// 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 parse import ( "fmt" "strings" "unicode" "unicode/utf8" ) // item represents a token or text string returned from the scanner. type item struct { typ itemType // The type of this item. pos Pos // The starting position, in bytes, of this item in the input string. val string // The value of this item. line int // The line number at the start of this item. } func (i item) String() string { switch { case i.typ == itemEOF: return "EOF" case i.typ == itemError: return i.val case i.typ > itemKeyword: return fmt.Sprintf("<%s>", i.val) case len(i.val) > 10: return fmt.Sprintf("%.10q...", i.val) } return fmt.Sprintf("%q", i.val) } // itemType identifies the type of lex items. type itemType int const ( itemError itemType = iota // error occurred; value is text of error itemBool // boolean constant itemChar // printable ASCII character; grab bag for comma etc. itemCharConstant // character constant itemComment // comment text itemComplex // complex constant (1+2i); imaginary is just a number itemAssign // equals ('=') introducing an assignment itemDeclare // colon-equals (':=') introducing a declaration itemEOF itemField // alphanumeric identifier starting with '.' itemIdentifier // alphanumeric identifier not starting with '.' itemLeftDelim // left action delimiter itemLeftParen // '(' inside action itemNumber // simple number, including imaginary itemPipe // pipe symbol itemRawString // raw quoted string (includes quotes) itemRightDelim // right action delimiter itemRightParen // ')' inside action itemSpace // run of spaces separating arguments itemString // quoted string (includes quotes) itemText // plain text itemVariable // variable starting with '$', such as '$' or '$1' or '$hello' // Keywords appear after all the rest. itemKeyword // used only to delimit the keywords itemBlock // block keyword itemBreak // break keyword itemContinue // continue keyword itemDot // the cursor, spelled '.' itemDefine // define keyword itemElse // else keyword itemEnd // end keyword itemIf // if keyword itemNil // the untyped nil constant, easiest to treat as a keyword itemRange // range keyword itemTemplate // template keyword itemWith // with keyword ) var key = map[string]itemType{ ".": itemDot, "block": itemBlock, "break": itemBreak, "continue": itemContinue, "define": itemDefine, "else": itemElse, "end": itemEnd, "if": itemIf, "range": itemRange, "nil": itemNil, "template": itemTemplate, "with": itemWith, } const eof = -1 // Trimming spaces. // If the action begins "{{- " rather than "{{", then all space/tab/newlines // preceding the action are trimmed; conversely if it ends " -}}" the // leading spaces are trimmed. This is done entirely in the lexer; the // parser never sees it happen. We require an ASCII space (' ', \t, \r, \n) // to be present to avoid ambiguity with things like "{{-3}}". It reads // better with the space present anyway. For simplicity, only ASCII // does the job. const ( spaceChars = " \t\r\n" // These are the space characters defined by Go itself. trimMarker = '-' // Attached to left/right delimiter, trims trailing spaces from preceding/following text. trimMarkerLen = Pos(1 + 1) // marker plus space before or after ) // stateFn represents the state of the scanner as a function that returns the next state. type stateFn func(*lexer) stateFn // lexer holds the state of the scanner. type lexer struct { name string // the name of the input; used only for error reports input string // the string being scanned leftDelim string // start of action marker rightDelim string // end of action marker pos Pos // current position in the input start Pos // start position of this item atEOF bool // we have hit the end of input and returned eof parenDepth int // nesting depth of ( ) exprs line int // 1+number of newlines seen startLine int // start line of this item item item // item to return to parser insideAction bool // are we inside an action? options lexOptions } // lexOptions control behavior of the lexer. All default to false. type lexOptions struct { emitComment bool // emit itemComment tokens. breakOK bool // break keyword allowed continueOK bool // continue keyword allowed } // next returns the next rune in the input. func (l *lexer) next() rune { if int(l.pos) >= len(l.input) { l.atEOF = true return eof } r, w := utf8.DecodeRuneInString(l.input[l.pos:]) l.pos += Pos(w) if r == '\n' { l.line++ } return r } // peek returns but does not consume the next rune in the input. func (l *lexer) peek() rune { r := l.next() l.backup() return r } // backup steps back one rune. func (l *lexer) backup() { if !l.atEOF && l.pos > 0 { r, w := utf8.DecodeLastRuneInString(l.input[:l.pos]) l.pos -= Pos(w) // Correct newline count. if r == '\n' { l.line-- } } } // thisItem returns the item at the current input point with the specified type // and advances the input. func (l *lexer) thisItem(t itemType) item { i := item{t, l.start, l.input[l.start:l.pos], l.startLine} l.start = l.pos l.startLine = l.line return i } // emit passes the trailing text as an item back to the parser. func (l *lexer) emit(t itemType) stateFn { return l.emitItem(l.thisItem(t)) } // emitItem passes the specified item to the parser. func (l *lexer) emitItem(i item) stateFn { l.item = i return nil } // ignore skips over the pending input before this point. // It tracks newlines in the ignored text, so use it only // for text that is skipped without calling l.next. func (l *lexer) ignore() { l.line += strings.Count(l.input[l.start:l.pos], "\n") l.start = l.pos l.startLine = l.line } // accept consumes the next rune if it's from the valid set. func (l *lexer) accept(valid string) bool { if strings.ContainsRune(valid, l.next()) { return true } l.backup() return false } // acceptRun consumes a run of runes from the valid set. func (l *lexer) acceptRun(valid string) { for strings.ContainsRune(valid, l.next()) { } l.backup() } // errorf returns an error token and terminates the scan by passing // back a nil pointer that will be the next state, terminating l.nextItem. func (l *lexer) errorf(format string, args ...any) stateFn { l.item = item{itemError, l.start, fmt.Sprintf(format, args...), l.startLine} l.start = 0 l.pos = 0 l.input = l.input[:0] return nil } // nextItem returns the next item from the input. // Called by the parser, not in the lexing goroutine. func (l *lexer) nextItem() item { l.item = item{itemEOF, l.pos, "EOF", l.startLine} state := lexText if l.insideAction { state = lexInsideAction } for { state = state(l) if state == nil { return l.item } } } // lex creates a new scanner for the input string. func lex(name, input, left, right string) *lexer { if left == "" { left = leftDelim } if right == "" { right = rightDelim } l := &lexer{ name: name, input: input, leftDelim: left, rightDelim: right, line: 1, startLine: 1, insideAction: false, } return l } // state functions const ( leftDelim = "{{" rightDelim = "}}" leftComment = "/*" rightComment = "*/" ) // lexText scans until an opening action delimiter, "{{". func lexText(l *lexer) stateFn { if x := strings.Index(l.input[l.pos:], l.leftDelim); x >= 0 { if x > 0 { l.pos += Pos(x) // Do we trim any trailing space? trimLength := Pos(0) delimEnd := l.pos + Pos(len(l.leftDelim)) if hasLeftTrimMarker(l.input[delimEnd:]) { trimLength = rightTrimLength(l.input[l.start:l.pos]) } l.pos -= trimLength l.line += strings.Count(l.input[l.start:l.pos], "\n") i := l.thisItem(itemText) l.pos += trimLength l.ignore() if len(i.val) > 0 { return l.emitItem(i) } } return lexLeftDelim } l.pos = Pos(len(l.input)) // Correctly reached EOF. if l.pos > l.start { l.line += strings.Count(l.input[l.start:l.pos], "\n") return l.emit(itemText) } return l.emit(itemEOF) } // rightTrimLength returns the length of the spaces at the end of the string. func rightTrimLength(s string) Pos { return Pos(len(s) - len(strings.TrimRight(s, spaceChars))) } // atRightDelim reports whether the lexer is at a right delimiter, possibly preceded by a trim marker. func (l *lexer) atRightDelim() (delim, trimSpaces bool) { if hasRightTrimMarker(l.input[l.pos:]) && strings.HasPrefix(l.input[l.pos+trimMarkerLen:], l.rightDelim) { // With trim marker. return true, true } if strings.HasPrefix(l.input[l.pos:], l.rightDelim) { // Without trim marker. return true, false } return false, false } // leftTrimLength returns the length of the spaces at the beginning of the string. func leftTrimLength(s string) Pos { return Pos(len(s) - len(strings.TrimLeft(s, spaceChars))) } // lexLeftDelim scans the left delimiter, which is known to be present, possibly with a trim marker. // (The text to be trimmed has already been emitted.) func lexLeftDelim(l *lexer) stateFn { l.pos += Pos(len(l.leftDelim)) trimSpace := hasLeftTrimMarker(l.input[l.pos:]) afterMarker := Pos(0) if trimSpace { afterMarker = trimMarkerLen } if strings.HasPrefix(l.input[l.pos+afterMarker:], leftComment) { l.pos += afterMarker l.ignore() return lexComment } i := l.thisItem(itemLeftDelim) l.insideAction = true l.pos += afterMarker l.ignore() l.parenDepth = 0 return l.emitItem(i) } // lexComment scans a comment. The left comment marker is known to be present. func lexComment(l *lexer) stateFn { l.pos += Pos(len(leftComment)) x := strings.Index(l.input[l.pos:], rightComment) if x < 0 { return l.errorf("unclosed comment") } l.pos += Pos(x + len(rightComment)) delim, trimSpace := l.atRightDelim() if !delim { return l.errorf("comment ends before closing delimiter") } l.line += strings.Count(l.input[l.start:l.pos], "\n") i := l.thisItem(itemComment) if trimSpace { l.pos += trimMarkerLen } l.pos += Pos(len(l.rightDelim)) if trimSpace { l.pos += leftTrimLength(l.input[l.pos:]) } l.ignore() if l.options.emitComment { return l.emitItem(i) } return lexText } // lexRightDelim scans the right delimiter, which is known to be present, possibly with a trim marker. func lexRightDelim(l *lexer) stateFn { _, trimSpace := l.atRightDelim() if trimSpace { l.pos += trimMarkerLen l.ignore() } l.pos += Pos(len(l.rightDelim)) i := l.thisItem(itemRightDelim) if trimSpace { l.pos += leftTrimLength(l.input[l.pos:]) l.ignore() } l.insideAction = false return l.emitItem(i) } // lexInsideAction scans the elements inside action delimiters. func lexInsideAction(l *lexer) stateFn { // Either number, quoted string, or identifier. // Spaces separate arguments; runs of spaces turn into itemSpace. // Pipe symbols separate and are emitted. delim, _ := l.atRightDelim() if delim { if l.parenDepth == 0 { return lexRightDelim } return l.errorf("unclosed left paren") } switch r := l.next(); { case r == eof: return l.errorf("unclosed action") case isSpace(r): l.backup() // Put space back in case we have " -}}". return lexSpace case r == '=': return l.emit(itemAssign) case r == ':': if l.next() != '=' { return l.errorf("expected :=") } return l.emit(itemDeclare) case r == '|': return l.emit(itemPipe) case r == '"': return lexQuote case r == '`': return lexRawQuote case r == '$': return lexVariable case r == '\'': return lexChar case r == '.': // special look-ahead for ".field" so we don't break l.backup(). if l.pos < Pos(len(l.input)) { r := l.input[l.pos] if r < '0' || '9' < r { return lexField } } fallthrough // '.' can start a number. case r == '+' || r == '-' || ('0' <= r && r <= '9'): l.backup() return lexNumber case isAlphaNumeric(r): l.backup() return lexIdentifier case r == '(': l.parenDepth++ return l.emit(itemLeftParen) case r == ')': l.parenDepth-- if l.parenDepth < 0 { return l.errorf("unexpected right paren") } return l.emit(itemRightParen) case r <= unicode.MaxASCII && unicode.IsPrint(r): return l.emit(itemChar) default: return l.errorf("unrecognized character in action: %#U", r) } } // lexSpace scans a run of space characters. // We have not consumed the first space, which is known to be present. // Take care if there is a trim-marked right delimiter, which starts with a space. func lexSpace(l *lexer) stateFn { var r rune var numSpaces int for { r = l.peek() if !isSpace(r) { break } l.next() numSpaces++ } // Be careful about a trim-marked closing delimiter, which has a minus // after a space. We know there is a space, so check for the '-' that might follow. if hasRightTrimMarker(l.input[l.pos-1:]) && strings.HasPrefix(l.input[l.pos-1+trimMarkerLen:], l.rightDelim) { l.backup() // Before the space. if numSpaces == 1 { return lexRightDelim // On the delim, so go right to that. } } return l.emit(itemSpace) } // lexIdentifier scans an alphanumeric. func lexIdentifier(l *lexer) stateFn { for { switch r := l.next(); { case isAlphaNumeric(r): // absorb. default: l.backup() word := l.input[l.start:l.pos] if !l.atTerminator() { return l.errorf("bad character %#U", r) } switch { case key[word] > itemKeyword: item := key[word] if item == itemBreak && !l.options.breakOK || item == itemContinue && !l.options.continueOK { return l.emit(itemIdentifier) } return l.emit(item) case word[0] == '.': return l.emit(itemField) case word == "true", word == "false": return l.emit(itemBool) default: return l.emit(itemIdentifier) } } } } // lexField scans a field: .Alphanumeric. // The . has been scanned. func lexField(l *lexer) stateFn { return lexFieldOrVariable(l, itemField) } // lexVariable scans a Variable: $Alphanumeric. // The $ has been scanned. func lexVariable(l *lexer) stateFn { if l.atTerminator() { // Nothing interesting follows -> "$". return l.emit(itemVariable) } return lexFieldOrVariable(l, itemVariable) } // lexFieldOrVariable scans a field or variable: [.$]Alphanumeric. // The . or $ has been scanned. func lexFieldOrVariable(l *lexer, typ itemType) stateFn { if l.atTerminator() { // Nothing interesting follows -> "." or "$". if typ == itemVariable { return l.emit(itemVariable) } return l.emit(itemDot) } var r rune for { r = l.next() if !isAlphaNumeric(r) { l.backup() break } } if !l.atTerminator() { return l.errorf("bad character %#U", r) } return l.emit(typ) } // atTerminator reports whether the input is at valid termination character to // appear after an identifier. Breaks .X.Y into two pieces. Also catches cases // like "$x+2" not being acceptable without a space, in case we decide one // day to implement arithmetic. func (l *lexer) atTerminator() bool { r := l.peek() if isSpace(r) { return true } switch r { case eof, '.', ',', '|', ':', ')', '(': return true } return strings.HasPrefix(l.input[l.pos:], l.rightDelim) } // lexChar scans a character constant. The initial quote is already // scanned. Syntax checking is done by the parser. func lexChar(l *lexer) stateFn { Loop: for { switch l.next() { case '\\': if r := l.next(); r != eof && r != '\n' { break } fallthrough case eof, '\n': return l.errorf("unterminated character constant") case '\'': break Loop } } return l.emit(itemCharConstant) } // lexNumber scans a number: decimal, octal, hex, float, or imaginary. This // isn't a perfect number scanner - for instance it accepts "." and "0x0.2" // and "089" - but when it's wrong the input is invalid and the parser (via // strconv) will notice. func lexNumber(l *lexer) stateFn { if !l.scanNumber() { return l.errorf("bad number syntax: %q", l.input[l.start:l.pos]) } if sign := l.peek(); sign == '+' || sign == '-' { // Complex: 1+2i. No spaces, must end in 'i'. if !l.scanNumber() || l.input[l.pos-1] != 'i' { return l.errorf("bad number syntax: %q", l.input[l.start:l.pos]) } return l.emit(itemComplex) } return l.emit(itemNumber) } func (l *lexer) scanNumber() bool { // Optional leading sign. l.accept("+-") // Is it hex? digits := "0123456789_" if l.accept("0") { // Note: Leading 0 does not mean octal in floats. if l.accept("xX") { digits = "0123456789abcdefABCDEF_" } else if l.accept("oO") { digits = "01234567_" } else if l.accept("bB") { digits = "01_" } } l.acceptRun(digits) if l.accept(".") { l.acceptRun(digits) } if len(digits) == 10+1 && l.accept("eE") { l.accept("+-") l.acceptRun("0123456789_") } if len(digits) == 16+6+1 && l.accept("pP") { l.accept("+-") l.acceptRun("0123456789_") } // Is it imaginary? l.accept("i") // Next thing mustn't be alphanumeric. if isAlphaNumeric(l.peek()) { l.next() return false } return true } // lexQuote scans a quoted string. func lexQuote(l *lexer) stateFn { Loop: for { switch l.next() { case '\\': if r := l.next(); r != eof && r != '\n' { break } fallthrough case eof, '\n': return l.errorf("unterminated quoted string") case '"': break Loop } } return l.emit(itemString) } // lexRawQuote scans a raw quoted string. func lexRawQuote(l *lexer) stateFn { Loop: for { switch l.next() { case eof: return l.errorf("unterminated raw quoted string") case '`': break Loop } } return l.emit(itemRawString) } // isSpace reports whether r is a space character. func isSpace(r rune) bool { return r == ' ' || r == '\t' || r == '\r' || r == '\n' } // isAlphaNumeric reports whether r is an alphabetic, digit, or underscore. func isAlphaNumeric(r rune) bool { return r == '_' || unicode.IsLetter(r) || unicode.IsDigit(r) } func hasLeftTrimMarker(s string) bool { return len(s) >= 2 && s[0] == trimMarker && isSpace(rune(s[1])) } func hasRightTrimMarker(s string) bool { return len(s) >= 2 && isSpace(rune(s[0])) && s[1] == trimMarker }