campaigner/vendor/github.com/trivago/tgo/tcontainer/trie.go

// Copyright 2015-2018 trivago N.V.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
//     http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.

package tcontainer

// TrieNode represents a single node inside a trie.
// Each node can contain a payload which can be retrieved after a successfull
// match. In addition to that PathLen will contain the length of the match.
type TrieNode struct {
	suffix      []byte
	children    []*TrieNode
	longestPath int
	PathLen     int
	Payload     interface{}
}

// NewTrie creates a new root TrieNode
func NewTrie(data []byte, payload interface{}) *TrieNode {
	return &TrieNode{
		suffix:      data,
		children:    []*TrieNode{},
		longestPath: len(data),
		PathLen:     len(data),
		Payload:     payload,
	}
}

func (node *TrieNode) addNewChild(data []byte, payload interface{}, pathLen int) {
	if node.longestPath < pathLen {
		node.longestPath = pathLen
	}

	idx := len(node.children)
	node.children = append(node.children, nil)

	for idx > 0 {
		nextIdx := idx - 1
		if node.children[nextIdx].longestPath > pathLen {
			break
		}
		node.children[idx] = node.children[nextIdx]
		idx = nextIdx
	}

	node.children[idx] = &TrieNode{
		suffix:      data,
		children:    []*TrieNode{},
		longestPath: pathLen,
		PathLen:     pathLen,
		Payload:     payload,
	}
}

func (node *TrieNode) replace(oldChild *TrieNode, newChild *TrieNode) {
	for i, child := range node.children {
		if child == oldChild {
			node.children[i] = newChild
			return // ### return, replaced ###
		}
	}
}

// ForEach applies a function to each node in the tree including and below the
// passed node.
func (node *TrieNode) ForEach(callback func(*TrieNode)) {
	callback(node)
	for _, child := range node.children {
		child.ForEach(callback)
	}
}

// Add adds a new data path to the trie.
// The TrieNode returned is the (new) root node so you should always reassign
// the root with the return value of Add.
func (node *TrieNode) Add(data []byte, payload interface{}) *TrieNode {
	return node.addPath(data, payload, len(data), nil)
}

func (node *TrieNode) addPath(data []byte, payload interface{}, pathLen int, parent *TrieNode) *TrieNode {
	dataLen := len(data)
	suffixLen := len(node.suffix)
	testLen := suffixLen
	if dataLen < suffixLen {
		testLen = dataLen
	}

	var splitIdx int
	for splitIdx = 0; splitIdx < testLen; splitIdx++ {
		if data[splitIdx] != node.suffix[splitIdx] {
			break // ### break, split found ###
		}
	}

	if splitIdx == suffixLen {
		// Continue down or stop here (full suffix match)

		if splitIdx == dataLen {
			node.Payload = payload // may overwrite
			return node            // ### return, path already stored ###
		}

		data = data[splitIdx:]
		if suffixLen > 0 {
			for _, child := range node.children {
				if child.suffix[0] == data[0] {
					child.addPath(data, payload, pathLen, node)
					return node // ### return, continue on path ###
				}
			}
		}

		node.addNewChild(data, payload, pathLen)
		return node // ### return, new leaf ###
	}

	if splitIdx == dataLen {
		// Make current node a subpath of new data node (full data match)
		// This case implies that dataLen < suffixLen as splitIdx == suffixLen
		// did not match.

		node.suffix = node.suffix[splitIdx:]

		newParent := NewTrie(data, payload)
		newParent.PathLen = pathLen
		newParent.longestPath = node.longestPath
		newParent.children = []*TrieNode{node}

		if parent != nil {
			parent.replace(node, newParent)
		}
		return newParent // ### return, rotation ###
	}

	// New parent required with both nodes as children (partial match)

	node.suffix = node.suffix[splitIdx:]

	newParent := NewTrie(data[:splitIdx], nil)
	newParent.PathLen = 0
	newParent.longestPath = node.longestPath
	newParent.children = []*TrieNode{node}
	newParent.addNewChild(data[splitIdx:], payload, pathLen)

	if parent != nil {
		parent.replace(node, newParent)
	}
	return newParent // ### return, new parent ###
}

// Match compares the trie to the given data stream.
// Match returns true if data can be completely matched to the trie.
func (node *TrieNode) Match(data []byte) *TrieNode {
	dataLen := len(data)
	suffixLen := len(node.suffix)
	if dataLen < suffixLen {
		return nil // ### return, cannot be fully matched ###
	}

	for i := 0; i < suffixLen; i++ {
		if data[i] != node.suffix[i] {
			return nil // ### return, no match ###
		}
	}

	if dataLen == suffixLen {
		if node.PathLen > 0 {
			return node // ### return, full match ###
		}
		return nil // ### return, invalid match ###
	}

	data = data[suffixLen:]
	numChildren := len(node.children)
	for i := 0; i < numChildren; i++ {
		matchedNode := node.children[i].Match(data)
		if matchedNode != nil {
			return matchedNode // ### return, match found ###
		}
	}

	return nil // ### return, no valid path ###
}

// MatchStart compares the trie to the beginning of the given data stream.
// MatchStart returns true if the beginning of data can be matched to the trie.
func (node *TrieNode) MatchStart(data []byte) *TrieNode {
	dataLen := len(data)
	suffixLen := len(node.suffix)
	if dataLen < suffixLen {
		return nil // ### return, cannot be fully matched ###
	}

	for i := 0; i < suffixLen; i++ {
		if data[i] != node.suffix[i] {
			return nil // ### return, no match ###
		}
	}

	// Match longest path first

	data = data[suffixLen:]
	numChildren := len(node.children)
	for i := 0; i < numChildren; i++ {
		matchedNode := node.children[i].MatchStart(data)
		if matchedNode != nil {
			return matchedNode // ### return, match found ###
		}
	}

	// May be only a part of data but we have a valid match

	if node.PathLen > 0 {
		return node // ### return, full match ###
	}
	return nil // ### return, no valid path ###
}
Replace direct usage of the API with go-jira 2020-03-04 22:13:55 +01:00			`// Copyright 2015-2018 trivago N.V.`
			`//`
			`// Licensed under the Apache License, Version 2.0 (the "License");`
			`// you may not use this file except in compliance with the License.`
			`// You may obtain a copy of the License at`
			`//`
			`// http://www.apache.org/licenses/LICENSE-2.0`
			`//`
			`// Unless required by applicable law or agreed to in writing, software`
			`// distributed under the License is distributed on an "AS IS" BASIS,`
			`// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.`
			`// See the License for the specific language governing permissions and`
			`// limitations under the License.`

			`package tcontainer`

			`// TrieNode represents a single node inside a trie.`
			`// Each node can contain a payload which can be retrieved after a successfull`
			`// match. In addition to that PathLen will contain the length of the match.`
			`type TrieNode struct {`
			`suffix []byte`
			`children []*TrieNode`
			`longestPath int`
			`PathLen int`
			`Payload interface{}`
			`}`

			`// NewTrie creates a new root TrieNode`
			`func NewTrie(data []byte, payload interface{}) *TrieNode {`
			`return &TrieNode{`
			`suffix: data,`
			`children: []*TrieNode{},`
			`longestPath: len(data),`
			`PathLen: len(data),`
			`Payload: payload,`
			`}`
			`}`

			`func (node *TrieNode) addNewChild(data []byte, payload interface{}, pathLen int) {`
			`if node.longestPath < pathLen {`
			`node.longestPath = pathLen`
			`}`

			`idx := len(node.children)`
			`node.children = append(node.children, nil)`

			`for idx > 0 {`
			`nextIdx := idx - 1`
			`if node.children[nextIdx].longestPath > pathLen {`
			`break`
			`}`
			`node.children[idx] = node.children[nextIdx]`
			`idx = nextIdx`
			`}`

			`node.children[idx] = &TrieNode{`
			`suffix: data,`
			`children: []*TrieNode{},`
			`longestPath: pathLen,`
			`PathLen: pathLen,`
			`Payload: payload,`
			`}`
			`}`

			`func (node TrieNode) replace(oldChild TrieNode, newChild *TrieNode) {`
			`for i, child := range node.children {`
			`if child == oldChild {`
			`node.children[i] = newChild`
			`return // ### return, replaced ###`
			`}`
			`}`
			`}`

			`// ForEach applies a function to each node in the tree including and below the`
			`// passed node.`
			`func (node TrieNode) ForEach(callback func(TrieNode)) {`
			`callback(node)`
			`for _, child := range node.children {`
			`child.ForEach(callback)`
			`}`
			`}`

			`// Add adds a new data path to the trie.`
			`// The TrieNode returned is the (new) root node so you should always reassign`
			`// the root with the return value of Add.`
			`func (node TrieNode) Add(data []byte, payload interface{}) TrieNode {`
			`return node.addPath(data, payload, len(data), nil)`
			`}`

			`func (node TrieNode) addPath(data []byte, payload interface{}, pathLen int, parent TrieNode) *TrieNode {`
			`dataLen := len(data)`
			`suffixLen := len(node.suffix)`
			`testLen := suffixLen`
			`if dataLen < suffixLen {`
			`testLen = dataLen`
			`}`

			`var splitIdx int`
			`for splitIdx = 0; splitIdx < testLen; splitIdx++ {`
			`if data[splitIdx] != node.suffix[splitIdx] {`
			`break // ### break, split found ###`
			`}`
			`}`

			`if splitIdx == suffixLen {`
			`// Continue down or stop here (full suffix match)`

			`if splitIdx == dataLen {`
			`node.Payload = payload // may overwrite`
			`return node // ### return, path already stored ###`
			`}`

			`data = data[splitIdx:]`
			`if suffixLen > 0 {`
			`for _, child := range node.children {`
			`if child.suffix[0] == data[0] {`
			`child.addPath(data, payload, pathLen, node)`
			`return node // ### return, continue on path ###`
			`}`
			`}`
			`}`

			`node.addNewChild(data, payload, pathLen)`
			`return node // ### return, new leaf ###`
			`}`

			`if splitIdx == dataLen {`
			`// Make current node a subpath of new data node (full data match)`
			`// This case implies that dataLen < suffixLen as splitIdx == suffixLen`
			`// did not match.`

			`node.suffix = node.suffix[splitIdx:]`

			`newParent := NewTrie(data, payload)`
			`newParent.PathLen = pathLen`
			`newParent.longestPath = node.longestPath`
			`newParent.children = []*TrieNode{node}`

			`if parent != nil {`
			`parent.replace(node, newParent)`
			`}`
			`return newParent // ### return, rotation ###`
			`}`

			`// New parent required with both nodes as children (partial match)`

			`node.suffix = node.suffix[splitIdx:]`

			`newParent := NewTrie(data[:splitIdx], nil)`
			`newParent.PathLen = 0`
			`newParent.longestPath = node.longestPath`
			`newParent.children = []*TrieNode{node}`
			`newParent.addNewChild(data[splitIdx:], payload, pathLen)`

			`if parent != nil {`
			`parent.replace(node, newParent)`
			`}`
			`return newParent // ### return, new parent ###`
			`}`

			`// Match compares the trie to the given data stream.`
			`// Match returns true if data can be completely matched to the trie.`
			`func (node TrieNode) Match(data []byte) TrieNode {`
			`dataLen := len(data)`
			`suffixLen := len(node.suffix)`
			`if dataLen < suffixLen {`
			`return nil // ### return, cannot be fully matched ###`
			`}`

			`for i := 0; i < suffixLen; i++ {`
			`if data[i] != node.suffix[i] {`
			`return nil // ### return, no match ###`
			`}`
			`}`

			`if dataLen == suffixLen {`
			`if node.PathLen > 0 {`
			`return node // ### return, full match ###`
			`}`
			`return nil // ### return, invalid match ###`
			`}`

			`data = data[suffixLen:]`
			`numChildren := len(node.children)`
			`for i := 0; i < numChildren; i++ {`
			`matchedNode := node.children[i].Match(data)`
			`if matchedNode != nil {`
			`return matchedNode // ### return, match found ###`
			`}`
			`}`

			`return nil // ### return, no valid path ###`
			`}`

			`// MatchStart compares the trie to the beginning of the given data stream.`
			`// MatchStart returns true if the beginning of data can be matched to the trie.`
			`func (node TrieNode) MatchStart(data []byte) TrieNode {`
			`dataLen := len(data)`
			`suffixLen := len(node.suffix)`
			`if dataLen < suffixLen {`
			`return nil // ### return, cannot be fully matched ###`
			`}`

			`for i := 0; i < suffixLen; i++ {`
			`if data[i] != node.suffix[i] {`
			`return nil // ### return, no match ###`
			`}`
			`}`

			`// Match longest path first`

			`data = data[suffixLen:]`
			`numChildren := len(node.children)`
			`for i := 0; i < numChildren; i++ {`
			`matchedNode := node.children[i].MatchStart(data)`
			`if matchedNode != nil {`
			`return matchedNode // ### return, match found ###`
			`}`
			`}`

			`// May be only a part of data but we have a valid match`

			`if node.PathLen > 0 {`
			`return node // ### return, full match ###`
			`}`
			`return nil // ### return, no valid path ###`
			`}`