go-ethereum/vendor/golang.org/x/net/html/token.go
Péter Szilágyi 289b30715d Godeps, vendor: convert dependency management to trash (#3198)
This commit converts the dependency management from Godeps to the vendor
folder, also switching the tool from godep to trash. Since the upstream tool
lacks a few features proposed via a few PRs, until those PRs are merged in
(if), use github.com/karalabe/trash.

You can update dependencies via trash --update.

All dependencies have been updated to their latest version.

Parts of the build system are reworked to drop old notions of Godeps and
invocation of the go vet command so that it doesn't run against the vendor
folder, as that will just blow up during vetting.

The conversion drops OpenCL (and hence GPU mining support) from ethash and our
codebase. The short reasoning is that there's noone to maintain and having
opencl libs in our deps messes up builds as go install ./... tries to build
them, failing with unsatisfied link errors for the C OpenCL deps.

golang.org/x/net/context is not vendored in. We expect it to be fetched by the
user (i.e. using go get). To keep ci.go builds reproducible the package is
"vendored" in build/_vendor.
2016-10-28 19:05:01 +02:00

1220 lines
30 KiB
Go

// Copyright 2010 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 (
"bytes"
"errors"
"io"
"strconv"
"strings"
"golang.org/x/net/html/atom"
)
// A TokenType is the type of a Token.
type TokenType uint32
const (
// ErrorToken means that an error occurred during tokenization.
ErrorToken TokenType = iota
// TextToken means a text node.
TextToken
// A StartTagToken looks like <a>.
StartTagToken
// An EndTagToken looks like </a>.
EndTagToken
// A SelfClosingTagToken tag looks like <br/>.
SelfClosingTagToken
// A CommentToken looks like <!--x-->.
CommentToken
// A DoctypeToken looks like <!DOCTYPE x>
DoctypeToken
)
// ErrBufferExceeded means that the buffering limit was exceeded.
var ErrBufferExceeded = errors.New("max buffer exceeded")
// String returns a string representation of the TokenType.
func (t TokenType) String() string {
switch t {
case ErrorToken:
return "Error"
case TextToken:
return "Text"
case StartTagToken:
return "StartTag"
case EndTagToken:
return "EndTag"
case SelfClosingTagToken:
return "SelfClosingTag"
case CommentToken:
return "Comment"
case DoctypeToken:
return "Doctype"
}
return "Invalid(" + strconv.Itoa(int(t)) + ")"
}
// An Attribute is an attribute namespace-key-value triple. Namespace is
// non-empty for foreign attributes like xlink, Key is alphabetic (and hence
// does not contain escapable characters like '&', '<' or '>'), and Val is
// unescaped (it looks like "a<b" rather than "a&lt;b").
//
// Namespace is only used by the parser, not the tokenizer.
type Attribute struct {
Namespace, Key, Val string
}
// A Token consists of a TokenType and some Data (tag name for start and end
// tags, content for text, comments and doctypes). A tag Token may also contain
// a slice of Attributes. Data is unescaped for all Tokens (it looks like "a<b"
// rather than "a&lt;b"). For tag Tokens, DataAtom is the atom for Data, or
// zero if Data is not a known tag name.
type Token struct {
Type TokenType
DataAtom atom.Atom
Data string
Attr []Attribute
}
// tagString returns a string representation of a tag Token's Data and Attr.
func (t Token) tagString() string {
if len(t.Attr) == 0 {
return t.Data
}
buf := bytes.NewBufferString(t.Data)
for _, a := range t.Attr {
buf.WriteByte(' ')
buf.WriteString(a.Key)
buf.WriteString(`="`)
escape(buf, a.Val)
buf.WriteByte('"')
}
return buf.String()
}
// String returns a string representation of the Token.
func (t Token) String() string {
switch t.Type {
case ErrorToken:
return ""
case TextToken:
return EscapeString(t.Data)
case StartTagToken:
return "<" + t.tagString() + ">"
case EndTagToken:
return "</" + t.tagString() + ">"
case SelfClosingTagToken:
return "<" + t.tagString() + "/>"
case CommentToken:
return "<!--" + t.Data + "-->"
case DoctypeToken:
return "<!DOCTYPE " + t.Data + ">"
}
return "Invalid(" + strconv.Itoa(int(t.Type)) + ")"
}
// span is a range of bytes in a Tokenizer's buffer. The start is inclusive,
// the end is exclusive.
type span struct {
start, end int
}
// A Tokenizer returns a stream of HTML Tokens.
type Tokenizer struct {
// r is the source of the HTML text.
r io.Reader
// tt is the TokenType of the current token.
tt TokenType
// err is the first error encountered during tokenization. It is possible
// for tt != Error && err != nil to hold: this means that Next returned a
// valid token but the subsequent Next call will return an error token.
// For example, if the HTML text input was just "plain", then the first
// Next call would set z.err to io.EOF but return a TextToken, and all
// subsequent Next calls would return an ErrorToken.
// err is never reset. Once it becomes non-nil, it stays non-nil.
err error
// readErr is the error returned by the io.Reader r. It is separate from
// err because it is valid for an io.Reader to return (n int, err1 error)
// such that n > 0 && err1 != nil, and callers should always process the
// n > 0 bytes before considering the error err1.
readErr error
// buf[raw.start:raw.end] holds the raw bytes of the current token.
// buf[raw.end:] is buffered input that will yield future tokens.
raw span
buf []byte
// maxBuf limits the data buffered in buf. A value of 0 means unlimited.
maxBuf int
// buf[data.start:data.end] holds the raw bytes of the current token's data:
// a text token's text, a tag token's tag name, etc.
data span
// pendingAttr is the attribute key and value currently being tokenized.
// When complete, pendingAttr is pushed onto attr. nAttrReturned is
// incremented on each call to TagAttr.
pendingAttr [2]span
attr [][2]span
nAttrReturned int
// rawTag is the "script" in "</script>" that closes the next token. If
// non-empty, the subsequent call to Next will return a raw or RCDATA text
// token: one that treats "<p>" as text instead of an element.
// rawTag's contents are lower-cased.
rawTag string
// textIsRaw is whether the current text token's data is not escaped.
textIsRaw bool
// convertNUL is whether NUL bytes in the current token's data should
// be converted into \ufffd replacement characters.
convertNUL bool
// allowCDATA is whether CDATA sections are allowed in the current context.
allowCDATA bool
}
// AllowCDATA sets whether or not the tokenizer recognizes <![CDATA[foo]]> as
// the text "foo". The default value is false, which means to recognize it as
// a bogus comment "<!-- [CDATA[foo]] -->" instead.
//
// Strictly speaking, an HTML5 compliant tokenizer should allow CDATA if and
// only if tokenizing foreign content, such as MathML and SVG. However,
// tracking foreign-contentness is difficult to do purely in the tokenizer,
// as opposed to the parser, due to HTML integration points: an <svg> element
// can contain a <foreignObject> that is foreign-to-SVG but not foreign-to-
// HTML. For strict compliance with the HTML5 tokenization algorithm, it is the
// responsibility of the user of a tokenizer to call AllowCDATA as appropriate.
// In practice, if using the tokenizer without caring whether MathML or SVG
// CDATA is text or comments, such as tokenizing HTML to find all the anchor
// text, it is acceptable to ignore this responsibility.
func (z *Tokenizer) AllowCDATA(allowCDATA bool) {
z.allowCDATA = allowCDATA
}
// NextIsNotRawText instructs the tokenizer that the next token should not be
// considered as 'raw text'. Some elements, such as script and title elements,
// normally require the next token after the opening tag to be 'raw text' that
// has no child elements. For example, tokenizing "<title>a<b>c</b>d</title>"
// yields a start tag token for "<title>", a text token for "a<b>c</b>d", and
// an end tag token for "</title>". There are no distinct start tag or end tag
// tokens for the "<b>" and "</b>".
//
// This tokenizer implementation will generally look for raw text at the right
// times. Strictly speaking, an HTML5 compliant tokenizer should not look for
// raw text if in foreign content: <title> generally needs raw text, but a
// <title> inside an <svg> does not. Another example is that a <textarea>
// generally needs raw text, but a <textarea> is not allowed as an immediate
// child of a <select>; in normal parsing, a <textarea> implies </select>, but
// one cannot close the implicit element when parsing a <select>'s InnerHTML.
// Similarly to AllowCDATA, tracking the correct moment to override raw-text-
// ness is difficult to do purely in the tokenizer, as opposed to the parser.
// For strict compliance with the HTML5 tokenization algorithm, it is the
// responsibility of the user of a tokenizer to call NextIsNotRawText as
// appropriate. In practice, like AllowCDATA, it is acceptable to ignore this
// responsibility for basic usage.
//
// Note that this 'raw text' concept is different from the one offered by the
// Tokenizer.Raw method.
func (z *Tokenizer) NextIsNotRawText() {
z.rawTag = ""
}
// Err returns the error associated with the most recent ErrorToken token.
// This is typically io.EOF, meaning the end of tokenization.
func (z *Tokenizer) Err() error {
if z.tt != ErrorToken {
return nil
}
return z.err
}
// readByte returns the next byte from the input stream, doing a buffered read
// from z.r into z.buf if necessary. z.buf[z.raw.start:z.raw.end] remains a contiguous byte
// slice that holds all the bytes read so far for the current token.
// It sets z.err if the underlying reader returns an error.
// Pre-condition: z.err == nil.
func (z *Tokenizer) readByte() byte {
if z.raw.end >= len(z.buf) {
// Our buffer is exhausted and we have to read from z.r. Check if the
// previous read resulted in an error.
if z.readErr != nil {
z.err = z.readErr
return 0
}
// We copy z.buf[z.raw.start:z.raw.end] to the beginning of z.buf. If the length
// z.raw.end - z.raw.start is more than half the capacity of z.buf, then we
// allocate a new buffer before the copy.
c := cap(z.buf)
d := z.raw.end - z.raw.start
var buf1 []byte
if 2*d > c {
buf1 = make([]byte, d, 2*c)
} else {
buf1 = z.buf[:d]
}
copy(buf1, z.buf[z.raw.start:z.raw.end])
if x := z.raw.start; x != 0 {
// Adjust the data/attr spans to refer to the same contents after the copy.
z.data.start -= x
z.data.end -= x
z.pendingAttr[0].start -= x
z.pendingAttr[0].end -= x
z.pendingAttr[1].start -= x
z.pendingAttr[1].end -= x
for i := range z.attr {
z.attr[i][0].start -= x
z.attr[i][0].end -= x
z.attr[i][1].start -= x
z.attr[i][1].end -= x
}
}
z.raw.start, z.raw.end, z.buf = 0, d, buf1[:d]
// Now that we have copied the live bytes to the start of the buffer,
// we read from z.r into the remainder.
var n int
n, z.readErr = readAtLeastOneByte(z.r, buf1[d:cap(buf1)])
if n == 0 {
z.err = z.readErr
return 0
}
z.buf = buf1[:d+n]
}
x := z.buf[z.raw.end]
z.raw.end++
if z.maxBuf > 0 && z.raw.end-z.raw.start >= z.maxBuf {
z.err = ErrBufferExceeded
return 0
}
return x
}
// Buffered returns a slice containing data buffered but not yet tokenized.
func (z *Tokenizer) Buffered() []byte {
return z.buf[z.raw.end:]
}
// readAtLeastOneByte wraps an io.Reader so that reading cannot return (0, nil).
// It returns io.ErrNoProgress if the underlying r.Read method returns (0, nil)
// too many times in succession.
func readAtLeastOneByte(r io.Reader, b []byte) (int, error) {
for i := 0; i < 100; i++ {
n, err := r.Read(b)
if n != 0 || err != nil {
return n, err
}
}
return 0, io.ErrNoProgress
}
// skipWhiteSpace skips past any white space.
func (z *Tokenizer) skipWhiteSpace() {
if z.err != nil {
return
}
for {
c := z.readByte()
if z.err != nil {
return
}
switch c {
case ' ', '\n', '\r', '\t', '\f':
// No-op.
default:
z.raw.end--
return
}
}
}
// readRawOrRCDATA reads until the next "</foo>", where "foo" is z.rawTag and
// is typically something like "script" or "textarea".
func (z *Tokenizer) readRawOrRCDATA() {
if z.rawTag == "script" {
z.readScript()
z.textIsRaw = true
z.rawTag = ""
return
}
loop:
for {
c := z.readByte()
if z.err != nil {
break loop
}
if c != '<' {
continue loop
}
c = z.readByte()
if z.err != nil {
break loop
}
if c != '/' {
continue loop
}
if z.readRawEndTag() || z.err != nil {
break loop
}
}
z.data.end = z.raw.end
// A textarea's or title's RCDATA can contain escaped entities.
z.textIsRaw = z.rawTag != "textarea" && z.rawTag != "title"
z.rawTag = ""
}
// readRawEndTag attempts to read a tag like "</foo>", where "foo" is z.rawTag.
// If it succeeds, it backs up the input position to reconsume the tag and
// returns true. Otherwise it returns false. The opening "</" has already been
// consumed.
func (z *Tokenizer) readRawEndTag() bool {
for i := 0; i < len(z.rawTag); i++ {
c := z.readByte()
if z.err != nil {
return false
}
if c != z.rawTag[i] && c != z.rawTag[i]-('a'-'A') {
z.raw.end--
return false
}
}
c := z.readByte()
if z.err != nil {
return false
}
switch c {
case ' ', '\n', '\r', '\t', '\f', '/', '>':
// The 3 is 2 for the leading "</" plus 1 for the trailing character c.
z.raw.end -= 3 + len(z.rawTag)
return true
}
z.raw.end--
return false
}
// readScript reads until the next </script> tag, following the byzantine
// rules for escaping/hiding the closing tag.
func (z *Tokenizer) readScript() {
defer func() {
z.data.end = z.raw.end
}()
var c byte
scriptData:
c = z.readByte()
if z.err != nil {
return
}
if c == '<' {
goto scriptDataLessThanSign
}
goto scriptData
scriptDataLessThanSign:
c = z.readByte()
if z.err != nil {
return
}
switch c {
case '/':
goto scriptDataEndTagOpen
case '!':
goto scriptDataEscapeStart
}
z.raw.end--
goto scriptData
scriptDataEndTagOpen:
if z.readRawEndTag() || z.err != nil {
return
}
goto scriptData
scriptDataEscapeStart:
c = z.readByte()
if z.err != nil {
return
}
if c == '-' {
goto scriptDataEscapeStartDash
}
z.raw.end--
goto scriptData
scriptDataEscapeStartDash:
c = z.readByte()
if z.err != nil {
return
}
if c == '-' {
goto scriptDataEscapedDashDash
}
z.raw.end--
goto scriptData
scriptDataEscaped:
c = z.readByte()
if z.err != nil {
return
}
switch c {
case '-':
goto scriptDataEscapedDash
case '<':
goto scriptDataEscapedLessThanSign
}
goto scriptDataEscaped
scriptDataEscapedDash:
c = z.readByte()
if z.err != nil {
return
}
switch c {
case '-':
goto scriptDataEscapedDashDash
case '<':
goto scriptDataEscapedLessThanSign
}
goto scriptDataEscaped
scriptDataEscapedDashDash:
c = z.readByte()
if z.err != nil {
return
}
switch c {
case '-':
goto scriptDataEscapedDashDash
case '<':
goto scriptDataEscapedLessThanSign
case '>':
goto scriptData
}
goto scriptDataEscaped
scriptDataEscapedLessThanSign:
c = z.readByte()
if z.err != nil {
return
}
if c == '/' {
goto scriptDataEscapedEndTagOpen
}
if 'a' <= c && c <= 'z' || 'A' <= c && c <= 'Z' {
goto scriptDataDoubleEscapeStart
}
z.raw.end--
goto scriptData
scriptDataEscapedEndTagOpen:
if z.readRawEndTag() || z.err != nil {
return
}
goto scriptDataEscaped
scriptDataDoubleEscapeStart:
z.raw.end--
for i := 0; i < len("script"); i++ {
c = z.readByte()
if z.err != nil {
return
}
if c != "script"[i] && c != "SCRIPT"[i] {
z.raw.end--
goto scriptDataEscaped
}
}
c = z.readByte()
if z.err != nil {
return
}
switch c {
case ' ', '\n', '\r', '\t', '\f', '/', '>':
goto scriptDataDoubleEscaped
}
z.raw.end--
goto scriptDataEscaped
scriptDataDoubleEscaped:
c = z.readByte()
if z.err != nil {
return
}
switch c {
case '-':
goto scriptDataDoubleEscapedDash
case '<':
goto scriptDataDoubleEscapedLessThanSign
}
goto scriptDataDoubleEscaped
scriptDataDoubleEscapedDash:
c = z.readByte()
if z.err != nil {
return
}
switch c {
case '-':
goto scriptDataDoubleEscapedDashDash
case '<':
goto scriptDataDoubleEscapedLessThanSign
}
goto scriptDataDoubleEscaped
scriptDataDoubleEscapedDashDash:
c = z.readByte()
if z.err != nil {
return
}
switch c {
case '-':
goto scriptDataDoubleEscapedDashDash
case '<':
goto scriptDataDoubleEscapedLessThanSign
case '>':
goto scriptData
}
goto scriptDataDoubleEscaped
scriptDataDoubleEscapedLessThanSign:
c = z.readByte()
if z.err != nil {
return
}
if c == '/' {
goto scriptDataDoubleEscapeEnd
}
z.raw.end--
goto scriptDataDoubleEscaped
scriptDataDoubleEscapeEnd:
if z.readRawEndTag() {
z.raw.end += len("</script>")
goto scriptDataEscaped
}
if z.err != nil {
return
}
goto scriptDataDoubleEscaped
}
// readComment reads the next comment token starting with "<!--". The opening
// "<!--" has already been consumed.
func (z *Tokenizer) readComment() {
z.data.start = z.raw.end
defer func() {
if z.data.end < z.data.start {
// It's a comment with no data, like <!-->.
z.data.end = z.data.start
}
}()
for dashCount := 2; ; {
c := z.readByte()
if z.err != nil {
// Ignore up to two dashes at EOF.
if dashCount > 2 {
dashCount = 2
}
z.data.end = z.raw.end - dashCount
return
}
switch c {
case '-':
dashCount++
continue
case '>':
if dashCount >= 2 {
z.data.end = z.raw.end - len("-->")
return
}
case '!':
if dashCount >= 2 {
c = z.readByte()
if z.err != nil {
z.data.end = z.raw.end
return
}
if c == '>' {
z.data.end = z.raw.end - len("--!>")
return
}
}
}
dashCount = 0
}
}
// readUntilCloseAngle reads until the next ">".
func (z *Tokenizer) readUntilCloseAngle() {
z.data.start = z.raw.end
for {
c := z.readByte()
if z.err != nil {
z.data.end = z.raw.end
return
}
if c == '>' {
z.data.end = z.raw.end - len(">")
return
}
}
}
// readMarkupDeclaration reads the next token starting with "<!". It might be
// a "<!--comment-->", a "<!DOCTYPE foo>", a "<![CDATA[section]]>" or
// "<!a bogus comment". The opening "<!" has already been consumed.
func (z *Tokenizer) readMarkupDeclaration() TokenType {
z.data.start = z.raw.end
var c [2]byte
for i := 0; i < 2; i++ {
c[i] = z.readByte()
if z.err != nil {
z.data.end = z.raw.end
return CommentToken
}
}
if c[0] == '-' && c[1] == '-' {
z.readComment()
return CommentToken
}
z.raw.end -= 2
if z.readDoctype() {
return DoctypeToken
}
if z.allowCDATA && z.readCDATA() {
z.convertNUL = true
return TextToken
}
// It's a bogus comment.
z.readUntilCloseAngle()
return CommentToken
}
// readDoctype attempts to read a doctype declaration and returns true if
// successful. The opening "<!" has already been consumed.
func (z *Tokenizer) readDoctype() bool {
const s = "DOCTYPE"
for i := 0; i < len(s); i++ {
c := z.readByte()
if z.err != nil {
z.data.end = z.raw.end
return false
}
if c != s[i] && c != s[i]+('a'-'A') {
// Back up to read the fragment of "DOCTYPE" again.
z.raw.end = z.data.start
return false
}
}
if z.skipWhiteSpace(); z.err != nil {
z.data.start = z.raw.end
z.data.end = z.raw.end
return true
}
z.readUntilCloseAngle()
return true
}
// readCDATA attempts to read a CDATA section and returns true if
// successful. The opening "<!" has already been consumed.
func (z *Tokenizer) readCDATA() bool {
const s = "[CDATA["
for i := 0; i < len(s); i++ {
c := z.readByte()
if z.err != nil {
z.data.end = z.raw.end
return false
}
if c != s[i] {
// Back up to read the fragment of "[CDATA[" again.
z.raw.end = z.data.start
return false
}
}
z.data.start = z.raw.end
brackets := 0
for {
c := z.readByte()
if z.err != nil {
z.data.end = z.raw.end
return true
}
switch c {
case ']':
brackets++
case '>':
if brackets >= 2 {
z.data.end = z.raw.end - len("]]>")
return true
}
brackets = 0
default:
brackets = 0
}
}
}
// startTagIn returns whether the start tag in z.buf[z.data.start:z.data.end]
// case-insensitively matches any element of ss.
func (z *Tokenizer) startTagIn(ss ...string) bool {
loop:
for _, s := range ss {
if z.data.end-z.data.start != len(s) {
continue loop
}
for i := 0; i < len(s); i++ {
c := z.buf[z.data.start+i]
if 'A' <= c && c <= 'Z' {
c += 'a' - 'A'
}
if c != s[i] {
continue loop
}
}
return true
}
return false
}
// readStartTag reads the next start tag token. The opening "<a" has already
// been consumed, where 'a' means anything in [A-Za-z].
func (z *Tokenizer) readStartTag() TokenType {
z.readTag(true)
if z.err != nil {
return ErrorToken
}
// Several tags flag the tokenizer's next token as raw.
c, raw := z.buf[z.data.start], false
if 'A' <= c && c <= 'Z' {
c += 'a' - 'A'
}
switch c {
case 'i':
raw = z.startTagIn("iframe")
case 'n':
raw = z.startTagIn("noembed", "noframes", "noscript")
case 'p':
raw = z.startTagIn("plaintext")
case 's':
raw = z.startTagIn("script", "style")
case 't':
raw = z.startTagIn("textarea", "title")
case 'x':
raw = z.startTagIn("xmp")
}
if raw {
z.rawTag = strings.ToLower(string(z.buf[z.data.start:z.data.end]))
}
// Look for a self-closing token like "<br/>".
if z.err == nil && z.buf[z.raw.end-2] == '/' {
return SelfClosingTagToken
}
return StartTagToken
}
// readTag reads the next tag token and its attributes. If saveAttr, those
// attributes are saved in z.attr, otherwise z.attr is set to an empty slice.
// The opening "<a" or "</a" has already been consumed, where 'a' means anything
// in [A-Za-z].
func (z *Tokenizer) readTag(saveAttr bool) {
z.attr = z.attr[:0]
z.nAttrReturned = 0
// Read the tag name and attribute key/value pairs.
z.readTagName()
if z.skipWhiteSpace(); z.err != nil {
return
}
for {
c := z.readByte()
if z.err != nil || c == '>' {
break
}
z.raw.end--
z.readTagAttrKey()
z.readTagAttrVal()
// Save pendingAttr if saveAttr and that attribute has a non-empty key.
if saveAttr && z.pendingAttr[0].start != z.pendingAttr[0].end {
z.attr = append(z.attr, z.pendingAttr)
}
if z.skipWhiteSpace(); z.err != nil {
break
}
}
}
// readTagName sets z.data to the "div" in "<div k=v>". The reader (z.raw.end)
// is positioned such that the first byte of the tag name (the "d" in "<div")
// has already been consumed.
func (z *Tokenizer) readTagName() {
z.data.start = z.raw.end - 1
for {
c := z.readByte()
if z.err != nil {
z.data.end = z.raw.end
return
}
switch c {
case ' ', '\n', '\r', '\t', '\f':
z.data.end = z.raw.end - 1
return
case '/', '>':
z.raw.end--
z.data.end = z.raw.end
return
}
}
}
// readTagAttrKey sets z.pendingAttr[0] to the "k" in "<div k=v>".
// Precondition: z.err == nil.
func (z *Tokenizer) readTagAttrKey() {
z.pendingAttr[0].start = z.raw.end
for {
c := z.readByte()
if z.err != nil {
z.pendingAttr[0].end = z.raw.end
return
}
switch c {
case ' ', '\n', '\r', '\t', '\f', '/':
z.pendingAttr[0].end = z.raw.end - 1
return
case '=', '>':
z.raw.end--
z.pendingAttr[0].end = z.raw.end
return
}
}
}
// readTagAttrVal sets z.pendingAttr[1] to the "v" in "<div k=v>".
func (z *Tokenizer) readTagAttrVal() {
z.pendingAttr[1].start = z.raw.end
z.pendingAttr[1].end = z.raw.end
if z.skipWhiteSpace(); z.err != nil {
return
}
c := z.readByte()
if z.err != nil {
return
}
if c != '=' {
z.raw.end--
return
}
if z.skipWhiteSpace(); z.err != nil {
return
}
quote := z.readByte()
if z.err != nil {
return
}
switch quote {
case '>':
z.raw.end--
return
case '\'', '"':
z.pendingAttr[1].start = z.raw.end
for {
c := z.readByte()
if z.err != nil {
z.pendingAttr[1].end = z.raw.end
return
}
if c == quote {
z.pendingAttr[1].end = z.raw.end - 1
return
}
}
default:
z.pendingAttr[1].start = z.raw.end - 1
for {
c := z.readByte()
if z.err != nil {
z.pendingAttr[1].end = z.raw.end
return
}
switch c {
case ' ', '\n', '\r', '\t', '\f':
z.pendingAttr[1].end = z.raw.end - 1
return
case '>':
z.raw.end--
z.pendingAttr[1].end = z.raw.end
return
}
}
}
}
// Next scans the next token and returns its type.
func (z *Tokenizer) Next() TokenType {
z.raw.start = z.raw.end
z.data.start = z.raw.end
z.data.end = z.raw.end
if z.err != nil {
z.tt = ErrorToken
return z.tt
}
if z.rawTag != "" {
if z.rawTag == "plaintext" {
// Read everything up to EOF.
for z.err == nil {
z.readByte()
}
z.data.end = z.raw.end
z.textIsRaw = true
} else {
z.readRawOrRCDATA()
}
if z.data.end > z.data.start {
z.tt = TextToken
z.convertNUL = true
return z.tt
}
}
z.textIsRaw = false
z.convertNUL = false
loop:
for {
c := z.readByte()
if z.err != nil {
break loop
}
if c != '<' {
continue loop
}
// Check if the '<' we have just read is part of a tag, comment
// or doctype. If not, it's part of the accumulated text token.
c = z.readByte()
if z.err != nil {
break loop
}
var tokenType TokenType
switch {
case 'a' <= c && c <= 'z' || 'A' <= c && c <= 'Z':
tokenType = StartTagToken
case c == '/':
tokenType = EndTagToken
case c == '!' || c == '?':
// We use CommentToken to mean any of "<!--actual comments-->",
// "<!DOCTYPE declarations>" and "<?xml processing instructions?>".
tokenType = CommentToken
default:
// Reconsume the current character.
z.raw.end--
continue
}
// We have a non-text token, but we might have accumulated some text
// before that. If so, we return the text first, and return the non-
// text token on the subsequent call to Next.
if x := z.raw.end - len("<a"); z.raw.start < x {
z.raw.end = x
z.data.end = x
z.tt = TextToken
return z.tt
}
switch tokenType {
case StartTagToken:
z.tt = z.readStartTag()
return z.tt
case EndTagToken:
c = z.readByte()
if z.err != nil {
break loop
}
if c == '>' {
// "</>" does not generate a token at all. Generate an empty comment
// to allow passthrough clients to pick up the data using Raw.
// Reset the tokenizer state and start again.
z.tt = CommentToken
return z.tt
}
if 'a' <= c && c <= 'z' || 'A' <= c && c <= 'Z' {
z.readTag(false)
if z.err != nil {
z.tt = ErrorToken
} else {
z.tt = EndTagToken
}
return z.tt
}
z.raw.end--
z.readUntilCloseAngle()
z.tt = CommentToken
return z.tt
case CommentToken:
if c == '!' {
z.tt = z.readMarkupDeclaration()
return z.tt
}
z.raw.end--
z.readUntilCloseAngle()
z.tt = CommentToken
return z.tt
}
}
if z.raw.start < z.raw.end {
z.data.end = z.raw.end
z.tt = TextToken
return z.tt
}
z.tt = ErrorToken
return z.tt
}
// Raw returns the unmodified text of the current token. Calling Next, Token,
// Text, TagName or TagAttr may change the contents of the returned slice.
func (z *Tokenizer) Raw() []byte {
return z.buf[z.raw.start:z.raw.end]
}
// convertNewlines converts "\r" and "\r\n" in s to "\n".
// The conversion happens in place, but the resulting slice may be shorter.
func convertNewlines(s []byte) []byte {
for i, c := range s {
if c != '\r' {
continue
}
src := i + 1
if src >= len(s) || s[src] != '\n' {
s[i] = '\n'
continue
}
dst := i
for src < len(s) {
if s[src] == '\r' {
if src+1 < len(s) && s[src+1] == '\n' {
src++
}
s[dst] = '\n'
} else {
s[dst] = s[src]
}
src++
dst++
}
return s[:dst]
}
return s
}
var (
nul = []byte("\x00")
replacement = []byte("\ufffd")
)
// Text returns the unescaped text of a text, comment or doctype token. The
// contents of the returned slice may change on the next call to Next.
func (z *Tokenizer) Text() []byte {
switch z.tt {
case TextToken, CommentToken, DoctypeToken:
s := z.buf[z.data.start:z.data.end]
z.data.start = z.raw.end
z.data.end = z.raw.end
s = convertNewlines(s)
if (z.convertNUL || z.tt == CommentToken) && bytes.Contains(s, nul) {
s = bytes.Replace(s, nul, replacement, -1)
}
if !z.textIsRaw {
s = unescape(s, false)
}
return s
}
return nil
}
// TagName returns the lower-cased name of a tag token (the `img` out of
// `<IMG SRC="foo">`) and whether the tag has attributes.
// The contents of the returned slice may change on the next call to Next.
func (z *Tokenizer) TagName() (name []byte, hasAttr bool) {
if z.data.start < z.data.end {
switch z.tt {
case StartTagToken, EndTagToken, SelfClosingTagToken:
s := z.buf[z.data.start:z.data.end]
z.data.start = z.raw.end
z.data.end = z.raw.end
return lower(s), z.nAttrReturned < len(z.attr)
}
}
return nil, false
}
// TagAttr returns the lower-cased key and unescaped value of the next unparsed
// attribute for the current tag token and whether there are more attributes.
// The contents of the returned slices may change on the next call to Next.
func (z *Tokenizer) TagAttr() (key, val []byte, moreAttr bool) {
if z.nAttrReturned < len(z.attr) {
switch z.tt {
case StartTagToken, SelfClosingTagToken:
x := z.attr[z.nAttrReturned]
z.nAttrReturned++
key = z.buf[x[0].start:x[0].end]
val = z.buf[x[1].start:x[1].end]
return lower(key), unescape(convertNewlines(val), true), z.nAttrReturned < len(z.attr)
}
}
return nil, nil, false
}
// Token returns the next Token. The result's Data and Attr values remain valid
// after subsequent Next calls.
func (z *Tokenizer) Token() Token {
t := Token{Type: z.tt}
switch z.tt {
case TextToken, CommentToken, DoctypeToken:
t.Data = string(z.Text())
case StartTagToken, SelfClosingTagToken, EndTagToken:
name, moreAttr := z.TagName()
for moreAttr {
var key, val []byte
key, val, moreAttr = z.TagAttr()
t.Attr = append(t.Attr, Attribute{"", atom.String(key), string(val)})
}
if a := atom.Lookup(name); a != 0 {
t.DataAtom, t.Data = a, a.String()
} else {
t.DataAtom, t.Data = 0, string(name)
}
}
return t
}
// SetMaxBuf sets a limit on the amount of data buffered during tokenization.
// A value of 0 means unlimited.
func (z *Tokenizer) SetMaxBuf(n int) {
z.maxBuf = n
}
// NewTokenizer returns a new HTML Tokenizer for the given Reader.
// The input is assumed to be UTF-8 encoded.
func NewTokenizer(r io.Reader) *Tokenizer {
return NewTokenizerFragment(r, "")
}
// NewTokenizerFragment returns a new HTML Tokenizer for the given Reader, for
// tokenizing an existing element's InnerHTML fragment. contextTag is that
// element's tag, such as "div" or "iframe".
//
// For example, how the InnerHTML "a<b" is tokenized depends on whether it is
// for a <p> tag or a <script> tag.
//
// The input is assumed to be UTF-8 encoded.
func NewTokenizerFragment(r io.Reader, contextTag string) *Tokenizer {
z := &Tokenizer{
r: r,
buf: make([]byte, 0, 4096),
}
if contextTag != "" {
switch s := strings.ToLower(contextTag); s {
case "iframe", "noembed", "noframes", "noscript", "plaintext", "script", "style", "title", "textarea", "xmp":
z.rawTag = s
}
}
return z
}