package goja import ( "github.com/dop251/goja/unistring" "math" "strings" "unicode/utf16" "unicode/utf8" "github.com/dop251/goja/parser" "golang.org/x/text/collate" "golang.org/x/text/language" "golang.org/x/text/unicode/norm" ) func (r *Runtime) collator() *collate.Collator { collator := r._collator if collator == nil { collator = collate.New(language.Und) r._collator = collator } return collator } func toString(arg Value) valueString { if s, ok := arg.(valueString); ok { return s } if s, ok := arg.(*Symbol); ok { return s.descriptiveString() } return arg.toString() } func (r *Runtime) builtin_String(call FunctionCall) Value { if len(call.Arguments) > 0 { return toString(call.Arguments[0]) } else { return stringEmpty } } func (r *Runtime) _newString(s valueString, proto *Object) *Object { v := &Object{runtime: r} o := &stringObject{} o.class = classString o.val = v o.extensible = true v.self = o o.prototype = proto if s != nil { o.value = s } o.init() return v } func (r *Runtime) builtin_newString(args []Value, proto *Object) *Object { var s valueString if len(args) > 0 { s = args[0].toString() } else { s = stringEmpty } return r._newString(s, proto) } func (r *Runtime) stringproto_toStringValueOf(this Value, funcName string) Value { if str, ok := this.(valueString); ok { return str } if obj, ok := this.(*Object); ok { if strObj, ok := obj.self.(*stringObject); ok { return strObj.value } } r.typeErrorResult(true, "String.prototype.%s is called on incompatible receiver", funcName) return nil } func (r *Runtime) stringproto_toString(call FunctionCall) Value { return r.stringproto_toStringValueOf(call.This, "toString") } func (r *Runtime) stringproto_valueOf(call FunctionCall) Value { return r.stringproto_toStringValueOf(call.This, "valueOf") } func (r *Runtime) stringproto_iterator(call FunctionCall) Value { r.checkObjectCoercible(call.This) return r.createStringIterator(call.This.toString()) } func (r *Runtime) string_fromcharcode(call FunctionCall) Value { b := make([]byte, len(call.Arguments)) for i, arg := range call.Arguments { chr := toUint16(arg) if chr >= utf8.RuneSelf { bb := make([]uint16, len(call.Arguments)+1) bb[0] = unistring.BOM bb1 := bb[1:] for j := 0; j < i; j++ { bb1[j] = uint16(b[j]) } bb1[i] = chr i++ for j, arg := range call.Arguments[i:] { bb1[i+j] = toUint16(arg) } return unicodeString(bb) } b[i] = byte(chr) } return asciiString(b) } func (r *Runtime) string_fromcodepoint(call FunctionCall) Value { var sb valueStringBuilder for _, arg := range call.Arguments { num := arg.ToNumber() var c rune if numInt, ok := num.(valueInt); ok { if numInt < 0 || numInt > utf8.MaxRune { panic(r.newError(r.global.RangeError, "Invalid code point %d", numInt)) } c = rune(numInt) } else { panic(r.newError(r.global.RangeError, "Invalid code point %s", num)) } sb.WriteRune(c) } return sb.String() } func (r *Runtime) string_raw(call FunctionCall) Value { cooked := call.Argument(0).ToObject(r) raw := nilSafe(cooked.self.getStr("raw", nil)).ToObject(r) literalSegments := toLength(raw.self.getStr("length", nil)) if literalSegments <= 0 { return stringEmpty } var stringElements valueStringBuilder nextIndex := int64(0) numberOfSubstitutions := int64(len(call.Arguments) - 1) for { nextSeg := nilSafe(raw.self.getIdx(valueInt(nextIndex), nil)).toString() stringElements.WriteString(nextSeg) if nextIndex+1 == literalSegments { return stringElements.String() } if nextIndex < numberOfSubstitutions { stringElements.WriteString(nilSafe(call.Arguments[nextIndex+1]).toString()) } nextIndex++ } } func (r *Runtime) stringproto_charAt(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() pos := call.Argument(0).ToInteger() if pos < 0 || pos >= int64(s.length()) { return stringEmpty } return newStringValue(string(s.charAt(toIntStrict(pos)))) } func (r *Runtime) stringproto_charCodeAt(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() pos := call.Argument(0).ToInteger() if pos < 0 || pos >= int64(s.length()) { return _NaN } return intToValue(int64(s.charAt(toIntStrict(pos)) & 0xFFFF)) } func (r *Runtime) stringproto_codePointAt(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() p := call.Argument(0).ToInteger() size := s.length() if p < 0 || p >= int64(size) { return _undefined } pos := toIntStrict(p) first := s.charAt(pos) if isUTF16FirstSurrogate(first) { pos++ if pos < size { second := s.charAt(pos) if isUTF16SecondSurrogate(second) { return intToValue(int64(utf16.DecodeRune(first, second))) } } } return intToValue(int64(first & 0xFFFF)) } func (r *Runtime) stringproto_concat(call FunctionCall) Value { r.checkObjectCoercible(call.This) strs := make([]valueString, len(call.Arguments)+1) strs[0] = call.This.toString() _, allAscii := strs[0].(asciiString) totalLen := strs[0].length() for i, arg := range call.Arguments { s := arg.toString() if allAscii { _, allAscii = s.(asciiString) } strs[i+1] = s totalLen += s.length() } if allAscii { var buf strings.Builder buf.Grow(totalLen) for _, s := range strs { buf.WriteString(s.String()) } return asciiString(buf.String()) } else { buf := make([]uint16, totalLen+1) buf[0] = unistring.BOM pos := 1 for _, s := range strs { switch s := s.(type) { case asciiString: for i := 0; i < len(s); i++ { buf[pos] = uint16(s[i]) pos++ } case unicodeString: copy(buf[pos:], s[1:]) pos += s.length() } } return unicodeString(buf) } } func (r *Runtime) stringproto_endsWith(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() searchString := call.Argument(0) if isRegexp(searchString) { panic(r.NewTypeError("First argument to String.prototype.endsWith must not be a regular expression")) } searchStr := searchString.toString() l := int64(s.length()) var pos int64 if posArg := call.Argument(1); posArg != _undefined { pos = posArg.ToInteger() } else { pos = l } end := toIntStrict(min(max(pos, 0), l)) searchLength := searchStr.length() start := end - searchLength if start < 0 { return valueFalse } for i := 0; i < searchLength; i++ { if s.charAt(start+i) != searchStr.charAt(i) { return valueFalse } } return valueTrue } func (r *Runtime) stringproto_includes(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() searchString := call.Argument(0) if isRegexp(searchString) { panic(r.NewTypeError("First argument to String.prototype.includes must not be a regular expression")) } searchStr := searchString.toString() var pos int64 if posArg := call.Argument(1); posArg != _undefined { pos = posArg.ToInteger() } else { pos = 0 } start := toIntStrict(min(max(pos, 0), int64(s.length()))) if s.index(searchStr, start) != -1 { return valueTrue } return valueFalse } func (r *Runtime) stringproto_indexOf(call FunctionCall) Value { r.checkObjectCoercible(call.This) value := call.This.toString() target := call.Argument(0).toString() pos := call.Argument(1).ToInteger() if pos < 0 { pos = 0 } else { l := int64(value.length()) if pos > l { pos = l } } return intToValue(int64(value.index(target, toIntStrict(pos)))) } func (r *Runtime) stringproto_lastIndexOf(call FunctionCall) Value { r.checkObjectCoercible(call.This) value := call.This.toString() target := call.Argument(0).toString() numPos := call.Argument(1).ToNumber() var pos int64 if f, ok := numPos.(valueFloat); ok && math.IsNaN(float64(f)) { pos = int64(value.length()) } else { pos = numPos.ToInteger() if pos < 0 { pos = 0 } else { l := int64(value.length()) if pos > l { pos = l } } } return intToValue(int64(value.lastIndex(target, toIntStrict(pos)))) } func (r *Runtime) stringproto_localeCompare(call FunctionCall) Value { r.checkObjectCoercible(call.This) this := norm.NFD.String(call.This.toString().String()) that := norm.NFD.String(call.Argument(0).toString().String()) return intToValue(int64(r.collator().CompareString(this, that))) } func (r *Runtime) stringproto_match(call FunctionCall) Value { r.checkObjectCoercible(call.This) regexp := call.Argument(0) if regexp != _undefined && regexp != _null { if matcher := toMethod(r.getV(regexp, SymMatch)); matcher != nil { return matcher(FunctionCall{ This: regexp, Arguments: []Value{call.This}, }) } } var rx *regexpObject if regexp, ok := regexp.(*Object); ok { rx, _ = regexp.self.(*regexpObject) } if rx == nil { rx = r.newRegExp(regexp, nil, r.global.RegExpPrototype) } if matcher, ok := r.toObject(rx.getSym(SymMatch, nil)).self.assertCallable(); ok { return matcher(FunctionCall{ This: rx.val, Arguments: []Value{call.This.toString()}, }) } panic(r.NewTypeError("RegExp matcher is not a function")) } func (r *Runtime) stringproto_matchAll(call FunctionCall) Value { r.checkObjectCoercible(call.This) regexp := call.Argument(0) if regexp != _undefined && regexp != _null { if isRegexp(regexp) { if o, ok := regexp.(*Object); ok { flags := nilSafe(o.self.getStr("flags", nil)) r.checkObjectCoercible(flags) if !strings.Contains(flags.toString().String(), "g") { panic(r.NewTypeError("RegExp doesn't have global flag set")) } } } if matcher := toMethod(r.getV(regexp, SymMatchAll)); matcher != nil { return matcher(FunctionCall{ This: regexp, Arguments: []Value{call.This}, }) } } rx := r.newRegExp(regexp, asciiString("g"), r.global.RegExpPrototype) if matcher, ok := r.toObject(rx.getSym(SymMatchAll, nil)).self.assertCallable(); ok { return matcher(FunctionCall{ This: rx.val, Arguments: []Value{call.This.toString()}, }) } panic(r.NewTypeError("RegExp matcher is not a function")) } func (r *Runtime) stringproto_normalize(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() var form string if formArg := call.Argument(0); formArg != _undefined { form = formArg.toString().toString().String() } else { form = "NFC" } var f norm.Form switch form { case "NFC": f = norm.NFC case "NFD": f = norm.NFD case "NFKC": f = norm.NFKC case "NFKD": f = norm.NFKD default: panic(r.newError(r.global.RangeError, "The normalization form should be one of NFC, NFD, NFKC, NFKD")) } if s, ok := s.(unicodeString); ok { ss := s.String() return newStringValue(f.String(ss)) } return s } func (r *Runtime) stringproto_padEnd(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() maxLength := toLength(call.Argument(0)) stringLength := int64(s.length()) if maxLength <= stringLength { return s } var filler valueString var fillerASCII bool if fillString := call.Argument(1); fillString != _undefined { filler = fillString.toString() if filler.length() == 0 { return s } _, fillerASCII = filler.(asciiString) } else { filler = asciiString(" ") fillerASCII = true } remaining := toIntStrict(maxLength - stringLength) _, stringASCII := s.(asciiString) if fillerASCII && stringASCII { fl := filler.length() var sb strings.Builder sb.Grow(toIntStrict(maxLength)) sb.WriteString(s.String()) fs := filler.String() for remaining >= fl { sb.WriteString(fs) remaining -= fl } if remaining > 0 { sb.WriteString(fs[:remaining]) } return asciiString(sb.String()) } var sb unicodeStringBuilder sb.Grow(toIntStrict(maxLength)) sb.WriteString(s) fl := filler.length() for remaining >= fl { sb.WriteString(filler) remaining -= fl } if remaining > 0 { sb.WriteString(filler.substring(0, remaining)) } return sb.String() } func (r *Runtime) stringproto_padStart(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() maxLength := toLength(call.Argument(0)) stringLength := int64(s.length()) if maxLength <= stringLength { return s } var filler valueString var fillerASCII bool if fillString := call.Argument(1); fillString != _undefined { filler = fillString.toString() if filler.length() == 0 { return s } _, fillerASCII = filler.(asciiString) } else { filler = asciiString(" ") fillerASCII = true } remaining := toIntStrict(maxLength - stringLength) _, stringASCII := s.(asciiString) if fillerASCII && stringASCII { fl := filler.length() var sb strings.Builder sb.Grow(toIntStrict(maxLength)) fs := filler.String() for remaining >= fl { sb.WriteString(fs) remaining -= fl } if remaining > 0 { sb.WriteString(fs[:remaining]) } sb.WriteString(s.String()) return asciiString(sb.String()) } var sb unicodeStringBuilder sb.Grow(toIntStrict(maxLength)) fl := filler.length() for remaining >= fl { sb.WriteString(filler) remaining -= fl } if remaining > 0 { sb.WriteString(filler.substring(0, remaining)) } sb.WriteString(s) return sb.String() } func (r *Runtime) stringproto_repeat(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() n := call.Argument(0).ToNumber() if n == _positiveInf { panic(r.newError(r.global.RangeError, "Invalid count value")) } numInt := n.ToInteger() if numInt < 0 { panic(r.newError(r.global.RangeError, "Invalid count value")) } if numInt == 0 || s.length() == 0 { return stringEmpty } num := toIntStrict(numInt) if s, ok := s.(asciiString); ok { var sb strings.Builder sb.Grow(len(s) * num) for i := 0; i < num; i++ { sb.WriteString(string(s)) } return asciiString(sb.String()) } var sb unicodeStringBuilder sb.Grow(s.length() * num) for i := 0; i < num; i++ { sb.WriteString(s) } return sb.String() } func getReplaceValue(replaceValue Value) (str valueString, rcall func(FunctionCall) Value) { if replaceValue, ok := replaceValue.(*Object); ok { if c, ok := replaceValue.self.assertCallable(); ok { rcall = c return } } str = replaceValue.toString() return } func stringReplace(s valueString, found [][]int, newstring valueString, rcall func(FunctionCall) Value) Value { if len(found) == 0 { return s } var str string var isASCII bool if astr, ok := s.(asciiString); ok { str = string(astr) isASCII = true } var buf valueStringBuilder lastIndex := 0 lengthS := s.length() if rcall != nil { for _, item := range found { if item[0] != lastIndex { buf.WriteSubstring(s, lastIndex, item[0]) } matchCount := len(item) / 2 argumentList := make([]Value, matchCount+2) for index := 0; index < matchCount; index++ { offset := 2 * index if item[offset] != -1 { if isASCII { argumentList[index] = asciiString(str[item[offset]:item[offset+1]]) } else { argumentList[index] = s.substring(item[offset], item[offset+1]) } } else { argumentList[index] = _undefined } } argumentList[matchCount] = valueInt(item[0]) argumentList[matchCount+1] = s replacement := rcall(FunctionCall{ This: _undefined, Arguments: argumentList, }).toString() buf.WriteString(replacement) lastIndex = item[1] } } else { for _, item := range found { if item[0] != lastIndex { buf.WriteString(s.substring(lastIndex, item[0])) } matchCount := len(item) / 2 writeSubstitution(s, item[0], matchCount, func(idx int) valueString { if item[idx*2] != -1 { if isASCII { return asciiString(str[item[idx*2]:item[idx*2+1]]) } return s.substring(item[idx*2], item[idx*2+1]) } return stringEmpty }, newstring, &buf) lastIndex = item[1] } } if lastIndex != lengthS { buf.WriteString(s.substring(lastIndex, lengthS)) } return buf.String() } func (r *Runtime) stringproto_replace(call FunctionCall) Value { r.checkObjectCoercible(call.This) searchValue := call.Argument(0) replaceValue := call.Argument(1) if searchValue != _undefined && searchValue != _null { if replacer := toMethod(r.getV(searchValue, SymReplace)); replacer != nil { return replacer(FunctionCall{ This: searchValue, Arguments: []Value{call.This, replaceValue}, }) } } s := call.This.toString() var found [][]int searchStr := searchValue.toString() pos := s.index(searchStr, 0) if pos != -1 { found = append(found, []int{pos, pos + searchStr.length()}) } str, rcall := getReplaceValue(replaceValue) return stringReplace(s, found, str, rcall) } func (r *Runtime) stringproto_search(call FunctionCall) Value { r.checkObjectCoercible(call.This) regexp := call.Argument(0) if regexp != _undefined && regexp != _null { if searcher := toMethod(r.getV(regexp, SymSearch)); searcher != nil { return searcher(FunctionCall{ This: regexp, Arguments: []Value{call.This}, }) } } var rx *regexpObject if regexp, ok := regexp.(*Object); ok { rx, _ = regexp.self.(*regexpObject) } if rx == nil { rx = r.newRegExp(regexp, nil, r.global.RegExpPrototype) } if searcher, ok := r.toObject(rx.getSym(SymSearch, nil)).self.assertCallable(); ok { return searcher(FunctionCall{ This: rx.val, Arguments: []Value{call.This.toString()}, }) } panic(r.NewTypeError("RegExp searcher is not a function")) } func (r *Runtime) stringproto_slice(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() l := int64(s.length()) start := call.Argument(0).ToInteger() var end int64 if arg1 := call.Argument(1); arg1 != _undefined { end = arg1.ToInteger() } else { end = l } if start < 0 { start += l if start < 0 { start = 0 } } else { if start > l { start = l } } if end < 0 { end += l if end < 0 { end = 0 } } else { if end > l { end = l } } if end > start { return s.substring(int(start), int(end)) } return stringEmpty } func (r *Runtime) stringproto_split(call FunctionCall) Value { r.checkObjectCoercible(call.This) separatorValue := call.Argument(0) limitValue := call.Argument(1) if separatorValue != _undefined && separatorValue != _null { if splitter := toMethod(r.getV(separatorValue, SymSplit)); splitter != nil { return splitter(FunctionCall{ This: separatorValue, Arguments: []Value{call.This, limitValue}, }) } } s := call.This.toString() limit := -1 if limitValue != _undefined { limit = int(toUint32(limitValue)) } separatorValue = separatorValue.ToString() if limit == 0 { return r.newArrayValues(nil) } if separatorValue == _undefined { return r.newArrayValues([]Value{s}) } separator := separatorValue.String() excess := false str := s.String() if limit > len(str) { limit = len(str) } splitLimit := limit if limit > 0 { splitLimit = limit + 1 excess = true } // TODO handle invalid UTF-16 split := strings.SplitN(str, separator, splitLimit) if excess && len(split) > limit { split = split[:limit] } valueArray := make([]Value, len(split)) for index, value := range split { valueArray[index] = newStringValue(value) } return r.newArrayValues(valueArray) } func (r *Runtime) stringproto_startsWith(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() searchString := call.Argument(0) if isRegexp(searchString) { panic(r.NewTypeError("First argument to String.prototype.startsWith must not be a regular expression")) } searchStr := searchString.toString() l := int64(s.length()) var pos int64 if posArg := call.Argument(1); posArg != _undefined { pos = posArg.ToInteger() } start := toIntStrict(min(max(pos, 0), l)) searchLength := searchStr.length() if int64(searchLength+start) > l { return valueFalse } for i := 0; i < searchLength; i++ { if s.charAt(start+i) != searchStr.charAt(i) { return valueFalse } } return valueTrue } func (r *Runtime) stringproto_substring(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() l := int64(s.length()) intStart := call.Argument(0).ToInteger() var intEnd int64 if end := call.Argument(1); end != _undefined { intEnd = end.ToInteger() } else { intEnd = l } if intStart < 0 { intStart = 0 } else if intStart > l { intStart = l } if intEnd < 0 { intEnd = 0 } else if intEnd > l { intEnd = l } if intStart > intEnd { intStart, intEnd = intEnd, intStart } return s.substring(int(intStart), int(intEnd)) } func (r *Runtime) stringproto_toLowerCase(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() return s.toLower() } func (r *Runtime) stringproto_toUpperCase(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() return s.toUpper() } func (r *Runtime) stringproto_trim(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() // TODO handle invalid UTF-16 return newStringValue(strings.Trim(s.String(), parser.WhitespaceChars)) } func (r *Runtime) stringproto_trimEnd(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() // TODO handle invalid UTF-16 return newStringValue(strings.TrimRight(s.String(), parser.WhitespaceChars)) } func (r *Runtime) stringproto_trimStart(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() // TODO handle invalid UTF-16 return newStringValue(strings.TrimLeft(s.String(), parser.WhitespaceChars)) } func (r *Runtime) stringproto_substr(call FunctionCall) Value { r.checkObjectCoercible(call.This) s := call.This.toString() start := call.Argument(0).ToInteger() var length int64 sl := int64(s.length()) if arg := call.Argument(1); arg != _undefined { length = arg.ToInteger() } else { length = sl } if start < 0 { start = max(sl+start, 0) } length = min(max(length, 0), sl-start) if length <= 0 { return stringEmpty } return s.substring(int(start), int(start+length)) } func (r *Runtime) stringIterProto_next(call FunctionCall) Value { thisObj := r.toObject(call.This) if iter, ok := thisObj.self.(*stringIterObject); ok { return iter.next() } panic(r.NewTypeError("Method String Iterator.prototype.next called on incompatible receiver %s", thisObj.String())) } func (r *Runtime) createStringIterProto(val *Object) objectImpl { o := newBaseObjectObj(val, r.global.IteratorPrototype, classObject) o._putProp("next", r.newNativeFunc(r.stringIterProto_next, nil, "next", nil, 0), true, false, true) o._putSym(SymToStringTag, valueProp(asciiString(classStringIterator), false, false, true)) return o } func (r *Runtime) initString() { r.global.StringIteratorPrototype = r.newLazyObject(r.createStringIterProto) r.global.StringPrototype = r.builtin_newString([]Value{stringEmpty}, r.global.ObjectPrototype) o := r.global.StringPrototype.self o._putProp("charAt", r.newNativeFunc(r.stringproto_charAt, nil, "charAt", nil, 1), true, false, true) o._putProp("charCodeAt", r.newNativeFunc(r.stringproto_charCodeAt, nil, "charCodeAt", nil, 1), true, false, true) o._putProp("codePointAt", r.newNativeFunc(r.stringproto_codePointAt, nil, "codePointAt", nil, 1), true, false, true) o._putProp("concat", r.newNativeFunc(r.stringproto_concat, nil, "concat", nil, 1), true, false, true) o._putProp("endsWith", r.newNativeFunc(r.stringproto_endsWith, nil, "endsWith", nil, 1), true, false, true) o._putProp("includes", r.newNativeFunc(r.stringproto_includes, nil, "includes", nil, 1), true, false, true) o._putProp("indexOf", r.newNativeFunc(r.stringproto_indexOf, nil, "indexOf", nil, 1), true, false, true) o._putProp("lastIndexOf", r.newNativeFunc(r.stringproto_lastIndexOf, nil, "lastIndexOf", nil, 1), true, false, true) o._putProp("localeCompare", r.newNativeFunc(r.stringproto_localeCompare, nil, "localeCompare", nil, 1), true, false, true) o._putProp("match", r.newNativeFunc(r.stringproto_match, nil, "match", nil, 1), true, false, true) o._putProp("matchAll", r.newNativeFunc(r.stringproto_matchAll, nil, "matchAll", nil, 1), true, false, true) o._putProp("normalize", r.newNativeFunc(r.stringproto_normalize, nil, "normalize", nil, 0), true, false, true) o._putProp("padEnd", r.newNativeFunc(r.stringproto_padEnd, nil, "padEnd", nil, 1), true, false, true) o._putProp("padStart", r.newNativeFunc(r.stringproto_padStart, nil, "padStart", nil, 1), true, false, true) o._putProp("repeat", r.newNativeFunc(r.stringproto_repeat, nil, "repeat", nil, 1), true, false, true) o._putProp("replace", r.newNativeFunc(r.stringproto_replace, nil, "replace", nil, 2), true, false, true) o._putProp("search", r.newNativeFunc(r.stringproto_search, nil, "search", nil, 1), true, false, true) o._putProp("slice", r.newNativeFunc(r.stringproto_slice, nil, "slice", nil, 2), true, false, true) o._putProp("split", r.newNativeFunc(r.stringproto_split, nil, "split", nil, 2), true, false, true) o._putProp("startsWith", r.newNativeFunc(r.stringproto_startsWith, nil, "startsWith", nil, 1), true, false, true) o._putProp("substring", r.newNativeFunc(r.stringproto_substring, nil, "substring", nil, 2), true, false, true) o._putProp("toLocaleLowerCase", r.newNativeFunc(r.stringproto_toLowerCase, nil, "toLocaleLowerCase", nil, 0), true, false, true) o._putProp("toLocaleUpperCase", r.newNativeFunc(r.stringproto_toUpperCase, nil, "toLocaleUpperCase", nil, 0), true, false, true) o._putProp("toLowerCase", r.newNativeFunc(r.stringproto_toLowerCase, nil, "toLowerCase", nil, 0), true, false, true) o._putProp("toString", r.newNativeFunc(r.stringproto_toString, nil, "toString", nil, 0), true, false, true) o._putProp("toUpperCase", r.newNativeFunc(r.stringproto_toUpperCase, nil, "toUpperCase", nil, 0), true, false, true) o._putProp("trim", r.newNativeFunc(r.stringproto_trim, nil, "trim", nil, 0), true, false, true) trimEnd := r.newNativeFunc(r.stringproto_trimEnd, nil, "trimEnd", nil, 0) trimStart := r.newNativeFunc(r.stringproto_trimStart, nil, "trimStart", nil, 0) o._putProp("trimEnd", trimEnd, true, false, true) o._putProp("trimStart", trimStart, true, false, true) o._putProp("trimRight", trimEnd, true, false, true) o._putProp("trimLeft", trimStart, true, false, true) o._putProp("valueOf", r.newNativeFunc(r.stringproto_valueOf, nil, "valueOf", nil, 0), true, false, true) o._putSym(SymIterator, valueProp(r.newNativeFunc(r.stringproto_iterator, nil, "[Symbol.iterator]", nil, 0), true, false, true)) // Annex B o._putProp("substr", r.newNativeFunc(r.stringproto_substr, nil, "substr", nil, 2), true, false, true) r.global.String = r.newNativeFunc(r.builtin_String, r.builtin_newString, "String", r.global.StringPrototype, 1) o = r.global.String.self o._putProp("fromCharCode", r.newNativeFunc(r.string_fromcharcode, nil, "fromCharCode", nil, 1), true, false, true) o._putProp("fromCodePoint", r.newNativeFunc(r.string_fromcodepoint, nil, "fromCodePoint", nil, 1), true, false, true) o._putProp("raw", r.newNativeFunc(r.string_raw, nil, "raw", nil, 1), true, false, true) r.addToGlobal("String", r.global.String) r.stringSingleton = r.builtin_new(r.global.String, nil).self.(*stringObject) }