Example #1
0
func parseDateFormat(format string) []string {
	format = strings.TrimSpace(format)

	start := 0
	seps := []string{}
	for i := 0; i < len(format); i++ {
		// Date format must start and end with number.
		if i == 0 || i == len(format)-1 {
			if !unicode.IsNumber(rune(format[i])) {
				return nil
			}

			continue
		}

		// Separator is a single none-number char.
		if !unicode.IsNumber(rune(format[i])) {
			if !unicode.IsNumber(rune(format[i-1])) {
				return nil
			}

			seps = append(seps, format[start:i])
			start = i + 1
		}

	}

	seps = append(seps, format[start:])
	return seps
}
Example #2
0
func isFloatNumber(s string) bool {
	if len(s) == 0 {
		return false
	}

	if !unicode.IsNumber(rune(s[0])) {
		return false
	}

	already_encountered := false

	if s[0] == '0' {
		return s[1] == '.'
	} else {
		for _, r := range s {
			if !unicode.IsNumber(r) && r != '.' {
				return false
			}

			if r == '.' {
				if already_encountered {
					return false
				} else {
					already_encountered = true
				}
			}
		}
	}

	return true
}
Example #3
0
func CheckRuneType(last, current rune) index.RuneType {
	if isTermSep(current) {
		return index.TokenSep
	}

	if current > 128 {
		return index.TokenStart
	}

	if unicode.IsLetter(current) {
		if unicode.IsLetter(last) {
			return index.TokenBody
		}
		return index.TokenStart
	}

	if unicode.IsNumber(current) {
		if unicode.IsNumber(last) {
			return index.TokenBody
		}
		return index.TokenStart
	}

	return index.TokenStart
}
Example #4
0
func get_identifier(s string, sk *Stack) (rs string, ri int) {
	i := 0
	if s == "" {
		ri = 1
		return
	}
	iLen := len(s)
	// fmt.Printf("@@@%s@@@\n", s)

	con := true

	for i < iLen && con {
		switch {
		case unicode.IsLetter(rune(s[i])), unicode.IsNumber(rune(s[i])), s[i] == '_':
			i++
			for i < iLen {
				if unicode.IsLetter(rune(s[i])) || unicode.IsNumber(rune(s[i])) || s[i] == '_' {
					i++
				} else {
					break
				}
			}
			con = false
		case s[i] == ' ', s[i] == '\t':
			i++
		default:
			con = false
			i++
		}
	}
	// time.Sleep(time.Second)
	ts := s[:i]
	s1 := strings.Trim(ts, " ")
	s = s[i:]
	sk.Push(s1)
	rs = s
	switch s1 {
	case "":
		ri = -1
	case "char", "short", "int", "long", "float", "double", "auto", "signed", "unsigned", "const", "volatile", "static", "enum", "struct", "union", "void":
		ri = -1
	default:
		if !unicode.IsLetter(rune(s1[0])) && s1[0] != '_' {
			ri = -1
		} else {
			ri = 0
		}
	}
	return
	// fmt.Printf("<<<%d|%s|%s|%d>>>\n", iLen, ts[:i], ts[i:], i)

}
Example #5
0
// readDeviceValues reads values from a single blkio file.
// It expects to read values like "245:1 read 18880" or "254:1 1909". It returns
// an array containing an entry for each valid line read.
func readBlkioValues(path ...string) ([]blkioValue, error) {
	f, err := os.Open(filepath.Join(path...))
	if err != nil {
		if os.IsNotExist(err) {
			return nil, nil
		}
		return nil, err
	}
	defer f.Close()

	var values []blkioValue
	sc := bufio.NewScanner(f)
	for sc.Scan() {
		line := strings.TrimSpace(sc.Text())
		if len(line) == 0 {
			continue
		}
		// Valid lines start with a device ID.
		if !unicode.IsNumber(rune(line[0])) {
			continue
		}

		v, err := parseBlkioValue(sc.Text())
		if err != nil {
			return nil, err
		}

		values = append(values, v)
	}

	return values, nil
}
Example #6
0
// CharType returns a string representing the unicode type of a rune
func CharType(r rune) string {
	switch {
	case unicode.IsLetter(r):
		return "letter"
	case unicode.IsSpace(r):
		return "space"
	case unicode.IsPunct(r):
		return "punct"
	case unicode.IsNumber(r):
		return "number"
	case unicode.IsSymbol(r):
		return "symbol"
	case unicode.IsMark(r):
		return "mark"
	case unicode.IsDigit(r):
		return "digit"
	case unicode.IsPrint(r):
		return "print"
	case unicode.IsControl(r):
		return "control"
	case unicode.IsGraphic(r):
		return "graphic"
	default:
		return "invalid"
	}
}
Example #7
0
File: util.go Project: nmeum/cpod
// Escape escapes the given data to make sure it is safe to use it as a
// filename. It also replaces spaces and other seperation characters
// with the '-' character. It returns an error if the escaped string is
// empty.
func Escape(name string) (escaped string, err error) {
	mfunc := func(r rune) rune {
		switch {
		case unicode.IsLetter(r):
			return r
		case unicode.IsNumber(r):
			return r
		case unicode.IsSpace(r):
			return '-'
		case unicode.IsPunct(r):
			return '-'
		}

		return -1
	}

	escaped = strings.Map(mfunc, html.UnescapeString(name))
	for strings.Contains(escaped, "--") {
		escaped = strings.Replace(escaped, "--", "-", -1)
	}

	escaped = strings.TrimPrefix(escaped, "-")
	escaped = strings.TrimSuffix(escaped, "-")

	if len(escaped) <= 0 {
		err = errors.New("couldn't escape title")
	}

	return
}
Example #8
0
func validateId(id string, allowEmpty bool, idName string, errors map[string][]error) (newId string, err error) {
	if idName == "" {
		idName = "id"
	}
	newId = strings.TrimSpace(id)
	if newId == "" {
		if !allowEmpty {
			err = ERR_MUST_SPECIFY_ID
		}
	}
	if err == nil {
		for _, rune := range newId {
			switch {
			case unicode.IsLetter(rune), unicode.IsNumber(rune):
			default:
				switch rune {
				case '/', '-', '_', '@', '.':
				default:
					err = ERR_INVALID_ID
				}
			}
			if err != nil {
				break
			}
		}
	}
	if err != nil && errors != nil {
		errors[idName] = []error{err}
	}
	return
}
Example #9
0
//Atbash implements atbash cypher
func Atbash(s string) (cypher string) {
	s = strings.ToLower(s)
	// s = strings.Replace(s, " ", "", -1)
	var code []string
	var block int
	for _, v := range s {
		if unicode.IsLetter(v) || unicode.IsNumber(v) {
			if block == 5 {
				code = append(code, DELIMITER)
				block = 0
			}

			if unicode.IsLetter(v) {
				index := v - 'a'
				cypherIndex := (('z' - 'a') - index)
				code = append(code, string(cypherIndex+'a'))
			} else {
				code = append(code, string(v))

			}

			block++
		}
	}
	cypher = strings.Join(code, "")
	return
}
Example #10
0
// CharCount scans a *bufio.Reader and returns a map of the counts of its
// Unicode character types.
func CharCount(in *bufio.Reader) map[string]int {
	counts := make(map[string]int) // counts of Unicode character types

	for {
		r, n, err := in.ReadRune() // returns rune, nbytes, error
		if err == io.EOF {
			break
		}
		if err != nil {
			fmt.Fprintf(os.Stderr, "charcount: %v\n", err)
			os.Exit(1)
		}

		switch {
		case r == unicode.ReplacementChar && n == 1:
			counts["invalid"]++
		case unicode.IsControl(r):
			counts["control"]++
		case unicode.IsLetter(r):
			counts["letter"]++
		case unicode.IsMark(r):
			counts["mark"]++
		case unicode.IsNumber(r):
			counts["number"]++
		case unicode.IsPunct(r):
			counts["punct"]++
		case unicode.IsSpace(r):
			counts["space"]++
		case unicode.IsSymbol(r):
			counts["symbol"]++
		}
	}
	return counts
}
Example #11
0
// parse12HourClock convers 12-hour clock time to 24-hour one.
func parse12HourClock(word string) (time.Time, error) {
	lower := strings.ToLower(word)
	now := time.Now().In(time.Local)

	start := 0
	hour := 0
	var err error
	for width := 0; start < len(lower); start += width {
		var r rune
		r, width = utf8.DecodeRuneInString(lower[start:])
		if !unicode.IsNumber(r) {
			hour, err = strconv.Atoi(lower[:start])
			if err != nil || hour > 12 || hour < 0 {
				return time.Now(), fmt.Errorf("Wrong hour: %v", word)
			}
			if string(lower[start:]) == "am" {
				break
			}
			if string(lower[start:]) == "pm" {
				hour += 12
				break
			}
			return time.Now(), fmt.Errorf("Unsupported 12 hour clock notation: %v", word)
		}
	}
	return time.Date(now.Year(), now.Month(), now.Day(), hour, 0, 0, 0, time.Local), nil
}
Example #12
0
func (this *Scanner) scanWord(token *TokenType, lexeme *string, tabIndex *int) {

	var char = this.lookahead

	for char != endOfFile && (unicode.IsLetter(char) || unicode.IsNumber(char)) {
		*lexeme += string(char)
		char = this.getc()
	}
	//Put back last invalid character
	this.ungetc(char)
	//Set lookahead for next lexeme
	this.lookahead = this.firstChar()

	//Finally check the symbol table for correctness
	/*
	 *	If the lexeme is already in the symbol table,
	 *	return its tokenclass.  If it isn't,            it must
	 *	be an identifier whose type we do not know yet.
	 */
	if this.St.Installname(*lexeme, tabIndex) {
		*token = this.St.gettok_class(*tabIndex)
	} else {
		this.St.Setattrib(*tabIndex, Stunknown, Tokidentifier)
		*token = Tokidentifier
	}

}
Example #13
0
func (x *exprLex) lexId(yylval *exprSymType) int {
	var b bytes.Buffer
	for {
		c := x.next()
		if c == lexEOF {
			break
		}

		// If this isn't a character we want in an ID, return out.
		// One day we should make this a regexp.
		if c != '_' &&
			c != '-' &&
			c != '.' &&
			c != '*' &&
			!unicode.IsLetter(c) &&
			!unicode.IsNumber(c) {
			x.backup()
			break
		}

		if _, err := b.WriteRune(c); err != nil {
			log.Printf("ERR: %s", err)
			return lexEOF
		}
	}

	yylval.str = b.String()
	return IDENTIFIER
}
Example #14
0
func valid_identifier_rune(r rune) bool {
	if unicode.IsLetter(r) || unicode.IsNumber(r) || r == rune('-') || r == rune('_') {
		return true
	} else {
		return false
	}
}
Example #15
0
func (self *Tokenizer) readNumber() (token int, lit string) {
	buffer := make([]rune, 0, 1)
	isFloat := false
	sawDecimal := false
	firstChar := true
	for !self.isEof() {
		ch := rune(self.CurrentCh)
		if ch == '.' && !sawDecimal {
			isFloat = true
			sawDecimal = true
			buffer = append(buffer, self.CurrentCh)
			self.Advance()
		} else if firstChar && ch == '-' {
			buffer = append(buffer, self.CurrentCh)
			self.Advance()
		} else if unicode.IsNumber(ch) {
			buffer = append(buffer, self.CurrentCh)
			self.Advance()
		} else {
			break
		}
		firstChar = false
	}

	lit = string(buffer)
	if isFloat {
		token = FLOAT
	} else {
		token = NUMBER
	}
	return
}
Example #16
0
func FactPointer(val string) (key string, start, end int) {
	// A pointer looks like *key or *{key with optional spaces}
	// In the former case key must be alphanumeric
	if start = strings.Index(val, "*"); start == -1 || start+1 == len(val) {
		return "", -1, -1
	}
	if val[start+1] == '{' {
		end = strings.Index(val[start:], "}") + start + 1
		// TrimSpace since it's not possible to have a fact key that
		// starts/ends with a space, but someone *could* write *{ foo }
		key = strings.ToLower(strings.TrimSpace(val[start+2 : end-1]))
	} else {
		// util.Lexer helps find the next char that isn't alphabetical
		l := &Lexer{Input: val}
		l.Pos(start + 1)
		key = strings.ToLower(l.Scan(func(r rune) bool {
			if unicode.IsLetter(r) || unicode.IsNumber(r) {
				return true
			}
			return false
		}))
		end = l.Pos()
		// Special case handling because *pointer might be *emphasis*
		// perlfu's designer has a lot to answer for :-/
		if l.Peek() == '*' {
			return "", -1, -1
		}
	}
	return
}
Example #17
0
// 将文本划分成字元
func splitTextToWords(text Text) []Text {
	output := make([]Text, 0, len(text)/8)
	current := 0
	inAlphanumeric := true
	alphanumericStart := 0
	for current < len(text) {
		r, size := utf8.DecodeRune(text[current:])
		if size <= 2 && (unicode.IsLetter(r) || unicode.IsNumber(r)) {
			// 当前是拉丁字母或数字(非中日韩文字)
			if !inAlphanumeric {
				alphanumericStart = current
				inAlphanumeric = true
			}
		} else {
			if inAlphanumeric {
				inAlphanumeric = false
				if current != 0 {
					output = append(output, toLower(text[alphanumericStart:current]))
				}
			}
			output = append(output, text[current:current+size])
		}
		current += size
	}

	// 处理最后一个字元是英文的情况
	if inAlphanumeric {
		if current != 0 {
			output = append(output, toLower(text[alphanumericStart:current]))
		}
	}

	return output
}
Example #18
0
func normalize(name string) string {
	fargs := func(c rune) bool {
		return !unicode.IsLetter(c) && !unicode.IsNumber(c)
	}
	// get function
	return strings.Join(strings.FieldsFunc(name, fargs), "-")
}
Example #19
0
// Stat calculates statistics for all runes read from r.
func (m *Main) Stat(r io.RuneReader) (Stats, error) {
	var stats Stats

	for {
		// Read next character.
		ch, sz, err := r.ReadRune()
		if err == io.EOF {
			break
		} else if err != nil {
			return stats, err
		}

		// Calculate stats.
		stats.TotalN++
		if unicode.IsControl(ch) {
			stats.ControlN++
		}
		if unicode.IsDigit(ch) {
			stats.DigitN++
		}
		if unicode.IsGraphic(ch) {
			stats.GraphicN++
		}
		if unicode.IsLetter(ch) {
			stats.LetterN++
		}
		if unicode.IsLower(ch) {
			stats.LowerN++
		}
		if unicode.IsMark(ch) {
			stats.MarkN++
		}
		if unicode.IsNumber(ch) {
			stats.NumberN++
		}
		if unicode.IsPrint(ch) {
			stats.PrintN++
		}
		if unicode.IsPunct(ch) {
			stats.PunctN++
		}
		if unicode.IsSpace(ch) {
			stats.SpaceN++
		}
		if unicode.IsSymbol(ch) {
			stats.SymbolN++
		}
		if unicode.IsTitle(ch) {
			stats.TitleN++
		}
		if unicode.IsUpper(ch) {
			stats.UpperN++
		}
		if sz > 1 {
			stats.MultiByteN++
		}
	}

	return stats, nil
}
Example #20
0
func (x *parserLex) lexId(yylval *parserSymType) int {
	var b bytes.Buffer
	for {
		c := x.next()
		if c == lexEOF {
			break
		}

		// If this isn't a character we want in an ID, return out.
		// One day we should make this a regexp.
		if c != '_' &&
			c != '-' &&
			c != '.' &&
			c != '*' &&
			!unicode.IsLetter(c) &&
			!unicode.IsNumber(c) {
			x.backup()
			break
		}

		if _, err := b.WriteRune(c); err != nil {
			x.Error(err.Error())
			return lexEOF
		}
	}

	yylval.token = &parserToken{Value: b.String()}
	return IDENTIFIER
}
Example #21
0
func makeGoIdentifier(in string) string {
	d.Chk.NotEmpty(in, "Cannot convert empty string to legal Go identifier.")
	if r, _ := utf8.DecodeRuneInString(in); unicode.IsNumber(r) {
		in = "_" + in
	}
	return illegalRune.ReplaceAllLiteralString(in, "_")
}
Example #22
0
func Tokenize(buf *bytes.Buffer) []interface{} {
	if buf.Len() == 0 {
		return nil
	}
	r := []interface{}{}

	acc := ""
	for buf.Len() > 0 {
		c := rune(buf.Next(1)[0])

		if unicode.IsLetter(c) || unicode.IsNumber(c) || c == '"' {
			acc += string(c)
		} else if c == '(' {
			var nested []interface{} = Tokenize(buf)
			r = append(r, nested)
		} else if c == ')' {
			break
		} else {
			if acc != "" {
				r = append(r, acc)
			}
			acc = ""
		}

	}
	if acc != "" {
		r = append(r, acc)
	}
	return r
}
Example #23
0
func incrementCount(r rune, counts map[int]int) {
	switch {
	case unicode.IsControl(r):
		counts[isControl]++

	case unicode.IsNumber(r):
		counts[isNumber]++

	case unicode.IsDigit(r):
		counts[isDigit]++

	case unicode.IsLetter(r):
		counts[isLetter]++

	case unicode.IsMark(r):
		counts[isMark]++

	case unicode.IsPunct(r):
		counts[isPunct]++

	case unicode.IsSpace(r):
		counts[isSpace]++

	case unicode.IsSymbol(r):
		counts[isSymbol]++

	case unicode.IsPrint(r):
		counts[isPrint]++

	case unicode.IsGraphic(r):
		counts[isGraphic]++
	}

}
Example #24
0
func validateHarborPassword(password string) bool {
	correct := true
	number := false
	upper := false
	lower := false
	count := 0
	for _, letter := range password {
		switch {
		case unicode.IsNumber(letter):
			number = true
			count++
		case unicode.IsUpper(letter):
			upper = true
			count++
		case unicode.IsLower(letter):
			lower = true
			count++
		case letter == ' ':
			correct = false
		default:
			count++
		}
	}
	return correct && number && upper && lower && (count >= 7)
}
Example #25
0
// our simplified version of MapReduce does not supply a
// key to the Map function, as in the paper; only a value,
// which is a part of the input file content. the return
// value should be a list of key/value pairs, each represented
// by a mapreduce.KeyValue.
func Map(value string) *list.List {

	f := func(c rune) bool {
		return !unicode.IsLetter(c) && !unicode.IsNumber(c)
	}

	s := strings.FieldsFunc(value, f)
	l := list.New()
	m := make(map[string]string)
	for _, k := range s {
		if v, exsits := m[k]; exsits != false {
			v += "1"
			m[k] = v
		} else {
			m[k] = "1"
		}
	}

	for k, v := range m {
		//fmt.Println(v)//XXX for test
		kv := mapreduce.NewKeyValue(k, v)
		l.PushBack(kv)
	}

	return l
}
Example #26
0
// baseで指定した数値をもとに、sで記述された値をパースし返します。
// baseを使うのは、s内で単位として"%"が使われた場合のみです。
// 単位に"px"が使われた場合と単位がない場合は、
// 単位を省いた数字の部分を数値に変換して返します。
func parseRelSize(base int, s string) (int, error) {
	i := strings.IndexFunc(s, func(c rune) bool {
		// TODO: cが数字の場合はfalse、そうでない場合はtrueを返す。
		// なお、iにはここがtrueになった箇所(インデックス)が入る。
		// ヒント:unicodeパッケージのドキュメントを見てみよう。
		return !unicode.IsNumber(c)
	})

	// TODO: 数字のみだった場合は、単位なしの数値のみとし、
	// sをint型に変換して返す。
	// ヒント:stringsパッケージのドキュメントを見て、struct.IndexFuncの戻り値を調べよう。
	if i < 0 {
		return strconv.Atoi(s)
	}

	// TODO:sのうち、数字だけの部分をint型に変換する。
	v, err := strconv.Atoi(s[:i])
	if err != nil {
		return 0, ErrInvalidSize
	}

	switch s[i:] {
	// TODO: "%"が指定された場合は、baseを100%として値を計算する。
	case "%":
		return int(float64(base) * float64(v) / 100), nil
	case "px":
		return v, nil
	default:
		// TODO: "%"と"px"以外の単位が指定された場合は、ErrUnkownUnitエラーを返す。
		return 0, ErrUnkownUnit
	}
}
Example #27
0
func ExampleFieldsFunc() {
	f := func(c rune) bool {
		return !unicode.IsLetter(c) && !unicode.IsNumber(c)
	}
	fmt.Printf("Fields are: %q", bytes.FieldsFunc([]byte("  foo1;bar2,baz3..."), f))
	// Output: Fields are: ["foo1" "bar2" "baz3"]
}
Example #28
0
func TestRune_IsIndependent(t *testing.T) {
	numbers := make([]rune, 0)
	letters := make([]rune, 0)
	marks := make([]rune, 0)
	symbols := make([]rune, 0)
	puncts := make([]rune, 0)
	others := make([]rune, 0)
	for _, r := range unicode.Myanmar.R16 {
		for c := r.Lo; c <= r.Hi; c++ {
			switch mr := rune(c); true {
			case unicode.IsLetter(mr):
				letters = append(letters, mr)
			case unicode.IsNumber(mr):
				numbers = append(numbers, mr)
			case unicode.IsMark(mr):
				marks = append(marks, mr)
			case unicode.IsPunct(mr):
				puncts = append(puncts, mr)
			case unicode.IsSymbol(mr):
				symbols = append(symbols, mr)
			default:
				others = append(others, mr)
			}
		}
	}

	independents := string(letters) + string(numbers) + string(puncts) + " \t\r\n"
	for _, consonant := range independents {
		if ok, _ := Rune(consonant).IsIndependent(); !ok {
			t.Errorf("[%U] expected result is true, but it returns false", consonant)
		}
	}
}
Example #29
0
//converts a string into a slice of strings.  symbols and contiguous strings of any other type
//are returned as individual elements.  all whitespace is excluded
func getTokens(value string) []string {
	var buffer []rune
	var result []string
	chars := []rune(value)
	for i, r := range chars {
		if !unicode.IsLetter(r) && !unicode.IsNumber(r) && !unicode.IsDigit(r) && !unicode.IsSpace(r) {
			if len(buffer) > 0 {
				result = append(result, string(buffer))
				buffer = nil
			}
			result = append(result, string(r))
		} else if unicode.IsSpace(r) {
			if len(buffer) > 0 {
				result = append(result, string(buffer))
			}
			buffer = nil
		} else {
			buffer = append(buffer, r)
			if i == len(chars)-1 {
				result = append(result, string(buffer))
			}
		}
	}
	return result
}
Example #30
0
// keywords returns a slice of searchable tokens extracted
// from the given UserID packet keywords string.
func keywords(key *openpgp.PrimaryKey) []string {
	m := make(map[string]bool)
	for _, uid := range key.UserIDs {
		s := strings.ToLower(uid.Keywords)
		lbr, rbr := strings.Index(s, "<"), strings.LastIndex(s, ">")
		if lbr != -1 && rbr > lbr {
			m[s[lbr+1:rbr]] = true
		}
		if lbr != -1 {
			fields := strings.FieldsFunc(s[:lbr], func(r rune) bool {
				if !utf8.ValidRune(r) {
					return true
				}
				if unicode.IsLetter(r) || unicode.IsNumber(r) {
					return false
				}
				return true
			})
			for _, field := range fields {
				m[field] = true
			}
		}
	}
	var result []string
	for k := range m {
		result = append(result, k)
	}
	return result
}