// // Blackfriday Markdown Processor // Available at http://github.com/russross/blackfriday // // Copyright © 2011 Russ Ross . // Distributed under the Simplified BSD License. // See README.md for details. // // // Functions to parse inline elements. // package blackfriday import ( "bytes" "regexp" "strconv" ) var ( urlRe = `((https?|ftp):\/\/|\/)[-A-Za-z0-9+&@#\/%?=~_|!:,.;\(\)]+` anchorRe = regexp.MustCompile(`^(]+")?\s?>` + urlRe + `<\/a>)`) // TODO: improve this regexp to catch all possible entities: htmlEntityRe = regexp.MustCompile(`&[a-z]{2,5};`) ) // Functions to parse text within a block // Each function returns the number of chars taken care of // data is the complete block being rendered // offset is the number of valid chars before the current cursor func (p *parser) inline(data []byte) { // this is called recursively: enforce a maximum depth if p.nesting >= p.maxNesting { return } p.nesting++ i, end := 0, 0 for i < len(data) { // Stop at EOL if data[i] == '\n' && i+1 == len(data) { break } // Copy inactive chars into the output, but first check for one quirk: // 'h', 'm' and 'f' all might trigger a check for autolink processing // and end this run of inactive characters. However, there's one nasty // case where breaking this run would be bad: in smartypants fraction // detection, we expect things like "1/2th" to be in a single run. So // we check here if an 'h' is followed by 't' (from 'http') and if it's // not, we short circuit the 'h' into the run of inactive characters. // // Also, in a similar fashion maybeLineBreak breaks this run of chars, // but smartDash processor relies on seeing context around the dashes. // Fix this somehow. for end < len(data) { if data[end] == ' ' { consumed, br := maybeLineBreak(p, data, end) if consumed > 0 { p.currBlock.appendChild(text(data[i:end])) if br { p.currBlock.appendChild(NewNode(Hardbreak)) } i = end i += consumed end = i } else { end++ } continue } if p.inlineCallback[data[end]] != nil { if end+1 < len(data) && data[end] == 'h' && data[end+1] != 't' { end++ } else { break } } else { end++ } } p.currBlock.appendChild(text(data[i:end])) if end >= len(data) { break } i = end // call the trigger handler := p.inlineCallback[data[end]] if consumed := handler(p, data, i); consumed == 0 { // no action from the callback; buffer the byte for later end = i + 1 } else { // skip past whatever the callback used i += consumed end = i } } p.nesting-- } // single and double emphasis parsing func emphasis(p *parser, data []byte, offset int) int { data = data[offset:] c := data[0] ret := 0 if len(data) > 2 && data[1] != c { // whitespace cannot follow an opening emphasis; // strikethrough only takes two characters '~~' if c == '~' || isspace(data[1]) { return 0 } if ret = helperEmphasis(p, data[1:], c); ret == 0 { return 0 } return ret + 1 } if len(data) > 3 && data[1] == c && data[2] != c { if isspace(data[2]) { return 0 } if ret = helperDoubleEmphasis(p, data[2:], c); ret == 0 { return 0 } return ret + 2 } if len(data) > 4 && data[1] == c && data[2] == c && data[3] != c { if c == '~' || isspace(data[3]) { return 0 } if ret = helperTripleEmphasis(p, data, 3, c); ret == 0 { return 0 } return ret + 3 } return 0 } func codeSpan(p *parser, data []byte, offset int) int { data = data[offset:] nb := 0 // count the number of backticks in the delimiter for nb < len(data) && data[nb] == '`' { nb++ } // find the next delimiter i, end := 0, 0 for end = nb; end < len(data) && i < nb; end++ { if data[end] == '`' { i++ } else { i = 0 } } // no matching delimiter? if i < nb && end >= len(data) { return 0 } // trim outside whitespace fBegin := nb for fBegin < end && data[fBegin] == ' ' { fBegin++ } fEnd := end - nb for fEnd > fBegin && data[fEnd-1] == ' ' { fEnd-- } // render the code span if fBegin != fEnd { code := NewNode(Code) code.Literal = data[fBegin:fEnd] p.currBlock.appendChild(code) } return end } // newline preceded by two spaces becomes
func maybeLineBreak(p *parser, data []byte, offset int) (int, bool) { origOffset := offset for offset < len(data) && data[offset] == ' ' { offset++ } if offset < len(data) && data[offset] == '\n' { if offset-origOffset >= 2 { return offset - origOffset + 1, true } return offset - origOffset, false } return 0, false } // newline without two spaces works when HardLineBreak is enabled func lineBreak(p *parser, data []byte, offset int) int { if p.flags&HardLineBreak != 0 { p.currBlock.appendChild(NewNode(Hardbreak)) return 1 } return 0 } type linkType int const ( linkNormal linkType = iota linkImg linkDeferredFootnote linkInlineFootnote ) func isReferenceStyleLink(data []byte, pos int, t linkType) bool { if t == linkDeferredFootnote { return false } return pos < len(data)-1 && data[pos] == '[' && data[pos+1] != '^' } func maybeImage(p *parser, data []byte, offset int) int { if offset < len(data)-1 && data[offset+1] == '[' { return link(p, data, offset) } return 0 } func maybeInlineFootnote(p *parser, data []byte, offset int) int { if offset < len(data)-1 && data[offset+1] == '[' { return link(p, data, offset) } return 0 } // '[': parse a link or an image or a footnote func link(p *parser, data []byte, offset int) int { // no links allowed inside regular links, footnote, and deferred footnotes if p.insideLink && (offset > 0 && data[offset-1] == '[' || len(data)-1 > offset && data[offset+1] == '^') { return 0 } var t linkType switch { // special case: ![^text] == deferred footnote (that follows something with // an exclamation point) case p.flags&Footnotes != 0 && len(data)-1 > offset && data[offset+1] == '^': t = linkDeferredFootnote // ![alt] == image case offset >= 0 && data[offset] == '!': t = linkImg offset += 1 // ^[text] == inline footnote // [^refId] == deferred footnote case p.flags&Footnotes != 0: if offset >= 0 && data[offset] == '^' { t = linkInlineFootnote offset += 1 } else if len(data)-1 > offset && data[offset+1] == '^' { t = linkDeferredFootnote } // [text] == regular link default: t = linkNormal } data = data[offset:] var ( i = 1 noteId int title, link, altContent []byte textHasNl = false ) if t == linkDeferredFootnote { i++ } // look for the matching closing bracket for level := 1; level > 0 && i < len(data); i++ { switch { case data[i] == '\n': textHasNl = true case data[i-1] == '\\': continue case data[i] == '[': level++ case data[i] == ']': level-- if level <= 0 { i-- // compensate for extra i++ in for loop } } } if i >= len(data) { return 0 } txtE := i i++ // skip any amount of whitespace or newline // (this is much more lax than original markdown syntax) for i < len(data) && isspace(data[i]) { i++ } // inline style link switch { case i < len(data) && data[i] == '(': // skip initial whitespace i++ for i < len(data) && isspace(data[i]) { i++ } linkB := i // look for link end: ' " ) findlinkend: for i < len(data) { switch { case data[i] == '\\': i += 2 case data[i] == ')' || data[i] == '\'' || data[i] == '"': break findlinkend default: i++ } } if i >= len(data) { return 0 } linkE := i // look for title end if present titleB, titleE := 0, 0 if data[i] == '\'' || data[i] == '"' { i++ titleB = i findtitleend: for i < len(data) { switch { case data[i] == '\\': i += 2 case data[i] == ')': break findtitleend default: i++ } } if i >= len(data) { return 0 } // skip whitespace after title titleE = i - 1 for titleE > titleB && isspace(data[titleE]) { titleE-- } // check for closing quote presence if data[titleE] != '\'' && data[titleE] != '"' { titleB, titleE = 0, 0 linkE = i } } // remove whitespace at the end of the link for linkE > linkB && isspace(data[linkE-1]) { linkE-- } // remove optional angle brackets around the link if data[linkB] == '<' { linkB++ } if data[linkE-1] == '>' { linkE-- } // build escaped link and title if linkE > linkB { link = data[linkB:linkE] } if titleE > titleB { title = data[titleB:titleE] } i++ // reference style link case isReferenceStyleLink(data, i, t): var id []byte altContentConsidered := false // look for the id i++ linkB := i for i < len(data) && data[i] != ']' { i++ } if i >= len(data) { return 0 } linkE := i // find the reference if linkB == linkE { if textHasNl { var b bytes.Buffer for j := 1; j < txtE; j++ { switch { case data[j] != '\n': b.WriteByte(data[j]) case data[j-1] != ' ': b.WriteByte(' ') } } id = b.Bytes() } else { id = data[1:txtE] altContentConsidered = true } } else { id = data[linkB:linkE] } // find the reference with matching id lr, ok := p.getRef(string(id)) if !ok { return 0 } // keep link and title from reference link = lr.link title = lr.title if altContentConsidered { altContent = lr.text } i++ // shortcut reference style link or reference or inline footnote default: var id []byte // craft the id if textHasNl { var b bytes.Buffer for j := 1; j < txtE; j++ { switch { case data[j] != '\n': b.WriteByte(data[j]) case data[j-1] != ' ': b.WriteByte(' ') } } id = b.Bytes() } else { if t == linkDeferredFootnote { id = data[2:txtE] // get rid of the ^ } else { id = data[1:txtE] } } if t == linkInlineFootnote { // create a new reference noteId = len(p.notes) + 1 var fragment []byte if len(id) > 0 { if len(id) < 16 { fragment = make([]byte, len(id)) } else { fragment = make([]byte, 16) } copy(fragment, slugify(id)) } else { fragment = append([]byte("footnote-"), []byte(strconv.Itoa(noteId))...) } ref := &reference{ noteId: noteId, hasBlock: false, link: fragment, title: id, } p.notes = append(p.notes, ref) link = ref.link title = ref.title } else { // find the reference with matching id lr, ok := p.getRef(string(id)) if !ok { return 0 } if t == linkDeferredFootnote { lr.noteId = len(p.notes) + 1 p.notes = append(p.notes, lr) } // keep link and title from reference link = lr.link // if inline footnote, title == footnote contents title = lr.title noteId = lr.noteId } // rewind the whitespace i = txtE + 1 } var uLink []byte if t == linkNormal || t == linkImg { if len(link) > 0 { var uLinkBuf bytes.Buffer unescapeText(&uLinkBuf, link) uLink = uLinkBuf.Bytes() } // links need something to click on and somewhere to go if len(uLink) == 0 || (t == linkNormal && txtE <= 1) { return 0 } } // call the relevant rendering function switch t { case linkNormal: linkNode := NewNode(Link) linkNode.Destination = normalizeURI(uLink) linkNode.Title = title p.currBlock.appendChild(linkNode) if len(altContent) > 0 { linkNode.appendChild(text(altContent)) } else { // links cannot contain other links, so turn off link parsing // temporarily and recurse insideLink := p.insideLink p.insideLink = true tmpNode := p.currBlock p.currBlock = linkNode p.inline(data[1:txtE]) p.currBlock = tmpNode p.insideLink = insideLink } case linkImg: linkNode := NewNode(Image) linkNode.Destination = uLink linkNode.Title = title p.currBlock.appendChild(linkNode) linkNode.appendChild(text(data[1:txtE])) i += 1 case linkInlineFootnote, linkDeferredFootnote: linkNode := NewNode(Link) linkNode.Destination = link linkNode.Title = title linkNode.NoteID = noteId p.currBlock.appendChild(linkNode) if t == linkInlineFootnote { i++ } default: return 0 } return i } func (p *parser) inlineHtmlComment(data []byte) int { if len(data) < 5 { return 0 } if data[0] != '<' || data[1] != '!' || data[2] != '-' || data[3] != '-' { return 0 } i := 5 // scan for an end-of-comment marker, across lines if necessary for i < len(data) && !(data[i-2] == '-' && data[i-1] == '-' && data[i] == '>') { i++ } // no end-of-comment marker if i >= len(data) { return 0 } return i + 1 } func stripMailto(link []byte) []byte { if bytes.HasPrefix(link, []byte("mailto://")) { return link[9:] } else if bytes.HasPrefix(link, []byte("mailto:")) { return link[7:] } else { return link } } // '<' when tags or autolinks are allowed func leftAngle(p *parser, data []byte, offset int) int { data = data[offset:] altype := LinkTypeNotAutolink end := tagLength(data, &altype) if size := p.inlineHtmlComment(data); size > 0 { end = size } if end > 2 { if altype != LinkTypeNotAutolink { var uLink bytes.Buffer unescapeText(&uLink, data[1:end+1-2]) if uLink.Len() > 0 { link := uLink.Bytes() node := NewNode(Link) node.Destination = link if altype == LinkTypeEmail { node.Destination = append([]byte("mailto:"), link...) } p.currBlock.appendChild(node) node.appendChild(text(stripMailto(link))) } } else { htmlTag := NewNode(HTMLSpan) htmlTag.Literal = data[:end] p.currBlock.appendChild(htmlTag) } } return end } // '\\' backslash escape var escapeChars = []byte("\\`*_{}[]()#+-.!:|&<>~") func escape(p *parser, data []byte, offset int) int { data = data[offset:] if len(data) > 1 { if p.flags&BackslashLineBreak != 0 && data[1] == '\n' { p.currBlock.appendChild(NewNode(Hardbreak)) return 2 } if bytes.IndexByte(escapeChars, data[1]) < 0 { return 0 } p.currBlock.appendChild(text(data[1:2])) } return 2 } func unescapeText(ob *bytes.Buffer, src []byte) { i := 0 for i < len(src) { org := i for i < len(src) && src[i] != '\\' { i++ } if i > org { ob.Write(src[org:i]) } if i+1 >= len(src) { break } ob.WriteByte(src[i+1]) i += 2 } } // '&' escaped when it doesn't belong to an entity // valid entities are assumed to be anything matching &#?[A-Za-z0-9]+; func entity(p *parser, data []byte, offset int) int { data = data[offset:] end := 1 if end < len(data) && data[end] == '#' { end++ } for end < len(data) && isalnum(data[end]) { end++ } if end < len(data) && data[end] == ';' { end++ // real entity } else { return 0 // lone '&' } ent := data[:end] // undo & escaping or it will be converted to &amp; by another // escaper in the renderer if bytes.Equal(ent, []byte("&")) { ent = []byte{'&'} } p.currBlock.appendChild(text(ent)) return end } func linkEndsWithEntity(data []byte, linkEnd int) bool { entityRanges := htmlEntityRe.FindAllIndex(data[:linkEnd], -1) return entityRanges != nil && entityRanges[len(entityRanges)-1][1] == linkEnd } func maybeAutoLink(p *parser, data []byte, offset int) int { // quick check to rule out most false hits if p.insideLink || len(data) < offset+6 { // 6 is the len() of the shortest prefix below return 0 } prefixes := []string{ "http://", "https://", "ftp://", "file://", "mailto:", } for _, prefix := range prefixes { endOfHead := offset + 8 // 8 is the len() of the longest prefix if endOfHead > len(data) { endOfHead = len(data) } head := bytes.ToLower(data[offset:endOfHead]) if bytes.HasPrefix(head, []byte(prefix)) { return autoLink(p, data, offset) } } return 0 } func autoLink(p *parser, data []byte, offset int) int { // Now a more expensive check to see if we're not inside an anchor element anchorStart := offset offsetFromAnchor := 0 for anchorStart > 0 && data[anchorStart] != '<' { anchorStart-- offsetFromAnchor++ } anchorStr := anchorRe.Find(data[anchorStart:]) if anchorStr != nil { anchorClose := NewNode(HTMLSpan) anchorClose.Literal = anchorStr[offsetFromAnchor:] p.currBlock.appendChild(anchorClose) return len(anchorStr) - offsetFromAnchor } // scan backward for a word boundary rewind := 0 for offset-rewind > 0 && rewind <= 7 && isletter(data[offset-rewind-1]) { rewind++ } if rewind > 6 { // longest supported protocol is "mailto" which has 6 letters return 0 } origData := data data = data[offset-rewind:] if !isSafeLink(data) { return 0 } linkEnd := 0 for linkEnd < len(data) && !isEndOfLink(data[linkEnd]) { linkEnd++ } // Skip punctuation at the end of the link if (data[linkEnd-1] == '.' || data[linkEnd-1] == ',') && data[linkEnd-2] != '\\' { linkEnd-- } // But don't skip semicolon if it's a part of escaped entity: if data[linkEnd-1] == ';' && data[linkEnd-2] != '\\' && !linkEndsWithEntity(data, linkEnd) { linkEnd-- } // See if the link finishes with a punctuation sign that can be closed. var copen byte switch data[linkEnd-1] { case '"': copen = '"' case '\'': copen = '\'' case ')': copen = '(' case ']': copen = '[' case '}': copen = '{' default: copen = 0 } if copen != 0 { bufEnd := offset - rewind + linkEnd - 2 openDelim := 1 /* Try to close the final punctuation sign in this same line; * if we managed to close it outside of the URL, that means that it's * not part of the URL. If it closes inside the URL, that means it * is part of the URL. * * Examples: * * foo http://www.pokemon.com/Pikachu_(Electric) bar * => http://www.pokemon.com/Pikachu_(Electric) * * foo (http://www.pokemon.com/Pikachu_(Electric)) bar * => http://www.pokemon.com/Pikachu_(Electric) * * foo http://www.pokemon.com/Pikachu_(Electric)) bar * => http://www.pokemon.com/Pikachu_(Electric)) * * (foo http://www.pokemon.com/Pikachu_(Electric)) bar * => foo http://www.pokemon.com/Pikachu_(Electric) */ for bufEnd >= 0 && origData[bufEnd] != '\n' && openDelim != 0 { if origData[bufEnd] == data[linkEnd-1] { openDelim++ } if origData[bufEnd] == copen { openDelim-- } bufEnd-- } if openDelim == 0 { linkEnd-- } } var uLink bytes.Buffer unescapeText(&uLink, data[:linkEnd]) if uLink.Len() > 0 { node := NewNode(Link) node.Destination = uLink.Bytes() p.currBlock.appendChild(node) node.appendChild(text(uLink.Bytes())) } return linkEnd } func isEndOfLink(char byte) bool { return isspace(char) || char == '<' } var validUris = [][]byte{[]byte("http://"), []byte("https://"), []byte("ftp://"), []byte("mailto://")} var validPaths = [][]byte{[]byte("/"), []byte("./"), []byte("../")} func isSafeLink(link []byte) bool { for _, path := range validPaths { if len(link) >= len(path) && bytes.Equal(link[:len(path)], path) { if len(link) == len(path) { return true } else if isalnum(link[len(path)]) { return true } } } for _, prefix := range validUris { // TODO: handle unicode here // case-insensitive prefix test if len(link) > len(prefix) && bytes.Equal(bytes.ToLower(link[:len(prefix)]), prefix) && isalnum(link[len(prefix)]) { return true } } return false } // return the length of the given tag, or 0 is it's not valid func tagLength(data []byte, autolink *LinkType) int { var i, j int // a valid tag can't be shorter than 3 chars if len(data) < 3 { return 0 } // begins with a '<' optionally followed by '/', followed by letter or number if data[0] != '<' { return 0 } if data[1] == '/' { i = 2 } else { i = 1 } if !isalnum(data[i]) { return 0 } // scheme test *autolink = LinkTypeNotAutolink // try to find the beginning of an URI for i < len(data) && (isalnum(data[i]) || data[i] == '.' || data[i] == '+' || data[i] == '-') { i++ } if i > 1 && i < len(data) && data[i] == '@' { if j = isMailtoAutoLink(data[i:]); j != 0 { *autolink = LinkTypeEmail return i + j } } if i > 2 && i < len(data) && data[i] == ':' { *autolink = LinkTypeNormal i++ } // complete autolink test: no whitespace or ' or " switch { case i >= len(data): *autolink = LinkTypeNotAutolink case *autolink != 0: j = i for i < len(data) { if data[i] == '\\' { i += 2 } else if data[i] == '>' || data[i] == '\'' || data[i] == '"' || isspace(data[i]) { break } else { i++ } } if i >= len(data) { return 0 } if i > j && data[i] == '>' { return i + 1 } // one of the forbidden chars has been found *autolink = LinkTypeNotAutolink } // look for something looking like a tag end for i < len(data) && data[i] != '>' { i++ } if i >= len(data) { return 0 } return i + 1 } // look for the address part of a mail autolink and '>' // this is less strict than the original markdown e-mail address matching func isMailtoAutoLink(data []byte) int { nb := 0 // address is assumed to be: [-@._a-zA-Z0-9]+ with exactly one '@' for i := 0; i < len(data); i++ { if isalnum(data[i]) { continue } switch data[i] { case '@': nb++ case '-', '.', '_': break case '>': if nb == 1 { return i + 1 } else { return 0 } default: return 0 } } return 0 } // look for the next emph char, skipping other constructs func helperFindEmphChar(data []byte, c byte) int { i := 0 for i < len(data) { for i < len(data) && data[i] != c && data[i] != '`' && data[i] != '[' { i++ } if i >= len(data) { return 0 } // do not count escaped chars if i != 0 && data[i-1] == '\\' { i++ continue } if data[i] == c { return i } if data[i] == '`' { // skip a code span tmpI := 0 i++ for i < len(data) && data[i] != '`' { if tmpI == 0 && data[i] == c { tmpI = i } i++ } if i >= len(data) { return tmpI } i++ } else if data[i] == '[' { // skip a link tmpI := 0 i++ for i < len(data) && data[i] != ']' { if tmpI == 0 && data[i] == c { tmpI = i } i++ } i++ for i < len(data) && (data[i] == ' ' || data[i] == '\n') { i++ } if i >= len(data) { return tmpI } if data[i] != '[' && data[i] != '(' { // not a link if tmpI > 0 { return tmpI } else { continue } } cc := data[i] i++ for i < len(data) && data[i] != cc { if tmpI == 0 && data[i] == c { return i } i++ } if i >= len(data) { return tmpI } i++ } } return 0 } func helperEmphasis(p *parser, data []byte, c byte) int { i := 0 // skip one symbol if coming from emph3 if len(data) > 1 && data[0] == c && data[1] == c { i = 1 } for i < len(data) { length := helperFindEmphChar(data[i:], c) if length == 0 { return 0 } i += length if i >= len(data) { return 0 } if i+1 < len(data) && data[i+1] == c { i++ continue } if data[i] == c && !isspace(data[i-1]) { if p.flags&NoIntraEmphasis != 0 { if !(i+1 == len(data) || isspace(data[i+1]) || ispunct(data[i+1])) { continue } } emph := NewNode(Emph) p.currBlock.appendChild(emph) tmp := p.currBlock p.currBlock = emph p.inline(data[:i]) p.currBlock = tmp return i + 1 } } return 0 } func helperDoubleEmphasis(p *parser, data []byte, c byte) int { i := 0 for i < len(data) { length := helperFindEmphChar(data[i:], c) if length == 0 { return 0 } i += length if i+1 < len(data) && data[i] == c && data[i+1] == c && i > 0 && !isspace(data[i-1]) { nodeType := Strong if c == '~' { nodeType = Del } node := NewNode(nodeType) p.currBlock.appendChild(node) tmp := p.currBlock p.currBlock = node p.inline(data[:i]) p.currBlock = tmp return i + 2 } i++ } return 0 } func helperTripleEmphasis(p *parser, data []byte, offset int, c byte) int { i := 0 origData := data data = data[offset:] for i < len(data) { length := helperFindEmphChar(data[i:], c) if length == 0 { return 0 } i += length // skip whitespace preceded symbols if data[i] != c || isspace(data[i-1]) { continue } switch { case i+2 < len(data) && data[i+1] == c && data[i+2] == c: // triple symbol found strong := NewNode(Strong) em := NewNode(Emph) strong.appendChild(em) p.currBlock.appendChild(strong) tmp := p.currBlock p.currBlock = em p.inline(data[:i]) p.currBlock = tmp return i + 3 case (i+1 < len(data) && data[i+1] == c): // double symbol found, hand over to emph1 length = helperEmphasis(p, origData[offset-2:], c) if length == 0 { return 0 } else { return length - 2 } default: // single symbol found, hand over to emph2 length = helperDoubleEmphasis(p, origData[offset-1:], c) if length == 0 { return 0 } else { return length - 1 } } } return 0 } func text(s []byte) *Node { node := NewNode(Text) node.Literal = s return node } func normalizeURI(s []byte) []byte { return s // TODO: implement }