strings.HasPrefix(search, n.prefix) {
			search = search[len(n.prefix):]
		} else {
			break
		}
	}
	if last != nil {
		return last.key, last.val, true
	}
	return "", nil, false
}

// Minimum is used to return the minimum value in the tree
func (t *Tree) Minimum() (string, interface{}, bool) {
	n := t.root
	for {
		if n.isLeaf() {
			return n.leaf.key, n.leaf.val, true
		}
		if len(n.edges) > 0 {
			n = n.edges[0].node
		} else {
			break
		}
	}
	return "", nil, false
}

// Maximum is used to return the maximum value in the tree
func (t *Tree) Maximum() (string, interface{}, bool) {
	n := t.root
	for {
		if num := len(n.edges); num > 0 {
			n = n.edges[num-1].node
			continue
		}
		if n.isLeaf() {
			return n.leaf.key, n.leaf.val, true
		} else {
			break
		}
	}
	return "", nil, false
}

// Walk is used to walk the tree
func (t *Tree) Walk(fn WalkFn) {
	recursiveWalk(t.root, fn)
}

// WalkPrefix is used to walk the tree under a prefix
func (t *Tree) WalkPrefix(prefix string, fn WalkFn) {
	n := t.root
	search := prefix
	for {
		// Check for key exhaution
		if len(search) == 0 {
			recursiveWalk(n, fn)
			return
		}

		// Look for an edge
		n = n.getEdge(search[0])
		if n == nil {
			break
		}

		// Consume the search prefix
		if strings.HasPrefix(search, n.prefix) {
			search = search[len(n.prefix):]

		} else if strings.HasPrefix(n.prefix, search) {
			// Child may be under our search prefix
			recursiveWalk(n, fn)
			return
		} else {
			break
		}
	}

}

// WalkPath is used to walk the tree, but only visiting nodes
// from the root down to a given leaf. Where WalkPrefix walks
// all the entries *under* the given prefix, this walks the
// entries *above* the given prefix.
func (t *Tree) WalkPath(path string, fn WalkFn) {
	n := t.root
	search := path
	for {
		// Visit the leaf values if any
		if n.leaf != nil && fn(n.leaf.key, n.leaf.val) {
			return
		}

		// Check for key exhaution
		if len(search) == 0 {
			return
		}

		// Look for an edge
		n = n.getEdge(search[0])
		if n == nil {
			return
		}

		// Consume the search prefix
		if strings.HasPrefix(search, n.prefix) {
			search = search[len(n.prefix):]
		} else {
			break
		}
	}
}

// recursiveWalk is used to do a pre-order walk of a node
// recursively. Returns true if the walk should be aborted
func recursiveWalk(n *node, fn WalkFn) bool {
	// Visit the leaf values if any
	if n.leaf != nil && fn(n.leaf.key, n.leaf.val) {
		return true
	}

	// Recurse on the children
	for _, e := range n.edges {
		if recursiveWalk(e.node, fn) {
			return true
		}
	}
	return false
}

// ToMap is used to walk the tree and convert it into a map
func (t *Tree) ToMap() map[string]interface{} {
	out := make(map[string]interface{}, t.size)
	t.Walk(func(k string, v interface{}) bool {
		out[k] = v
		return false
	})
	return out
}
Update libnetwork dependencies for b66c038 Signed-off-by: Alessandro Boch <aboch@docker.com> 2016-05-08 03:31:30 -04:00			`package radix`

			`import (`
			`"sort"`
			`"strings"`
			`)`

			`// WalkFn is used when walking the tree. Takes a`
			`// key and value, returning if iteration should`
			`// be terminated.`
			`type WalkFn func(s string, v interface{}) bool`

			`// leafNode is used to represent a value`
			`type leafNode struct {`
			`key string`
			`val interface{}`
			`}`

			`// edge is used to represent an edge node`
			`type edge struct {`
			`label byte`
			`node *node`
			`}`

			`type node struct {`
			`// leaf is used to store possible leaf`
			`leaf *leafNode`

			`// prefix is the common prefix we ignore`
			`prefix string`

			`// Edges should be stored in-order for iteration.`
			`// We avoid a fully materialized slice to save memory,`
			`// since in most cases we expect to be sparse`
			`edges edges`
			`}`

			`func (n *node) isLeaf() bool {`
			`return n.leaf != nil`
			`}`

			`func (n *node) addEdge(e edge) {`
			`n.edges = append(n.edges, e)`
			`n.edges.Sort()`
			`}`

			`func (n *node) replaceEdge(e edge) {`
			`num := len(n.edges)`
			`idx := sort.Search(num, func(i int) bool {`
			`return n.edges[i].label >= e.label`
			`})`
			`if idx < num && n.edges[idx].label == e.label {`
			`n.edges[idx].node = e.node`
			`return`
			`}`
			`panic("replacing missing edge")`
			`}`

			`func (n node) getEdge(label byte) node {`
			`num := len(n.edges)`
			`idx := sort.Search(num, func(i int) bool {`
			`return n.edges[i].label >= label`
			`})`
			`if idx < num && n.edges[idx].label == label {`
			`return n.edges[idx].node`
			`}`
			`return nil`
			`}`

			`type edges []edge`

			`func (e edges) Len() int {`
			`return len(e)`
			`}`

			`func (e edges) Less(i, j int) bool {`
			`return e[i].label < e[j].label`
			`}`

			`func (e edges) Swap(i, j int) {`
			`e[i], e[j] = e[j], e[i]`
			`}`

			`func (e edges) Sort() {`
			`sort.Sort(e)`
			`}`

			`// Tree implements a radix tree. This can be treated as a`
			`// Dictionary abstract data type. The main advantage over`
			`// a standard hash map is prefix-based lookups and`
			`// ordered iteration,`
			`type Tree struct {`
			`root *node`
			`size int`
			`}`

			`// New returns an empty Tree`
			`func New() *Tree {`
			`return NewFromMap(nil)`
			`}`

			`// NewFromMap returns a new tree containing the keys`
			`// from an existing map`
			`func NewFromMap(m map[string]interface{}) *Tree {`
			`t := &Tree{root: &node{}}`
			`for k, v := range m {`
			`t.Insert(k, v)`
			`}`
			`return t`
			`}`

			`// Len is used to return the number of elements in the tree`
			`func (t *Tree) Len() int {`
			`return t.size`
			`}`

			`// longestPrefix finds the length of the shared prefix`
			`// of two strings`
			`func longestPrefix(k1, k2 string) int {`
			`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`
			`}`

			`// Insert is used to add a newentry or update`
			`// an existing entry. Returns if updated.`
			`func (t *Tree) Insert(s string, v interface{}) (interface{}, bool) {`
			`var parent *node`
			`n := t.root`
			`search := s`
			`for {`
			`// Handle key exhaution`
			`if len(search) == 0 {`
			`if n.isLeaf() {`
			`old := n.leaf.val`
			`n.leaf.val = v`
			`return old, true`
			`} else {`
			`n.leaf = &leafNode{`
			`key: s,`
			`val: v,`
			`}`
			`t.size++`
			`return nil, false`
			`}`
			`}`

			`// Look for the edge`
			`parent = n`
			`n = n.getEdge(search[0])`

			`// No edge, create one`
			`if n == nil {`
			`e := edge{`
			`label: search[0],`
			`node: &node{`
			`leaf: &leafNode{`
			`key: s,`
			`val: v,`
			`},`
			`prefix: search,`
			`},`
			`}`
			`parent.addEdge(e)`
			`t.size++`
			`return nil, false`
			`}`

			`// Determine longest prefix of the search key on match`
			`commonPrefix := longestPrefix(search, n.prefix)`
			`if commonPrefix == len(n.prefix) {`
			`search = search[commonPrefix:]`
			`continue`
			`}`

			`// Split the node`
			`t.size++`
			`child := &node{`
			`prefix: search[:commonPrefix],`
			`}`
			`parent.replaceEdge(edge{`
			`label: search[0],`
			`node: child,`
			`})`

			`// Restore the existing node`
			`child.addEdge(edge{`
			`label: n.prefix[commonPrefix],`
			`node: n,`
			`})`
			`n.prefix = n.prefix[commonPrefix:]`

			`// Create a new leaf node`
			`leaf := &leafNode{`
			`key: s,`
			`val: v,`
			`}`

			`// If the new key is a subset, add to to this node`
			`search = search[commonPrefix:]`
			`if len(search) == 0 {`
			`child.leaf = leaf`
			`return nil, false`
			`}`

			`// Create a new edge for the node`
			`child.addEdge(edge{`
			`label: search[0],`
			`node: &node{`
			`leaf: leaf,`
			`prefix: search,`
			`},`
			`})`
			`return nil, false`
			`}`
			`return nil, false`
			`}`

			`// Delete is used to delete a key, returning the previous`
			`// value and if it was deleted`
			`func (t *Tree) Delete(s string) (interface{}, bool) {`
			`n := t.root`
			`search := s`
			`for {`
			`// Check for key exhaution`
			`if len(search) == 0 {`
			`if !n.isLeaf() {`
			`break`
			`}`
			`goto DELETE`
			`}`

			`// Look for an edge`
			`n = n.getEdge(search[0])`
			`if n == nil {`
			`break`
			`}`

			`// Consume the search prefix`
			`if strings.HasPrefix(search, n.prefix) {`
			`search = search[len(n.prefix):]`
			`} else {`
			`break`
			`}`
			`}`
			`return nil, false`

			`DELETE:`
			`// Delete the leaf`
			`leaf := n.leaf`
			`n.leaf = nil`
			`t.size--`

			`// Check if we should merge this node`
			`if len(n.edges) == 1 {`
			`e := n.edges[0]`
			`child := e.node`
			`n.prefix = n.prefix + child.prefix`
			`n.leaf = child.leaf`
			`n.edges = child.edges`
			`}`
			`return leaf.val, true`
			`}`

			`// Get is used to lookup a specific key, returning`
			`// the value and if it was found`
			`func (t *Tree) Get(s string) (interface{}, bool) {`
			`n := t.root`
			`search := s`
			`for {`
			`// Check for key exhaution`
			`if len(search) == 0 {`
			`if n.isLeaf() {`
			`return n.leaf.val, true`
			`}`
			`break`
			`}`

			`// Look for an edge`
			`n = n.getEdge(search[0])`
			`if n == nil {`
			`break`
			`}`

			`// Consume the search prefix`
			`if strings.HasPrefix(search, n.prefix) {`
			`search = search[len(n.prefix):]`
			`} else {`
			`break`
			`}`
			`}`
			`return nil, false`
			`}`

			`// LongestPrefix is like Get, but instead of an`
			`// exact match, it will return the longest prefix match.`
			`func (t *Tree) LongestPrefix(s string) (string, interface{}, bool) {`
			`var last *leafNode`
			`n := t.root`
			`search := s`
			`for {`
			`// Look for a leaf node`
			`if n.isLeaf() {`
			`last = n.leaf`
			`}`

			`// Check for key exhaution`
			`if len(search) == 0 {`
			`break`
			`}`

			`// Look for an edge`
			`n = n.getEdge(search[0])`
			`if n == nil {`
			`break`
			`}`

			`// Consume the search prefix`
			`if strings.HasPrefix(search, n.prefix) {`
			`search = search[len(n.prefix):]`
			`} else {`
			`break`
			`}`
			`}`
			`if last != nil {`
			`return last.key, last.val, true`
			`}`
			`return "", nil, false`
			`}`

			`// Minimum is used to return the minimum value in the tree`
			`func (t *Tree) Minimum() (string, interface{}, bool) {`
			`n := t.root`
			`for {`
			`if n.isLeaf() {`
			`return n.leaf.key, n.leaf.val, true`
			`}`
			`if len(n.edges) > 0 {`
			`n = n.edges[0].node`
			`} else {`
			`break`
			`}`
			`}`
			`return "", nil, false`
			`}`

			`// Maximum is used to return the maximum value in the tree`
			`func (t *Tree) Maximum() (string, interface{}, bool) {`
			`n := t.root`
			`for {`
			`if num := len(n.edges); num > 0 {`
			`n = n.edges[num-1].node`
			`continue`
			`}`
			`if n.isLeaf() {`
			`return n.leaf.key, n.leaf.val, true`
			`} else {`
			`break`
			`}`
			`}`
			`return "", nil, false`
			`}`

			`// Walk is used to walk the tree`
			`func (t *Tree) Walk(fn WalkFn) {`
			`recursiveWalk(t.root, fn)`
			`}`

			`// WalkPrefix is used to walk the tree under a prefix`
			`func (t *Tree) WalkPrefix(prefix string, fn WalkFn) {`
			`n := t.root`
			`search := prefix`
			`for {`
			`// Check for key exhaution`
			`if len(search) == 0 {`
			`recursiveWalk(n, fn)`
			`return`
			`}`

			`// Look for an edge`
			`n = n.getEdge(search[0])`
			`if n == nil {`
			`break`
			`}`

			`// Consume the search prefix`
			`if strings.HasPrefix(search, n.prefix) {`
			`search = search[len(n.prefix):]`

			`} else if strings.HasPrefix(n.prefix, search) {`
			`// Child may be under our search prefix`
			`recursiveWalk(n, fn)`
			`return`
			`} else {`
			`break`
			`}`
			`}`

			`}`

			`// WalkPath is used to walk the tree, but only visiting nodes`
			`// from the root down to a given leaf. Where WalkPrefix walks`
			`// all the entries under the given prefix, this walks the`
			`// entries above the given prefix.`
			`func (t *Tree) WalkPath(path string, fn WalkFn) {`
			`n := t.root`
			`search := path`
			`for {`
			`// Visit the leaf values if any`
			`if n.leaf != nil && fn(n.leaf.key, n.leaf.val) {`
			`return`
			`}`

			`// Check for key exhaution`
			`if len(search) == 0 {`
			`return`
			`}`

			`// Look for an edge`
			`n = n.getEdge(search[0])`
			`if n == nil {`
			`return`
			`}`

			`// Consume the search prefix`
			`if strings.HasPrefix(search, n.prefix) {`
			`search = search[len(n.prefix):]`
			`} else {`
			`break`
			`}`
			`}`
			`}`

			`// recursiveWalk is used to do a pre-order walk of a node`
			`// recursively. Returns true if the walk should be aborted`
			`func recursiveWalk(n *node, fn WalkFn) bool {`
			`// Visit the leaf values if any`
			`if n.leaf != nil && fn(n.leaf.key, n.leaf.val) {`
			`return true`
			`}`

			`// Recurse on the children`
			`for _, e := range n.edges {`
			`if recursiveWalk(e.node, fn) {`
			`return true`
			`}`
			`}`
			`return false`
			`}`

			`// ToMap is used to walk the tree and convert it into a map`
			`func (t *Tree) ToMap() map[string]interface{} {`
			`out := make(map[string]interface{}, t.size)`
			`t.Walk(func(k string, v interface{}) bool {`
			`out[k] = v`
			`return false`
			`})`
			`return out`
			`}`