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     18  ****************************************************************/
     19 
     20 package org.apache.james.mime4j.codec;
     21 
     22 import java.nio.ByteBuffer;
     23 import java.nio.charset.Charset;
     24 import java.util.BitSet;
     25 import java.util.Locale;
     26 
     27 import org.apache.james.mime4j.util.CharsetUtil;
     28 
     29 /**
     30  * ANDROID:  THIS CLASS IS COPIED FROM A NEWER VERSION OF MIME4J
     31  */
     32 
     33 /**
     34  * Static methods for encoding header field values. This includes encoded-words
     35  * as defined in <a href='http://www.faqs.org/rfcs/rfc2047.html'>RFC 2047</a>
     36  * or display-names of an e-mail address, for example.
     37  *
     38  */
     39 public class EncoderUtil {
     40 
     41     // This array is a lookup table that translates 6-bit positive integer index
     42     // values into their "Base64 Alphabet" equivalents as specified in Table 1
     43     // of RFC 2045.
     44     // ANDROID:  THIS TABLE IS COPIED FROM BASE64OUTPUTSTREAM
     45     static final byte[] BASE64_TABLE = { 'A', 'B', 'C', 'D', 'E', 'F',
     46             'G', 'H', 'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P', 'Q', 'R', 'S',
     47             'T', 'U', 'V', 'W', 'X', 'Y', 'Z', 'a', 'b', 'c', 'd', 'e', 'f',
     48             'g', 'h', 'i', 'j', 'k', 'l', 'm', 'n', 'o', 'p', 'q', 'r', 's',
     49             't', 'u', 'v', 'w', 'x', 'y', 'z', '0', '1', '2', '3', '4', '5',
     50             '6', '7', '8', '9', '+', '/' };
     51 
     52     // Byte used to pad output.
     53     private static final byte BASE64_PAD = '=';
     54 
     55     private static final BitSet Q_REGULAR_CHARS = initChars("=_?");
     56 
     57     private static final BitSet Q_RESTRICTED_CHARS = initChars("=_?\"#$%&'(),.:;<>@[\\]^`{|}~");
     58 
     59     private static final int MAX_USED_CHARACTERS = 50;
     60 
     61     private static final String ENC_WORD_PREFIX = "=?";
     62     private static final String ENC_WORD_SUFFIX = "?=";
     63 
     64     private static final int ENCODED_WORD_MAX_LENGTH = 75; // RFC 2047
     65 
     66     private static final BitSet TOKEN_CHARS = initChars("()<>@,;:\\\"/[]?=");
     67 
     68     private static final BitSet ATEXT_CHARS = initChars("()<>@.,;:\\\"[]");
     69 
     70     private static BitSet initChars(String specials) {
     71         BitSet bs = new BitSet(128);
     72         for (char ch = 33; ch < 127; ch++) {
     73             if (specials.indexOf(ch) == -1) {
     74                 bs.set(ch);
     75             }
     76         }
     77         return bs;
     78     }
     79 
     80     /**
     81      * Selects one of the two encodings specified in RFC 2047.
     82      */
     83     public enum Encoding {
     84         /** The B encoding (identical to base64 defined in RFC 2045). */
     85         B,
     86         /** The Q encoding (similar to quoted-printable defined in RFC 2045). */
     87         Q
     88     }
     89 
     90     /**
     91      * Indicates the intended usage of an encoded word.
     92      */
     93     public enum Usage {
     94         /**
     95          * Encoded word is used to replace a 'text' token in any Subject or
     96          * Comments header field.
     97          */
     98         TEXT_TOKEN,
     99         /**
    100          * Encoded word is used to replace a 'word' entity within a 'phrase',
    101          * for example, one that precedes an address in a From, To, or Cc
    102          * header.
    103          */
    104         WORD_ENTITY
    105     }
    106 
    107     private EncoderUtil() {
    108     }
    109 
    110     /**
    111      * Encodes the display-name portion of an address. See <a
    112      * href='http://www.faqs.org/rfcs/rfc5322.html'>RFC 5322</a> section 3.4
    113      * and <a href='http://www.faqs.org/rfcs/rfc2047.html'>RFC 2047</a> section
    114      * 5.3. The specified string should not be folded.
    115      *
    116      * @param displayName
    117      *            display-name to encode.
    118      * @return encoded display-name.
    119      */
    120     public static String encodeAddressDisplayName(String displayName) {
    121         // display-name = phrase
    122         // phrase = 1*( encoded-word / word )
    123         // word = atom / quoted-string
    124         // atom = [CFWS] 1*atext [CFWS]
    125         // CFWS = comment or folding white space
    126 
    127         if (isAtomPhrase(displayName)) {
    128             return displayName;
    129         } else if (hasToBeEncoded(displayName, 0)) {
    130             return encodeEncodedWord(displayName, Usage.WORD_ENTITY);
    131         } else {
    132             return quote(displayName);
    133         }
    134     }
    135 
    136     /**
    137      * Encodes the local part of an address specification as described in RFC
    138      * 5322 section 3.4.1. Leading and trailing CFWS should have been removed
    139      * before calling this method. The specified string should not contain any
    140      * illegal (control or non-ASCII) characters.
    141      *
    142      * @param localPart
    143      *            the local part to encode
    144      * @return the encoded local part.
    145      */
    146     public static String encodeAddressLocalPart(String localPart) {
    147         // local-part = dot-atom / quoted-string
    148         // dot-atom = [CFWS] dot-atom-text [CFWS]
    149         // CFWS = comment or folding white space
    150 
    151         if (isDotAtomText(localPart)) {
    152             return localPart;
    153         } else {
    154             return quote(localPart);
    155         }
    156     }
    157 
    158     /**
    159      * Encodes the specified strings into a header parameter as described in RFC
    160      * 2045 section 5.1 and RFC 2183 section 2. The specified strings should not
    161      * contain any illegal (control or non-ASCII) characters.
    162      *
    163      * @param name
    164      *            parameter name.
    165      * @param value
    166      *            parameter value.
    167      * @return encoded result.
    168      */
    169     public static String encodeHeaderParameter(String name, String value) {
    170         name = name.toLowerCase(Locale.US);
    171 
    172         // value := token / quoted-string
    173         if (isToken(value)) {
    174             return name + "=" + value;
    175         } else {
    176             return name + "=" + quote(value);
    177         }
    178     }
    179 
    180     /**
    181      * Shortcut method that encodes the specified text into an encoded-word if
    182      * the text has to be encoded.
    183      *
    184      * @param text
    185      *            text to encode.
    186      * @param usage
    187      *            whether the encoded-word is to be used to replace a text token
    188      *            or a word entity (see RFC 822).
    189      * @param usedCharacters
    190      *            number of characters already used up (<code>0 <= usedCharacters <= 50</code>).
    191      * @return the specified text if encoding is not necessary or an encoded
    192      *         word or a sequence of encoded words otherwise.
    193      */
    194     public static String encodeIfNecessary(String text, Usage usage,
    195             int usedCharacters) {
    196         if (hasToBeEncoded(text, usedCharacters))
    197             return encodeEncodedWord(text, usage, usedCharacters);
    198         else
    199             return text;
    200     }
    201 
    202     /**
    203      * Determines if the specified string has to encoded into an encoded-word.
    204      * Returns <code>true</code> if the text contains characters that don't
    205      * fall into the printable ASCII character set or if the text contains a
    206      * 'word' (sequence of non-whitespace characters) longer than 77 characters
    207      * (including characters already used up in the line).
    208      *
    209      * @param text
    210      *            text to analyze.
    211      * @param usedCharacters
    212      *            number of characters already used up (<code>0 <= usedCharacters <= 50</code>).
    213      * @return <code>true</code> if the specified text has to be encoded into
    214      *         an encoded-word, <code>false</code> otherwise.
    215      */
    216     public static boolean hasToBeEncoded(String text, int usedCharacters) {
    217         if (text == null)
    218             throw new IllegalArgumentException();
    219         if (usedCharacters < 0 || usedCharacters > MAX_USED_CHARACTERS)
    220             throw new IllegalArgumentException();
    221 
    222         int nonWhiteSpaceCount = usedCharacters;
    223 
    224         for (int idx = 0; idx < text.length(); idx++) {
    225             char ch = text.charAt(idx);
    226             if (ch == '\t' || ch == ' ') {
    227                 nonWhiteSpaceCount = 0;
    228             } else {
    229                 nonWhiteSpaceCount++;
    230                 if (nonWhiteSpaceCount > 77) {
    231                     // Line cannot be folded into multiple lines with no more
    232                     // than 78 characters each. Encoding as encoded-words makes
    233                     // that possible. One character has to be reserved for
    234                     // folding white space; that leaves 77 characters.
    235                     return true;
    236                 }
    237 
    238                 if (ch < 32 || ch >= 127) {
    239                     // non-printable ascii character has to be encoded
    240                     return true;
    241                 }
    242             }
    243         }
    244 
    245         return false;
    246     }
    247 
    248     /**
    249      * Encodes the specified text into an encoded word or a sequence of encoded
    250      * words separated by space. The text is separated into a sequence of
    251      * encoded words if it does not fit in a single one.
    252      * <p>
    253      * The charset to encode the specified text into a byte array and the
    254      * encoding to use for the encoded-word are detected automatically.
    255      * <p>
    256      * This method assumes that zero characters have already been used up in the
    257      * current line.
    258      *
    259      * @param text
    260      *            text to encode.
    261      * @param usage
    262      *            whether the encoded-word is to be used to replace a text token
    263      *            or a word entity (see RFC 822).
    264      * @return the encoded word (or sequence of encoded words if the given text
    265      *         does not fit in a single encoded word).
    266      * @see #hasToBeEncoded(String, int)
    267      */
    268     public static String encodeEncodedWord(String text, Usage usage) {
    269         return encodeEncodedWord(text, usage, 0, null, null);
    270     }
    271 
    272     /**
    273      * Encodes the specified text into an encoded word or a sequence of encoded
    274      * words separated by space. The text is separated into a sequence of
    275      * encoded words if it does not fit in a single one.
    276      * <p>
    277      * The charset to encode the specified text into a byte array and the
    278      * encoding to use for the encoded-word are detected automatically.
    279      *
    280      * @param text
    281      *            text to encode.
    282      * @param usage
    283      *            whether the encoded-word is to be used to replace a text token
    284      *            or a word entity (see RFC 822).
    285      * @param usedCharacters
    286      *            number of characters already used up (<code>0 <= usedCharacters <= 50</code>).
    287      * @return the encoded word (or sequence of encoded words if the given text
    288      *         does not fit in a single encoded word).
    289      * @see #hasToBeEncoded(String, int)
    290      */
    291     public static String encodeEncodedWord(String text, Usage usage,
    292             int usedCharacters) {
    293         return encodeEncodedWord(text, usage, usedCharacters, null, null);
    294     }
    295 
    296     /**
    297      * Encodes the specified text into an encoded word or a sequence of encoded
    298      * words separated by space. The text is separated into a sequence of
    299      * encoded words if it does not fit in a single one.
    300      *
    301      * @param text
    302      *            text to encode.
    303      * @param usage
    304      *            whether the encoded-word is to be used to replace a text token
    305      *            or a word entity (see RFC 822).
    306      * @param usedCharacters
    307      *            number of characters already used up (<code>0 <= usedCharacters <= 50</code>).
    308      * @param charset
    309      *            the Java charset that should be used to encode the specified
    310      *            string into a byte array. A suitable charset is detected
    311      *            automatically if this parameter is <code>null</code>.
    312      * @param encoding
    313      *            the encoding to use for the encoded-word (either B or Q). A
    314      *            suitable encoding is automatically chosen if this parameter is
    315      *            <code>null</code>.
    316      * @return the encoded word (or sequence of encoded words if the given text
    317      *         does not fit in a single encoded word).
    318      * @see #hasToBeEncoded(String, int)
    319      */
    320     public static String encodeEncodedWord(String text, Usage usage,
    321             int usedCharacters, Charset charset, Encoding encoding) {
    322         if (text == null)
    323             throw new IllegalArgumentException();
    324         if (usedCharacters < 0 || usedCharacters > MAX_USED_CHARACTERS)
    325             throw new IllegalArgumentException();
    326 
    327         if (charset == null)
    328             charset = determineCharset(text);
    329 
    330         String mimeCharset = CharsetUtil.toMimeCharset(charset.name());
    331         if (mimeCharset == null) {
    332             // cannot happen if charset was originally null
    333             throw new IllegalArgumentException("Unsupported charset");
    334         }
    335 
    336         byte[] bytes = encode(text, charset);
    337 
    338         if (encoding == null)
    339             encoding = determineEncoding(bytes, usage);
    340 
    341         if (encoding == Encoding.B) {
    342             String prefix = ENC_WORD_PREFIX + mimeCharset + "?B?";
    343             return encodeB(prefix, text, usedCharacters, charset, bytes);
    344         } else {
    345             String prefix = ENC_WORD_PREFIX + mimeCharset + "?Q?";
    346             return encodeQ(prefix, text, usage, usedCharacters, charset, bytes);
    347         }
    348     }
    349 
    350     /**
    351      * Encodes the specified byte array using the B encoding defined in RFC
    352      * 2047.
    353      *
    354      * @param bytes
    355      *            byte array to encode.
    356      * @return encoded string.
    357      */
    358     public static String encodeB(byte[] bytes) {
    359         StringBuilder sb = new StringBuilder();
    360 
    361         int idx = 0;
    362         final int end = bytes.length;
    363         for (; idx < end - 2; idx += 3) {
    364             int data = (bytes[idx] & 0xff) << 16 | (bytes[idx + 1] & 0xff) << 8
    365                     | bytes[idx + 2] & 0xff;
    366             sb.append((char) BASE64_TABLE[data >> 18 & 0x3f]);
    367             sb.append((char) BASE64_TABLE[data >> 12 & 0x3f]);
    368             sb.append((char) BASE64_TABLE[data >> 6 & 0x3f]);
    369             sb.append((char) BASE64_TABLE[data & 0x3f]);
    370         }
    371 
    372         if (idx == end - 2) {
    373             int data = (bytes[idx] & 0xff) << 16 | (bytes[idx + 1] & 0xff) << 8;
    374             sb.append((char) BASE64_TABLE[data >> 18 & 0x3f]);
    375             sb.append((char) BASE64_TABLE[data >> 12 & 0x3f]);
    376             sb.append((char) BASE64_TABLE[data >> 6 & 0x3f]);
    377             sb.append((char) BASE64_PAD);
    378 
    379         } else if (idx == end - 1) {
    380             int data = (bytes[idx] & 0xff) << 16;
    381             sb.append((char) BASE64_TABLE[data >> 18 & 0x3f]);
    382             sb.append((char) BASE64_TABLE[data >> 12 & 0x3f]);
    383             sb.append((char) BASE64_PAD);
    384             sb.append((char) BASE64_PAD);
    385         }
    386 
    387         return sb.toString();
    388     }
    389 
    390     /**
    391      * Encodes the specified byte array using the Q encoding defined in RFC
    392      * 2047.
    393      *
    394      * @param bytes
    395      *            byte array to encode.
    396      * @param usage
    397      *            whether the encoded-word is to be used to replace a text token
    398      *            or a word entity (see RFC 822).
    399      * @return encoded string.
    400      */
    401     public static String encodeQ(byte[] bytes, Usage usage) {
    402         BitSet qChars = usage == Usage.TEXT_TOKEN ? Q_REGULAR_CHARS
    403                 : Q_RESTRICTED_CHARS;
    404 
    405         StringBuilder sb = new StringBuilder();
    406 
    407         final int end = bytes.length;
    408         for (int idx = 0; idx < end; idx++) {
    409             int v = bytes[idx] & 0xff;
    410             if (v == 32) {
    411                 sb.append('_');
    412             } else if (!qChars.get(v)) {
    413                 sb.append('=');
    414                 sb.append(hexDigit(v >>> 4));
    415                 sb.append(hexDigit(v & 0xf));
    416             } else {
    417                 sb.append((char) v);
    418             }
    419         }
    420 
    421         return sb.toString();
    422     }
    423 
    424     /**
    425      * Tests whether the specified string is a token as defined in RFC 2045
    426      * section 5.1.
    427      *
    428      * @param str
    429      *            string to test.
    430      * @return <code>true</code> if the specified string is a RFC 2045 token,
    431      *         <code>false</code> otherwise.
    432      */
    433     public static boolean isToken(String str) {
    434         // token := 1*<any (US-ASCII) CHAR except SPACE, CTLs, or tspecials>
    435         // tspecials := "(" / ")" / "<" / ">" / "@" / "," / ";" / ":" / "\" /
    436         // <"> / "/" / "[" / "]" / "?" / "="
    437         // CTL := 0.- 31., 127.
    438 
    439         final int length = str.length();
    440         if (length == 0)
    441             return false;
    442 
    443         for (int idx = 0; idx < length; idx++) {
    444             char ch = str.charAt(idx);
    445             if (!TOKEN_CHARS.get(ch))
    446                 return false;
    447         }
    448 
    449         return true;
    450     }
    451 
    452     private static boolean isAtomPhrase(String str) {
    453         // atom = [CFWS] 1*atext [CFWS]
    454 
    455         boolean containsAText = false;
    456 
    457         final int length = str.length();
    458         for (int idx = 0; idx < length; idx++) {
    459             char ch = str.charAt(idx);
    460             if (ATEXT_CHARS.get(ch)) {
    461                 containsAText = true;
    462             } else if (!CharsetUtil.isWhitespace(ch)) {
    463                 return false;
    464             }
    465         }
    466 
    467         return containsAText;
    468     }
    469 
    470     // RFC 5322 section 3.2.3
    471     private static boolean isDotAtomText(String str) {
    472         // dot-atom-text = 1*atext *("." 1*atext)
    473         // atext = ALPHA / DIGIT / "!" / "#" / "$" / "%" / "&" / "'" / "*" /
    474         // "+" / "-" / "/" / "=" / "?" / "^" / "_" / "`" / "{" / "|" / "}" / "~"
    475 
    476         char prev = '.';
    477 
    478         final int length = str.length();
    479         if (length == 0)
    480             return false;
    481 
    482         for (int idx = 0; idx < length; idx++) {
    483             char ch = str.charAt(idx);
    484 
    485             if (ch == '.') {
    486                 if (prev == '.' || idx == length - 1)
    487                     return false;
    488             } else {
    489                 if (!ATEXT_CHARS.get(ch))
    490                     return false;
    491             }
    492 
    493             prev = ch;
    494         }
    495 
    496         return true;
    497     }
    498 
    499     // RFC 5322 section 3.2.4
    500     private static String quote(String str) {
    501         // quoted-string = [CFWS] DQUOTE *([FWS] qcontent) [FWS] DQUOTE [CFWS]
    502         // qcontent = qtext / quoted-pair
    503         // qtext = %d33 / %d35-91 / %d93-126
    504         // quoted-pair = ("\" (VCHAR / WSP))
    505         // VCHAR = %x21-7E
    506         // DQUOTE = %x22
    507 
    508         String escaped = str.replaceAll("[\\\\\"]", "\\\\$0");
    509         return "\"" + escaped + "\"";
    510     }
    511 
    512     private static String encodeB(String prefix, String text,
    513             int usedCharacters, Charset charset, byte[] bytes) {
    514         int encodedLength = bEncodedLength(bytes);
    515 
    516         int totalLength = prefix.length() + encodedLength
    517                 + ENC_WORD_SUFFIX.length();
    518         if (totalLength <= ENCODED_WORD_MAX_LENGTH - usedCharacters) {
    519             return prefix + encodeB(bytes) + ENC_WORD_SUFFIX;
    520         } else {
    521             int splitOffset = text.offsetByCodePoints(text.length() / 2, -1);
    522 
    523             String part1 = text.substring(0, splitOffset);
    524             byte[] bytes1 = encode(part1, charset);
    525             String word1 = encodeB(prefix, part1, usedCharacters, charset,
    526                     bytes1);
    527 
    528             String part2 = text.substring(splitOffset);
    529             byte[] bytes2 = encode(part2, charset);
    530             String word2 = encodeB(prefix, part2, 0, charset, bytes2);
    531 
    532             return word1 + " " + word2;
    533         }
    534     }
    535 
    536     private static int bEncodedLength(byte[] bytes) {
    537         return (bytes.length + 2) / 3 * 4;
    538     }
    539 
    540     private static String encodeQ(String prefix, String text, Usage usage,
    541             int usedCharacters, Charset charset, byte[] bytes) {
    542         int encodedLength = qEncodedLength(bytes, usage);
    543 
    544         int totalLength = prefix.length() + encodedLength
    545                 + ENC_WORD_SUFFIX.length();
    546         if (totalLength <= ENCODED_WORD_MAX_LENGTH - usedCharacters) {
    547             return prefix + encodeQ(bytes, usage) + ENC_WORD_SUFFIX;
    548         } else {
    549             int splitOffset = text.offsetByCodePoints(text.length() / 2, -1);
    550 
    551             String part1 = text.substring(0, splitOffset);
    552             byte[] bytes1 = encode(part1, charset);
    553             String word1 = encodeQ(prefix, part1, usage, usedCharacters,
    554                     charset, bytes1);
    555 
    556             String part2 = text.substring(splitOffset);
    557             byte[] bytes2 = encode(part2, charset);
    558             String word2 = encodeQ(prefix, part2, usage, 0, charset, bytes2);
    559 
    560             return word1 + " " + word2;
    561         }
    562     }
    563 
    564     private static int qEncodedLength(byte[] bytes, Usage usage) {
    565         BitSet qChars = usage == Usage.TEXT_TOKEN ? Q_REGULAR_CHARS
    566                 : Q_RESTRICTED_CHARS;
    567 
    568         int count = 0;
    569 
    570         for (int idx = 0; idx < bytes.length; idx++) {
    571             int v = bytes[idx] & 0xff;
    572             if (v == 32) {
    573                 count++;
    574             } else if (!qChars.get(v)) {
    575                 count += 3;
    576             } else {
    577                 count++;
    578             }
    579         }
    580 
    581         return count;
    582     }
    583 
    584     private static byte[] encode(String text, Charset charset) {
    585         ByteBuffer buffer = charset.encode(text);
    586         byte[] bytes = new byte[buffer.limit()];
    587         buffer.get(bytes);
    588         return bytes;
    589     }
    590 
    591     private static Charset determineCharset(String text) {
    592         // it is an important property of iso-8859-1 that it directly maps
    593         // unicode code points 0000 to 00ff to byte values 00 to ff.
    594         boolean ascii = true;
    595         final int len = text.length();
    596         for (int index = 0; index < len; index++) {
    597             char ch = text.charAt(index);
    598             if (ch > 0xff) {
    599                 return CharsetUtil.UTF_8;
    600             }
    601             if (ch > 0x7f) {
    602                 ascii = false;
    603             }
    604         }
    605         return ascii ? CharsetUtil.US_ASCII : CharsetUtil.ISO_8859_1;
    606     }
    607 
    608     private static Encoding determineEncoding(byte[] bytes, Usage usage) {
    609         if (bytes.length == 0)
    610             return Encoding.Q;
    611 
    612         BitSet qChars = usage == Usage.TEXT_TOKEN ? Q_REGULAR_CHARS
    613                 : Q_RESTRICTED_CHARS;
    614 
    615         int qEncoded = 0;
    616         for (int i = 0; i < bytes.length; i++) {
    617             int v = bytes[i] & 0xff;
    618             if (v != 32 && !qChars.get(v)) {
    619                 qEncoded++;
    620             }
    621         }
    622 
    623         int percentage = qEncoded * 100 / bytes.length;
    624         return percentage > 30 ? Encoding.B : Encoding.Q;
    625     }
    626 
    627     private static char hexDigit(int i) {
    628         return i < 10 ? (char) (i + '0') : (char) (i - 10 + 'A');
    629     }
    630 }
    631