gitea/vendor/golang.org/x/net/html/node.go

// Copyright 2011 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.

package html

import (
	"golang.org/x/net/html/atom"
)

// A NodeType is the type of a Node.
type NodeType uint32

const (
	ErrorNode NodeType = iota
	TextNode
	DocumentNode
	ElementNode
	CommentNode
	DoctypeNode
	scopeMarkerNode
)

// Section 12.2.3.3 says "scope markers are inserted when entering applet
// elements, buttons, object elements, marquees, table cells, and table
// captions, and are used to prevent formatting from 'leaking'".
var scopeMarker = Node{Type: scopeMarkerNode}

// A Node consists of a NodeType and some Data (tag name for element nodes,
// content for text) and are part of a tree of Nodes. Element nodes may also
// have a Namespace and contain a slice of Attributes. Data is unescaped, so
// that it looks like "a<b" rather than "a&lt;b". For element nodes, DataAtom
// is the atom for Data, or zero if Data is not a known tag name.
//
// An empty Namespace implies a "http://www.w3.org/1999/xhtml" namespace.
// Similarly, "math" is short for "http://www.w3.org/1998/Math/MathML", and
// "svg" is short for "http://www.w3.org/2000/svg".
type Node struct {
	Parent, FirstChild, LastChild, PrevSibling, NextSibling *Node

	Type      NodeType
	DataAtom  atom.Atom
	Data      string
	Namespace string
	Attr      []Attribute
}

// InsertBefore inserts newChild as a child of n, immediately before oldChild
// in the sequence of n's children. oldChild may be nil, in which case newChild
// is appended to the end of n's children.
//
// It will panic if newChild already has a parent or siblings.
func (n *Node) InsertBefore(newChild, oldChild *Node) {
	if newChild.Parent != nil || newChild.PrevSibling != nil || newChild.NextSibling != nil {
		panic("html: InsertBefore called for an attached child Node")
	}
	var prev, next *Node
	if oldChild != nil {
		prev, next = oldChild.PrevSibling, oldChild
	} else {
		prev = n.LastChild
	}
	if prev != nil {
		prev.NextSibling = newChild
	} else {
		n.FirstChild = newChild
	}
	if next != nil {
		next.PrevSibling = newChild
	} else {
		n.LastChild = newChild
	}
	newChild.Parent = n
	newChild.PrevSibling = prev
	newChild.NextSibling = next
}

// AppendChild adds a node c as a child of n.
//
// It will panic if c already has a parent or siblings.
func (n *Node) AppendChild(c *Node) {
	if c.Parent != nil || c.PrevSibling != nil || c.NextSibling != nil {
		panic("html: AppendChild called for an attached child Node")
	}
	last := n.LastChild
	if last != nil {
		last.NextSibling = c
	} else {
		n.FirstChild = c
	}
	n.LastChild = c
	c.Parent = n
	c.PrevSibling = last
}

// RemoveChild removes a node c that is a child of n. Afterwards, c will have
// no parent and no siblings.
//
// It will panic if c's parent is not n.
func (n *Node) RemoveChild(c *Node) {
	if c.Parent != n {
		panic("html: RemoveChild called for a non-child Node")
	}
	if n.FirstChild == c {
		n.FirstChild = c.NextSibling
	}
	if c.NextSibling != nil {
		c.NextSibling.PrevSibling = c.PrevSibling
	}
	if n.LastChild == c {
		n.LastChild = c.PrevSibling
	}
	if c.PrevSibling != nil {
		c.PrevSibling.NextSibling = c.NextSibling
	}
	c.Parent = nil
	c.PrevSibling = nil
	c.NextSibling = nil
}

// reparentChildren reparents all of src's child nodes to dst.
func reparentChildren(dst, src *Node) {
	for {
		child := src.FirstChild
		if child == nil {
			break
		}
		src.RemoveChild(child)
		dst.AppendChild(child)
	}
}

// clone returns a new node with the same type, data and attributes.
// The clone has no parent, no siblings and no children.
func (n *Node) clone() *Node {
	m := &Node{
		Type:     n.Type,
		DataAtom: n.DataAtom,
		Data:     n.Data,
		Attr:     make([]Attribute, len(n.Attr)),
	}
	copy(m.Attr, n.Attr)
	return m
}

// nodeStack is a stack of nodes.
type nodeStack []*Node

// pop pops the stack. It will panic if s is empty.
func (s *nodeStack) pop() *Node {
	i := len(*s)
	n := (*s)[i-1]
	*s = (*s)[:i-1]
	return n
}

// top returns the most recently pushed node, or nil if s is empty.
func (s *nodeStack) top() *Node {
	if i := len(*s); i > 0 {
		return (*s)[i-1]
	}
	return nil
}

// index returns the index of the top-most occurrence of n in the stack, or -1
// if n is not present.
func (s *nodeStack) index(n *Node) int {
	for i := len(*s) - 1; i >= 0; i-- {
		if (*s)[i] == n {
			return i
		}
	}
	return -1
}

// insert inserts a node at the given index.
func (s *nodeStack) insert(i int, n *Node) {
	(*s) = append(*s, nil)
	copy((*s)[i+1:], (*s)[i:])
	(*s)[i] = n
}

// remove removes a node from the stack. It is a no-op if n is not present.
func (s *nodeStack) remove(n *Node) {
	i := s.index(n)
	if i == -1 {
		return
	}
	copy((*s)[i:], (*s)[i+1:])
	j := len(*s) - 1
	(*s)[j] = nil
	*s = (*s)[:j]
}
Added all required dependencies 8 years ago			`// Copyright 2011 The Go Authors. All rights reserved.`
			`// Use of this source code is governed by a BSD-style`
			`// license that can be found in the LICENSE file.`

			`package html`

			`import (`
			`"golang.org/x/net/html/atom"`
			`)`

			`// A NodeType is the type of a Node.`
			`type NodeType uint32`

			`const (`
			`ErrorNode NodeType = iota`
			`TextNode`
			`DocumentNode`
			`ElementNode`
			`CommentNode`
			`DoctypeNode`
			`scopeMarkerNode`
			`)`

			`// Section 12.2.3.3 says "scope markers are inserted when entering applet`
			`// elements, buttons, object elements, marquees, table cells, and table`
			`// captions, and are used to prevent formatting from 'leaking'".`
			`var scopeMarker = Node{Type: scopeMarkerNode}`

			`// A Node consists of a NodeType and some Data (tag name for element nodes,`
			`// content for text) and are part of a tree of Nodes. Element nodes may also`
			`// have a Namespace and contain a slice of Attributes. Data is unescaped, so`
			`// that it looks like "a<b" rather than "a<b". For element nodes, DataAtom`
			`// is the atom for Data, or zero if Data is not a known tag name.`
			`//`
			`// An empty Namespace implies a "http://www.w3.org/1999/xhtml" namespace.`
			`// Similarly, "math" is short for "http://www.w3.org/1998/Math/MathML", and`
			`// "svg" is short for "http://www.w3.org/2000/svg".`
			`type Node struct {`
			`Parent, FirstChild, LastChild, PrevSibling, NextSibling *Node`

			`Type NodeType`
			`DataAtom atom.Atom`
			`Data string`
			`Namespace string`
			`Attr []Attribute`
			`}`

			`// InsertBefore inserts newChild as a child of n, immediately before oldChild`
			`// in the sequence of n's children. oldChild may be nil, in which case newChild`
			`// is appended to the end of n's children.`
			`//`
			`// It will panic if newChild already has a parent or siblings.`
			`func (n Node) InsertBefore(newChild, oldChild Node) {`
			`if newChild.Parent != nil \|\| newChild.PrevSibling != nil \|\| newChild.NextSibling != nil {`
			`panic("html: InsertBefore called for an attached child Node")`
			`}`
			`var prev, next *Node`
			`if oldChild != nil {`
			`prev, next = oldChild.PrevSibling, oldChild`
			`} else {`
			`prev = n.LastChild`
			`}`
			`if prev != nil {`
			`prev.NextSibling = newChild`
			`} else {`
			`n.FirstChild = newChild`
			`}`
			`if next != nil {`
			`next.PrevSibling = newChild`
			`} else {`
			`n.LastChild = newChild`
			`}`
			`newChild.Parent = n`
			`newChild.PrevSibling = prev`
			`newChild.NextSibling = next`
			`}`

			`// AppendChild adds a node c as a child of n.`
			`//`
			`// It will panic if c already has a parent or siblings.`
			`func (n Node) AppendChild(c Node) {`
			`if c.Parent != nil \|\| c.PrevSibling != nil \|\| c.NextSibling != nil {`
			`panic("html: AppendChild called for an attached child Node")`
			`}`
			`last := n.LastChild`
			`if last != nil {`
			`last.NextSibling = c`
			`} else {`
			`n.FirstChild = c`
			`}`
			`n.LastChild = c`
			`c.Parent = n`
			`c.PrevSibling = last`
			`}`

			`// RemoveChild removes a node c that is a child of n. Afterwards, c will have`
			`// no parent and no siblings.`
			`//`
			`// It will panic if c's parent is not n.`
			`func (n Node) RemoveChild(c Node) {`
			`if c.Parent != n {`
			`panic("html: RemoveChild called for a non-child Node")`
			`}`
			`if n.FirstChild == c {`
			`n.FirstChild = c.NextSibling`
			`}`
			`if c.NextSibling != nil {`
			`c.NextSibling.PrevSibling = c.PrevSibling`
			`}`
			`if n.LastChild == c {`
			`n.LastChild = c.PrevSibling`
			`}`
			`if c.PrevSibling != nil {`
			`c.PrevSibling.NextSibling = c.NextSibling`
			`}`
			`c.Parent = nil`
			`c.PrevSibling = nil`
			`c.NextSibling = nil`
			`}`

			`// reparentChildren reparents all of src's child nodes to dst.`
			`func reparentChildren(dst, src *Node) {`
			`for {`
			`child := src.FirstChild`
			`if child == nil {`
			`break`
			`}`
			`src.RemoveChild(child)`
			`dst.AppendChild(child)`
			`}`
			`}`

			`// clone returns a new node with the same type, data and attributes.`
			`// The clone has no parent, no siblings and no children.`
			`func (n Node) clone() Node {`
			`m := &Node{`
			`Type: n.Type,`
			`DataAtom: n.DataAtom,`
			`Data: n.Data,`
			`Attr: make([]Attribute, len(n.Attr)),`
			`}`
			`copy(m.Attr, n.Attr)`
			`return m`
			`}`

			`// nodeStack is a stack of nodes.`
			`type nodeStack []*Node`

			`// pop pops the stack. It will panic if s is empty.`
			`func (s nodeStack) pop() Node {`
			`i := len(*s)`
			`n := (*s)[i-1]`
			`s = (s)[:i-1]`
			`return n`
			`}`

			`// top returns the most recently pushed node, or nil if s is empty.`
			`func (s nodeStack) top() Node {`
			`if i := len(*s); i > 0 {`
			`return (*s)[i-1]`
			`}`
			`return nil`
			`}`

			`// index returns the index of the top-most occurrence of n in the stack, or -1`
			`// if n is not present.`
			`func (s nodeStack) index(n Node) int {`
			`for i := len(*s) - 1; i >= 0; i-- {`
			`if (*s)[i] == n {`
			`return i`
			`}`
			`}`
			`return -1`
			`}`

			`// insert inserts a node at the given index.`
			`func (s nodeStack) insert(i int, n Node) {`
			`(s) = append(s, nil)`
			`copy((s)[i+1:], (s)[i:])`
			`(*s)[i] = n`
			`}`

			`// remove removes a node from the stack. It is a no-op if n is not present.`
			`func (s nodeStack) remove(n Node) {`
			`i := s.index(n)`
			`if i == -1 {`
			`return`
			`}`
			`copy((s)[i:], (s)[i+1:])`
			`j := len(*s) - 1`
			`(*s)[j] = nil`
			`s = (s)[:j]`
			`}`