package quotedprintable import ( "bytes" "encoding/base64" "errors" "fmt" "io" "strings" "unicode" "unicode/utf8" ) // A WordEncoder is a RFC 2047 encoded-word encoder. type WordEncoder byte const ( // BEncoding represents Base64 encoding scheme as defined by RFC 2045. BEncoding = WordEncoder('b') // QEncoding represents the Q-encoding scheme as defined by RFC 2047. QEncoding = WordEncoder('q') ) var ( errInvalidWord = errors.New("mime: invalid RFC 2047 encoded-word") ) // Encode returns the encoded-word form of s. If s is ASCII without special // characters, it is returned unchanged. The provided charset is the IANA // charset name of s. It is case insensitive. func (e WordEncoder) Encode(charset, s string) string { if !needsEncoding(s) { return s } return e.encodeWord(charset, s) } func needsEncoding(s string) bool { for _, b := range s { if (b < ' ' || b > '~') && b != '\t' { return true } } return false } // encodeWord encodes a string into an encoded-word. func (e WordEncoder) encodeWord(charset, s string) string { buf := getBuffer() defer putBuffer(buf) buf.WriteString("=?") buf.WriteString(charset) buf.WriteByte('?') buf.WriteByte(byte(e)) buf.WriteByte('?') if e == BEncoding { w := base64.NewEncoder(base64.StdEncoding, buf) io.WriteString(w, s) w.Close() } else { enc := make([]byte, 3) for i := 0; i < len(s); i++ { b := s[i] switch { case b == ' ': buf.WriteByte('_') case b <= '~' && b >= '!' && b != '=' && b != '?' && b != '_': buf.WriteByte(b) default: enc[0] = '=' enc[1] = upperhex[b>>4] enc[2] = upperhex[b&0x0f] buf.Write(enc) } } } buf.WriteString("?=") return buf.String() } const upperhex = "0123456789ABCDEF" // A WordDecoder decodes MIME headers containing RFC 2047 encoded-words. type WordDecoder struct { // CharsetReader, if non-nil, defines a function to generate // charset-conversion readers, converting from the provided // charset into UTF-8. // Charsets are always lower-case. utf-8, iso-8859-1 and us-ascii charsets // are handled by default. // One of the the CharsetReader's result values must be non-nil. CharsetReader func(charset string, input io.Reader) (io.Reader, error) } // Decode decodes an encoded-word. If word is not a valid RFC 2047 encoded-word, // word is returned unchanged. func (d *WordDecoder) Decode(word string) (string, error) { fields := strings.Split(word, "?") // TODO: remove allocation? if len(fields) != 5 || fields[0] != "=" || fields[4] != "=" || len(fields[2]) != 1 { return "", errInvalidWord } content, err := decode(fields[2][0], fields[3]) if err != nil { return "", err } buf := getBuffer() defer putBuffer(buf) if err := d.convert(buf, fields[1], content); err != nil { return "", err } return buf.String(), nil } // DecodeHeader decodes all encoded-words of the given string. It returns an // error if and only if CharsetReader of d returns an error. func (d *WordDecoder) DecodeHeader(header string) (string, error) { // If there is no encoded-word, returns before creating a buffer. i := strings.Index(header, "=?") if i == -1 { return header, nil } buf := getBuffer() defer putBuffer(buf) buf.WriteString(header[:i]) header = header[i:] betweenWords := false for { start := strings.Index(header, "=?") if start == -1 { break } cur := start + len("=?") i := strings.Index(header[cur:], "?") if i == -1 { break } charset := header[cur : cur+i] cur += i + len("?") if len(header) < cur+len("Q??=") { break } encoding := header[cur] cur++ if header[cur] != '?' { break } cur++ j := strings.Index(header[cur:], "?=") if j == -1 { break } text := header[cur : cur+j] end := cur + j + len("?=") content, err := decode(encoding, text) if err != nil { betweenWords = false buf.WriteString(header[:start+2]) header = header[start+2:] continue } // Write characters before the encoded-word. White-space and newline // characters separating two encoded-words must be deleted. if start > 0 && (!betweenWords || hasNonWhitespace(header[:start])) { buf.WriteString(header[:start]) } if err := d.convert(buf, charset, content); err != nil { return "", err } header = header[end:] betweenWords = true } if len(header) > 0 { buf.WriteString(header) } return buf.String(), nil } func decode(encoding byte, text string) ([]byte, error) { switch encoding { case 'B', 'b': return base64.StdEncoding.DecodeString(text) case 'Q', 'q': return qDecode(text) } return nil, errInvalidWord } func (d *WordDecoder) convert(buf *bytes.Buffer, charset string, content []byte) error { switch { case strings.EqualFold("utf-8", charset): buf.Write(content) case strings.EqualFold("iso-8859-1", charset): for _, c := range content { buf.WriteRune(rune(c)) } case strings.EqualFold("us-ascii", charset): for _, c := range content { if c >= utf8.RuneSelf { buf.WriteRune(unicode.ReplacementChar) } else { buf.WriteByte(c) } } default: if d.CharsetReader == nil { return fmt.Errorf("mime: unhandled charset %q", charset) } r, err := d.CharsetReader(strings.ToLower(charset), bytes.NewReader(content)) if err != nil { return err } if _, err = buf.ReadFrom(r); err != nil { return err } } return nil } // hasNonWhitespace reports whether s (assumed to be ASCII) contains at least // one byte of non-whitespace. func hasNonWhitespace(s string) bool { for _, b := range s { switch b { // Encoded-words can only be separated by linear white spaces which does // not include vertical tabs (\v). case ' ', '\t', '\n', '\r': default: return true } } return false } // qDecode decodes a Q encoded string. func qDecode(s string) ([]byte, error) { dec := make([]byte, len(s)) n := 0 for i := 0; i < len(s); i++ { switch c := s[i]; { case c == '_': dec[n] = ' ' case c == '=': if i+2 >= len(s) { return nil, errInvalidWord } b, err := readHexByte(s[i+1], s[i+2]) if err != nil { return nil, err } dec[n] = b i += 2 case (c <= '~' && c >= ' ') || c == '\n' || c == '\r' || c == '\t': dec[n] = c default: return nil, errInvalidWord } n++ } return dec[:n], nil }