android-platform-libcore/luni/src/main/java/java/util/regex/Pattern.java - nest-cam/4320010/android-platform-libcore - Git at Google

 /*
  * Copyright (C) 2007 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 package java.util.regex;

 import java.io.IOException;
 import java.io.ObjectInputStream;
 import java.io.Serializable;

 /**
  * Patterns are compiled regular expressions. In many cases, convenience methods such as
  * {@link String#matches String.matches}, {@link String#replaceAll String.replaceAll} and
  * {@link String#split String.split} will be preferable, but if you need to do a lot of work
  * with the same regular expression, it may be more efficient to compile it once and reuse it.
  * The {@code Pattern} class and its companion, {@link Matcher}, also offer more functionality
  * than the small amount exposed by {@code String}.
  *
  * <pre>
  * // String convenience methods:
  * boolean sawFailures = s.matches("Failures: \\d+");
  * String farewell = s.replaceAll("Hello, (\\S+)", "Goodbye, $1");
  * String[] fields = s.split(":");
  *
  * // Direct use of Pattern:
  * Pattern p = Pattern.compile("Hello, (\\S+)");
  * Matcher m = p.matcher(inputString);
  * while (m.find()) { // Find each match in turn; String can't do this.
  *     String name = m.group(1); // Access a submatch group; String can't do this.
  * }
  * </pre>
  *
  * <h3>Regular expression syntax</h3>
  * <span class="datatable">
  * <style type="text/css">
  * .datatable td { padding-right: 20px; }
  * </style>
  *
  * <p>Java supports a subset of Perl 5 regular expression syntax. An important gotcha is that Java
  * has no regular expression literals, and uses plain old string literals instead. This means that
  * you need an extra level of escaping. For example, the regular expression {@code \s+} has to
  * be represented as the string {@code "\\s+"}.
  *
  * <h3>Escape sequences</h3>
  * <p><table>
  * <tr> <td> \ </td> <td>Quote the following metacharacter (so {@code \.} matches a literal {@code .}).</td> </tr>
  * <tr> <td> \Q </td> <td>Quote all following metacharacters until {@code \E}.</td> </tr>
  * <tr> <td> \E </td> <td>Stop quoting metacharacters (started by {@code \Q}).</td> </tr>
  * <tr> <td> \\ </td> <td>A literal backslash.</td> </tr>
  * <tr> <td> &#x005c;u<i>hhhh</i> </td> <td>The Unicode character U+hhhh (in hex).</td> </tr>
  * <tr> <td> &#x005c;x<i>hh</i> </td> <td>The Unicode character U+00hh (in hex).</td> </tr>
  * <tr> <td> \c<i>x</i> </td> <td>The ASCII control character ^x (so {@code \cH} would be ^H, U+0008).</td> </tr>
  *
  * <tr> <td> \a </td> <td>The ASCII bell character (U+0007).</td> </tr>
  * <tr> <td> \e </td> <td>The ASCII ESC character (U+001b).</td> </tr>
  * <tr> <td> \f </td> <td>The ASCII form feed character (U+000c).</td> </tr>
  * <tr> <td> \n </td> <td>The ASCII newline character (U+000a).</td> </tr>
  * <tr> <td> \r </td> <td>The ASCII carriage return character (U+000d).</td> </tr>
  * <tr> <td> \t </td> <td>The ASCII tab character (U+0009).</td> </tr>
  * </table>
  *
  * <h3>Character classes</h3>
  * <p>It's possible to construct arbitrary character classes using set operations:
  * <table>
  * <tr> <td> [abc] </td> <td>Any one of {@code a}, {@code b}, or {@code c}. (Enumeration.)</td> </tr>
  * <tr> <td> [a-c] </td> <td>Any one of {@code a}, {@code b}, or {@code c}. (Range.)</td> </tr>
  * <tr> <td> [^abc] </td> <td>Any character <i>except</i> {@code a}, {@code b}, or {@code c}. (Negation.)</td> </tr>
  * <tr> <td> [[a-f][0-9]] </td> <td>Any character in either range. (Union.)</td> </tr>
  * <tr> <td> [[a-z]&&[jkl]] </td> <td>Any character in both ranges. (Intersection.)</td> </tr>
  * </table>
  * <p>Most of the time, the built-in character classes are more useful:
  * <table>
  * <tr> <td> \d </td> <td>Any digit character.</td> </tr>
  * <tr> <td> \D </td> <td>Any non-digit character.</td> </tr>
  * <tr> <td> \s </td> <td>Any whitespace character.</td> </tr>
  * <tr> <td> \S </td> <td>Any non-whitespace character.</td> </tr>
  * <tr> <td> \w </td> <td>Any word character.</td> </tr>
  * <tr> <td> \W </td> <td>Any non-word character.</td> </tr>
  * <tr> <td> \p{<i>NAME</i>} </td> <td> Any character in the class with the given <i>NAME</i>. </td> </tr>
  * <tr> <td> \P{<i>NAME</i>} </td> <td> Any character <i>not</i> in the named class. </td> </tr>
  * </table>
  * <p>There are a variety of named classes:
  * <ul>
  * <li><a href="../../lang/Character.html#unicode_categories">Unicode category names</a>,
  * prefixed by {@code Is}. For example {@code \p{IsLu}} for all uppercase letters.
  * <li>POSIX class names. These are 'Alnum', 'Alpha', 'ASCII', 'Blank', 'Cntrl', 'Digit',
  * 'Graph', 'Lower', 'Print', 'Punct', 'Upper', 'XDigit'.
  * <li>Unicode block names, as used by {@link java.lang.Character.UnicodeBlock#forName} prefixed
  * by {@code In}. For example {@code \p{InHebrew}} for all characters in the Hebrew block.
  * <li>Character method names. These are all non-deprecated methods from {@link java.lang.Character}
  * whose name starts with {@code is}, but with the {@code is} replaced by {@code java}.
  * For example, {@code \p{javaLowerCase}}.
  * </ul>
  *
  * <h3>Quantifiers</h3>
  * <p>Quantifiers match some number of instances of the preceding regular expression.
  * <table>
  * <tr> <td> * </td> <td>Zero or more.</td> </tr>
  * <tr> <td> ? </td> <td>Zero or one.</td> </tr>
  * <tr> <td> + </td> <td>One or more.</td> </tr>
  * <tr> <td> {<i>n</i>} </td> <td>Exactly <i>n</i>.</td> </tr>
  * <tr> <td> {<i>n,</i>} </td> <td>At least <i>n</i>.</td> </tr>
  * <tr> <td> {<i>n</i>,<i>m</i>} </td> <td>At least <i>n</i> but not more than <i>m</i>.</td> </tr>
  * </table>
  * <p>Quantifiers are "greedy" by default, meaning that they will match the longest possible input
  * sequence. There are also non-greedy quantifiers that match the shortest possible input sequence.
  * They're same as the greedy ones but with a trailing {@code ?}:
  * <table>
  * <tr> <td> *? </td> <td>Zero or more (non-greedy).</td> </tr>
  * <tr> <td> ?? </td> <td>Zero or one (non-greedy).</td> </tr>
  * <tr> <td> +? </td> <td>One or more (non-greedy).</td> </tr>
  * <tr> <td> {<i>n</i>}? </td> <td>Exactly <i>n</i> (non-greedy).</td> </tr>
  * <tr> <td> {<i>n,</i>}? </td> <td>At least <i>n</i> (non-greedy).</td> </tr>
  * <tr> <td> {<i>n</i>,<i>m</i>}? </td> <td>At least <i>n</i> but not more than <i>m</i> (non-greedy).</td> </tr>
  * </table>
  * <p>Quantifiers allow backtracking by default. There are also possessive quantifiers to prevent
  * backtracking. They're same as the greedy ones but with a trailing {@code +}:
  * <table>
  * <tr> <td> *+ </td> <td>Zero or more (possessive).</td> </tr>
  * <tr> <td> ?+ </td> <td>Zero or one (possessive).</td> </tr>
  * <tr> <td> ++ </td> <td>One or more (possessive).</td> </tr>
  * <tr> <td> {<i>n</i>}+ </td> <td>Exactly <i>n</i> (possessive).</td> </tr>
  * <tr> <td> {<i>n,</i>}+ </td> <td>At least <i>n</i> (possessive).</td> </tr>
  * <tr> <td> {<i>n</i>,<i>m</i>}+ </td> <td>At least <i>n</i> but not more than <i>m</i> (possessive).</td> </tr>
  * </table>
  *
  * <h3>Zero-width assertions</h3>
  * <p><table>
  * <tr> <td> ^ </td> <td>At beginning of line.</td> </tr>
  * <tr> <td> $ </td> <td>At end of line.</td> </tr>
  * <tr> <td> \A </td> <td>At beginning of input.</td> </tr>
  * <tr> <td> \b </td> <td>At word boundary.</td> </tr>
  * <tr> <td> \B </td> <td>At non-word boundary.</td> </tr>
  * <tr> <td> \G </td> <td>At end of previous match.</td> </tr>
  * <tr> <td> \z </td> <td>At end of input.</td> </tr>
  * <tr> <td> \Z </td> <td>At end of input, or before newline at end.</td> </tr>
  * </table>
  *
  * <h3>Look-around assertions</h3>
  * <p>Look-around assertions assert that the subpattern does (positive) or doesn't (negative) match
  * after (look-ahead) or before (look-behind) the current position, without including the matched
  * text in the containing match. The maximum length of possible matches for look-behind patterns
  * must not be unbounded.
  * <p><table>
  * <tr> <td> (?=<i>a</i>) </td> <td>Zero-width positive look-ahead.</td> </tr>
  * <tr> <td> (?!<i>a</i>) </td> <td>Zero-width negative look-ahead.</td> </tr>
  * <tr> <td> (?&lt;=<i>a</i>) </td> <td>Zero-width positive look-behind.</td> </tr>
  * <tr> <td> (?&lt;!<i>a</i>) </td> <td>Zero-width negative look-behind.</td> </tr>
  * </table>
  *
  * <h3>Groups</h3>
  *
  * <p><table>
  * <tr> <td> (<i>a</i>) </td> <td>A capturing group.</td> </tr>
  * <tr> <td> (?:<i>a</i>) </td> <td>A non-capturing group.</td> </tr>
  * <tr> <td> (?&gt;<i>a</i>) </td> <td>An independent non-capturing group. (The first match of the subgroup is the only match tried.)</td> </tr>
  * <tr> <td> \<i>n</i> </td> <td>The text already matched by capturing group <i>n</i>.</td> </tr>
  * </table>
  * <p>See {@link Matcher#group} for details of how capturing groups are numbered and accessed.
  *
  * <h3>Operators</h3>
  * <p><table>
  * <tr> <td> <i>ab</i> </td> <td>Expression <i>a</i> followed by expression <i>b</i>.</td> </tr>
  * <tr> <td> <i>a</i>|<i>b</i> </td> <td>Either expression <i>a</i> or expression <i>b</i>.</td> </tr>
  * </table>
  *
  * <a name="flags"><h3>Flags</h3></a>
  * <p><table>
  * <tr> <td> (?dimsux-dimsux:<i>a</i>) </td> <td>Evaluates the expression <i>a</i> with the given flags enabled/disabled.</td> </tr>
  * <tr> <td> (?dimsux-dimsux) </td> <td>Evaluates the rest of the pattern with the given flags enabled/disabled.</td> </tr>
  * </table>
  *
  * <p>The flags are:
  * <table>
  * <tr><td>{@code i}</td> <td>{@link #CASE_INSENSITIVE}</td> <td>case insensitive matching</td></tr>
  * <tr><td>{@code d}</td> <td>{@link #UNIX_LINES}</td>       <td>only accept {@code '\n'} as a line terminator</td></tr>
  * <tr><td>{@code m}</td> <td>{@link #MULTILINE}</td>        <td>allow {@code ^} and {@code $} to match beginning/end of any line</td></tr>
  * <tr><td>{@code s}</td> <td>{@link #DOTALL}</td>           <td>allow {@code .} to match {@code '\n'} ("s" for "single line")</td></tr>
  * <tr><td>{@code u}</td> <td>{@link #UNICODE_CASE}</td>     <td>enable Unicode case folding</td></tr>
  * <tr><td>{@code x}</td> <td>{@link #COMMENTS}</td>         <td>allow whitespace and comments</td></tr>
  * </table>
  * <p>Either set of flags may be empty. For example, {@code (?i-m)} would turn on case-insensitivity
  * and turn off multiline mode, {@code (?i)} would just turn on case-insensitivity,
  * and {@code (?-m)} would just turn off multiline mode.
  * <p>Note that on Android, {@code UNICODE_CASE} is always on: case-insensitive matching will
  * always be Unicode-aware.
  * <p>There are two other flags not settable via this mechanism: {@link #CANON_EQ} and
  * {@link #LITERAL}. Attempts to use {@link #CANON_EQ} on Android will throw an exception.
  * </span>
  *
  * <h3>Implementation notes</h3>
  *
  * <p>The regular expression implementation used in Android is provided by
  * <a href="http://www.icu-project.org">ICU</a>. The notation for the regular
  * expressions is mostly a superset of those used in other Java language
  * implementations. This means that existing applications will normally work as
  * expected, but in rare cases Android may accept a regular expression that is
  * not accepted by other implementations.
  *
  * <p>In some cases, Android will recognize that a regular expression is a simple
  * special case that can be handled more efficiently. This is true of both the convenience methods
  * in {@code String} and the methods in {@code Pattern}.
  *
  * @see Matcher
  */
 public final class Pattern implements Serializable {

     private static final long serialVersionUID = 5073258162644648461L;

     /**
      * This constant specifies that a pattern matches Unix line endings ('\n')
      * only against the '.', '^', and '$' meta characters. Corresponds to {@code (?d)}.
      */
     public static final int UNIX_LINES = 0x01;

     /**
      * This constant specifies that a {@code Pattern} is matched
      * case-insensitively. That is, the patterns "a+" and "A+" would both match
      * the string "aAaAaA". See {@link #UNICODE_CASE}. Corresponds to {@code (?i)}.
      */
     public static final int CASE_INSENSITIVE = 0x02;

     /**
      * This constant specifies that a {@code Pattern} may contain whitespace or
      * comments. Otherwise comments and whitespace are taken as literal
      * characters. Corresponds to {@code (?x)}.
      */
     public static final int COMMENTS = 0x04;

     /**
      * This constant specifies that the meta characters '^' and '$' match only
      * the beginning and end of an input line, respectively. Normally, they
      * match the beginning and the end of the complete input. Corresponds to {@code (?m)}.
      */
     public static final int MULTILINE = 0x08;

     /**
      * This constant specifies that the whole {@code Pattern} is to be taken
      * literally, that is, all meta characters lose their meanings.
      */
     public static final int LITERAL = 0x10;

     /**
      * This constant specifies that the '.' meta character matches arbitrary
      * characters, including line endings, which is normally not the case.
      * Corresponds to {@code (?s)}.
      */
     public static final int DOTALL = 0x20;

     /**
      * This constant specifies that a {@code Pattern} that uses case-insensitive matching
      * will use Unicode case folding. On Android, {@code UNICODE_CASE} is always on:
      * case-insensitive matching will always be Unicode-aware. If your code is intended to
      * be portable and uses case-insensitive matching on non-ASCII characters, you should
      * use this flag. Corresponds to {@code (?u)}.
      */
     public static final int UNICODE_CASE = 0x40;

     /**
      * This constant specifies that a character in a {@code Pattern} and a
      * character in the input string only match if they are canonically
      * equivalent. It is (currently) not supported in Android.
      */
     public static final int CANON_EQ = 0x80;

     private final String pattern;
     private final int flags;

     transient int address;

     /**
      * Returns a {@link Matcher} for this pattern applied to the given {@code input}.
      * The {@code Matcher} can be used to match the {@code Pattern} against the
      * whole input, find occurrences of the {@code Pattern} in the input, or
      * replace parts of the input.
      */
     public Matcher matcher(CharSequence input) {
         return new Matcher(this, input);
     }

     /**
      * Splits the given {@code input} at occurrences of this pattern.
      *
      * <p>If this pattern does not occur in the input, the result is an
      * array containing the input (converted from a {@code CharSequence} to
      * a {@code String}).
      *
      * <p>Otherwise, the {@code limit} parameter controls the contents of the
      * returned array as described below.
      *
      * @param limit
      *            Determines the maximum number of entries in the resulting
      *            array, and the treatment of trailing empty strings.
      *            <ul>
      *            <li>For n &gt; 0, the resulting array contains at most n
      *            entries. If this is fewer than the number of matches, the
      *            final entry will contain all remaining input.
      *            <li>For n &lt; 0, the length of the resulting array is
      *            exactly the number of occurrences of the {@code Pattern}
      *            plus one for the text after the final separator.
      *            All entries are included.
      *            <li>For n == 0, the result is as for n &lt; 0, except
      *            trailing empty strings will not be returned. (Note that
      *            the case where the input is itself an empty string is
      *            special, as described above, and the limit parameter does
      *            not apply there.)
      *            </ul>
      */
     public String[] split(CharSequence input, int limit) {
         return Splitter.split(this, pattern, input.toString(), limit);
     }

     /**
      * Equivalent to {@code split(input, 0)}.
      */
     public String[] split(CharSequence input) {
         return split(input, 0);
     }

     /**
      * Returns the regular expression supplied to {@code compile}.
      */
     public String pattern() {
         return pattern;
     }

     @Override
     public String toString() {
         return pattern;
     }

     /**
      * Returns the flags supplied to {@code compile}.
      */
     public int flags() {
         return flags;
     }

     /**
      * Returns a compiled form of the given {@code regularExpression}, as modified by the
      * given {@code flags}. See the <a href="#flags">flags overview</a> for more on flags.
      *
      * @throws PatternSyntaxException if the regular expression is syntactically incorrect.
      *
      * @see #CANON_EQ
      * @see #CASE_INSENSITIVE
      * @see #COMMENTS
      * @see #DOTALL
      * @see #LITERAL
      * @see #MULTILINE
      * @see #UNICODE_CASE
      * @see #UNIX_LINES
      */
     public static Pattern compile(String regularExpression, int flags) throws PatternSyntaxException {
         return new Pattern(regularExpression, flags);
     }

     /**
      * Equivalent to {@code Pattern.compile(pattern, 0)}.
      */
     public static Pattern compile(String pattern) {
         return new Pattern(pattern, 0);
     }

     private Pattern(String pattern, int flags) throws PatternSyntaxException {
         if ((flags & CANON_EQ) != 0) {
             throw new UnsupportedOperationException("CANON_EQ flag not supported");
         }
         this.pattern = pattern;
         this.flags = flags;
         compile();
     }

     private void compile() throws PatternSyntaxException {
         if (pattern == null) {
             throw new NullPointerException("pattern == null");
         }

         String icuPattern = pattern;
         if ((flags & LITERAL) != 0) {
             icuPattern = quote(pattern);
         }

         // These are the flags natively supported by ICU.
         // They even have the same value in native code.
         int icuFlags = flags & (CASE_INSENSITIVE | COMMENTS | MULTILINE | DOTALL | UNIX_LINES);

         address = compileImpl(icuPattern, icuFlags);
     }

     /**
      * Tests whether the given {@code regularExpression} matches the given {@code input}.
      * Equivalent to {@code Pattern.compile(regularExpression).matcher(input).matches()}.
      * If the same regular expression is to be used for multiple operations, it may be more
      * efficient to reuse a compiled {@code Pattern}.
      *
      * @see Pattern#compile(java.lang.String, int)
      * @see Matcher#matches()
      */
     public static boolean matches(String regularExpression, CharSequence input) {
         return new Matcher(new Pattern(regularExpression, 0), input).matches();
     }

     /**
      * Quotes the given {@code string} using "\Q" and "\E", so that all
      * meta-characters lose their special meaning. This method correctly
      * escapes embedded instances of "\Q" or "\E". If the entire result
      * is to be passed verbatim to {@link #compile}, it's usually clearer
      * to use the {@link #LITERAL} flag instead.
      */
     public static String quote(String string) {
         StringBuilder sb = new StringBuilder();
         sb.append("\\Q");
         int apos = 0;
         int k;
         while ((k = string.indexOf("\\E", apos)) >= 0) {
             sb.append(string.substring(apos, k + 2)).append("\\\\E\\Q");
             apos = k + 2;
         }
         return sb.append(string.substring(apos)).append("\\E").toString();
     }

     @Override protected void finalize() throws Throwable {
         try {
             closeImpl(address);
         } finally {
             super.finalize();
         }
     }

     private void readObject(ObjectInputStream s) throws IOException, ClassNotFoundException {
         s.defaultReadObject();
         compile();
     }

     private static native void closeImpl(int addr);
     private static native int compileImpl(String regex, int flags);
 }
	/*
	* Copyright (C) 2007 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	package java.util.regex;

	import java.io.IOException;
	import java.io.ObjectInputStream;
	import java.io.Serializable;

	/**
	* Patterns are compiled regular expressions. In many cases, convenience methods such as
	* {@link String#matches String.matches}, {@link String#replaceAll String.replaceAll} and
	* {@link String#split String.split} will be preferable, but if you need to do a lot of work
	* with the same regular expression, it may be more efficient to compile it once and reuse it.
	* The {@code Pattern} class and its companion, {@link Matcher}, also offer more functionality
	* than the small amount exposed by {@code String}.
	*
	* <pre>
	* // String convenience methods:
	* boolean sawFailures = s.matches("Failures: \\d+");
	* String farewell = s.replaceAll("Hello, (\\S+)", "Goodbye, $1");
	* String[] fields = s.split(":");
	*
	* // Direct use of Pattern:
	* Pattern p = Pattern.compile("Hello, (\\S+)");
	* Matcher m = p.matcher(inputString);
	* while (m.find()) { // Find each match in turn; String can't do this.
	* String name = m.group(1); // Access a submatch group; String can't do this.
	* }
	* </pre>
	*
	* <h3>Regular expression syntax</h3>
	* <span class="datatable">
	* <style type="text/css">
	* .datatable td { padding-right: 20px; }
	* </style>
	*
	* <p>Java supports a subset of Perl 5 regular expression syntax. An important gotcha is that Java
	* has no regular expression literals, and uses plain old string literals instead. This means that
	* you need an extra level of escaping. For example, the regular expression {@code \s+} has to
	* be represented as the string {@code "\\s+"}.
	*
	* <h3>Escape sequences</h3>
	* <p><table>
	* <tr> <td> \ </td> <td>Quote the following metacharacter (so {@code \.} matches a literal {@code .}).</td> </tr>
	* <tr> <td> \Q </td> <td>Quote all following metacharacters until {@code \E}.</td> </tr>
	* <tr> <td> \E </td> <td>Stop quoting metacharacters (started by {@code \Q}).</td> </tr>
	* <tr> <td> \\ </td> <td>A literal backslash.</td> </tr>
	* <tr> <td> \u<i>hhhh</i> </td> <td>The Unicode character U+hhhh (in hex).</td> </tr>
	* <tr> <td> \x<i>hh</i> </td> <td>The Unicode character U+00hh (in hex).</td> </tr>
	* <tr> <td> \c<i>x</i> </td> <td>The ASCII control character ^x (so {@code \cH} would be ^H, U+0008).</td> </tr>
	*
	* <tr> <td> \a </td> <td>The ASCII bell character (U+0007).</td> </tr>
	* <tr> <td> \e </td> <td>The ASCII ESC character (U+001b).</td> </tr>
	* <tr> <td> \f </td> <td>The ASCII form feed character (U+000c).</td> </tr>
	* <tr> <td> \n </td> <td>The ASCII newline character (U+000a).</td> </tr>
	* <tr> <td> \r </td> <td>The ASCII carriage return character (U+000d).</td> </tr>
	* <tr> <td> \t </td> <td>The ASCII tab character (U+0009).</td> </tr>
	* </table>
	*
	* <h3>Character classes</h3>
	* <p>It's possible to construct arbitrary character classes using set operations:
	* <table>
	* <tr> <td> [abc] </td> <td>Any one of {@code a}, {@code b}, or {@code c}. (Enumeration.)</td> </tr>
	* <tr> <td> [a-c] </td> <td>Any one of {@code a}, {@code b}, or {@code c}. (Range.)</td> </tr>
	* <tr> <td> [^abc] </td> <td>Any character <i>except</i> {@code a}, {@code b}, or {@code c}. (Negation.)</td> </tr>
	* <tr> <td> [[a-f][0-9]] </td> <td>Any character in either range. (Union.)</td> </tr>
	* <tr> <td> [[a-z]&&[jkl]] </td> <td>Any character in both ranges. (Intersection.)</td> </tr>
	* </table>
	* <p>Most of the time, the built-in character classes are more useful:
	* <table>
	* <tr> <td> \d </td> <td>Any digit character.</td> </tr>
	* <tr> <td> \D </td> <td>Any non-digit character.</td> </tr>
	* <tr> <td> \s </td> <td>Any whitespace character.</td> </tr>
	* <tr> <td> \S </td> <td>Any non-whitespace character.</td> </tr>
	* <tr> <td> \w </td> <td>Any word character.</td> </tr>
	* <tr> <td> \W </td> <td>Any non-word character.</td> </tr>
	* <tr> <td> \p{<i>NAME</i>} </td> <td> Any character in the class with the given <i>NAME</i>. </td> </tr>
	* <tr> <td> \P{<i>NAME</i>} </td> <td> Any character <i>not</i> in the named class. </td> </tr>
	* </table>
	* <p>There are a variety of named classes:
	* <ul>
	* <li><a href="../../lang/Character.html#unicode_categories">Unicode category names</a>,
	* prefixed by {@code Is}. For example {@code \p{IsLu}} for all uppercase letters.
	* <li>POSIX class names. These are 'Alnum', 'Alpha', 'ASCII', 'Blank', 'Cntrl', 'Digit',
	* 'Graph', 'Lower', 'Print', 'Punct', 'Upper', 'XDigit'.
	* <li>Unicode block names, as used by {@link java.lang.Character.UnicodeBlock#forName} prefixed
	* by {@code In}. For example {@code \p{InHebrew}} for all characters in the Hebrew block.
	* <li>Character method names. These are all non-deprecated methods from {@link java.lang.Character}
	* whose name starts with {@code is}, but with the {@code is} replaced by {@code java}.
	* For example, {@code \p{javaLowerCase}}.
	* </ul>
	*
	* <h3>Quantifiers</h3>
	* <p>Quantifiers match some number of instances of the preceding regular expression.
	* <table>
	* <tr> <td> * </td> <td>Zero or more.</td> </tr>
	* <tr> <td> ? </td> <td>Zero or one.</td> </tr>
	* <tr> <td> + </td> <td>One or more.</td> </tr>
	* <tr> <td> {<i>n</i>} </td> <td>Exactly <i>n</i>.</td> </tr>
	* <tr> <td> {<i>n,</i>} </td> <td>At least <i>n</i>.</td> </tr>
	* <tr> <td> {<i>n</i>,<i>m</i>} </td> <td>At least <i>n</i> but not more than <i>m</i>.</td> </tr>
	* </table>
	* <p>Quantifiers are "greedy" by default, meaning that they will match the longest possible input
	* sequence. There are also non-greedy quantifiers that match the shortest possible input sequence.
	* They're same as the greedy ones but with a trailing {@code ?}:
	* <table>
	* <tr> <td> *? </td> <td>Zero or more (non-greedy).</td> </tr>
	* <tr> <td> ?? </td> <td>Zero or one (non-greedy).</td> </tr>
	* <tr> <td> +? </td> <td>One or more (non-greedy).</td> </tr>
	* <tr> <td> {<i>n</i>}? </td> <td>Exactly <i>n</i> (non-greedy).</td> </tr>
	* <tr> <td> {<i>n,</i>}? </td> <td>At least <i>n</i> (non-greedy).</td> </tr>
	* <tr> <td> {<i>n</i>,<i>m</i>}? </td> <td>At least <i>n</i> but not more than <i>m</i> (non-greedy).</td> </tr>
	* </table>
	* <p>Quantifiers allow backtracking by default. There are also possessive quantifiers to prevent
	* backtracking. They're same as the greedy ones but with a trailing {@code +}:
	* <table>
	* <tr> <td> *+ </td> <td>Zero or more (possessive).</td> </tr>
	* <tr> <td> ?+ </td> <td>Zero or one (possessive).</td> </tr>
	* <tr> <td> ++ </td> <td>One or more (possessive).</td> </tr>
	* <tr> <td> {<i>n</i>}+ </td> <td>Exactly <i>n</i> (possessive).</td> </tr>
	* <tr> <td> {<i>n,</i>}+ </td> <td>At least <i>n</i> (possessive).</td> </tr>
	* <tr> <td> {<i>n</i>,<i>m</i>}+ </td> <td>At least <i>n</i> but not more than <i>m</i> (possessive).</td> </tr>
	* </table>
	*
	* <h3>Zero-width assertions</h3>
	* <p><table>
	* <tr> <td> ^ </td> <td>At beginning of line.</td> </tr>
	* <tr> <td> $ </td> <td>At end of line.</td> </tr>
	* <tr> <td> \A </td> <td>At beginning of input.</td> </tr>
	* <tr> <td> \b </td> <td>At word boundary.</td> </tr>
	* <tr> <td> \B </td> <td>At non-word boundary.</td> </tr>
	* <tr> <td> \G </td> <td>At end of previous match.</td> </tr>
	* <tr> <td> \z </td> <td>At end of input.</td> </tr>
	* <tr> <td> \Z </td> <td>At end of input, or before newline at end.</td> </tr>
	* </table>
	*
	* <h3>Look-around assertions</h3>
	* <p>Look-around assertions assert that the subpattern does (positive) or doesn't (negative) match
	* after (look-ahead) or before (look-behind) the current position, without including the matched
	* text in the containing match. The maximum length of possible matches for look-behind patterns
	* must not be unbounded.
	* <p><table>
	* <tr> <td> (?=<i>a</i>) </td> <td>Zero-width positive look-ahead.</td> </tr>
	* <tr> <td> (?!<i>a</i>) </td> <td>Zero-width negative look-ahead.</td> </tr>
	* <tr> <td> (?<=<i>a</i>) </td> <td>Zero-width positive look-behind.</td> </tr>
	* <tr> <td> (?<!<i>a</i>) </td> <td>Zero-width negative look-behind.</td> </tr>
	* </table>
	*
	* <h3>Groups</h3>
	*
	* <p><table>
	* <tr> <td> (<i>a</i>) </td> <td>A capturing group.</td> </tr>
	* <tr> <td> (?:<i>a</i>) </td> <td>A non-capturing group.</td> </tr>
	* <tr> <td> (?><i>a</i>) </td> <td>An independent non-capturing group. (The first match of the subgroup is the only match tried.)</td> </tr>
	* <tr> <td> \<i>n</i> </td> <td>The text already matched by capturing group <i>n</i>.</td> </tr>
	* </table>
	* <p>See {@link Matcher#group} for details of how capturing groups are numbered and accessed.
	*
	* <h3>Operators</h3>
	* <p><table>
	* <tr> <td> <i>ab</i> </td> <td>Expression <i>a</i> followed by expression <i>b</i>.</td> </tr>
	* <tr> <td> <i>a</i>\|<i>b</i> </td> <td>Either expression <i>a</i> or expression <i>b</i>.</td> </tr>
	* </table>
	*
	* <a name="flags"><h3>Flags</h3></a>
	* <p><table>
	* <tr> <td> (?dimsux-dimsux:<i>a</i>) </td> <td>Evaluates the expression <i>a</i> with the given flags enabled/disabled.</td> </tr>
	* <tr> <td> (?dimsux-dimsux) </td> <td>Evaluates the rest of the pattern with the given flags enabled/disabled.</td> </tr>
	* </table>
	*
	* <p>The flags are:
	* <table>
	* <tr><td>{@code i}</td> <td>{@link #CASE_INSENSITIVE}</td> <td>case insensitive matching</td></tr>
	* <tr><td>{@code d}</td> <td>{@link #UNIX_LINES}</td> <td>only accept {@code '\n'} as a line terminator</td></tr>
	* <tr><td>{@code m}</td> <td>{@link #MULTILINE}</td> <td>allow {@code ^} and {@code $} to match beginning/end of any line</td></tr>
	* <tr><td>{@code s}</td> <td>{@link #DOTALL}</td> <td>allow {@code .} to match {@code '\n'} ("s" for "single line")</td></tr>
	* <tr><td>{@code u}</td> <td>{@link #UNICODE_CASE}</td> <td>enable Unicode case folding</td></tr>
	* <tr><td>{@code x}</td> <td>{@link #COMMENTS}</td> <td>allow whitespace and comments</td></tr>
	* </table>
	* <p>Either set of flags may be empty. For example, {@code (?i-m)} would turn on case-insensitivity
	* and turn off multiline mode, {@code (?i)} would just turn on case-insensitivity,
	* and {@code (?-m)} would just turn off multiline mode.
	* <p>Note that on Android, {@code UNICODE_CASE} is always on: case-insensitive matching will
	* always be Unicode-aware.
	* <p>There are two other flags not settable via this mechanism: {@link #CANON_EQ} and
	* {@link #LITERAL}. Attempts to use {@link #CANON_EQ} on Android will throw an exception.
	* </span>
	*
	* <h3>Implementation notes</h3>
	*
	* <p>The regular expression implementation used in Android is provided by
	* <a href="http://www.icu-project.org">ICU</a>. The notation for the regular
	* expressions is mostly a superset of those used in other Java language
	* implementations. This means that existing applications will normally work as
	* expected, but in rare cases Android may accept a regular expression that is
	* not accepted by other implementations.
	*
	* <p>In some cases, Android will recognize that a regular expression is a simple
	* special case that can be handled more efficiently. This is true of both the convenience methods
	* in {@code String} and the methods in {@code Pattern}.
	*
	* @see Matcher
	*/
	public final class Pattern implements Serializable {

	private static final long serialVersionUID = 5073258162644648461L;

	/**
	* This constant specifies that a pattern matches Unix line endings ('\n')
	* only against the '.', '^', and '$' meta characters. Corresponds to {@code (?d)}.
	*/
	public static final int UNIX_LINES = 0x01;

	/**
	* This constant specifies that a {@code Pattern} is matched
	* case-insensitively. That is, the patterns "a+" and "A+" would both match
	* the string "aAaAaA". See {@link #UNICODE_CASE}. Corresponds to {@code (?i)}.
	*/
	public static final int CASE_INSENSITIVE = 0x02;

	/**
	* This constant specifies that a {@code Pattern} may contain whitespace or
	* comments. Otherwise comments and whitespace are taken as literal
	* characters. Corresponds to {@code (?x)}.
	*/
	public static final int COMMENTS = 0x04;

	/**
	* This constant specifies that the meta characters '^' and '$' match only
	* the beginning and end of an input line, respectively. Normally, they
	* match the beginning and the end of the complete input. Corresponds to {@code (?m)}.
	*/
	public static final int MULTILINE = 0x08;

	/**
	* This constant specifies that the whole {@code Pattern} is to be taken
	* literally, that is, all meta characters lose their meanings.
	*/
	public static final int LITERAL = 0x10;

	/**
	* This constant specifies that the '.' meta character matches arbitrary
	* characters, including line endings, which is normally not the case.
	* Corresponds to {@code (?s)}.
	*/
	public static final int DOTALL = 0x20;

	/**
	* This constant specifies that a {@code Pattern} that uses case-insensitive matching
	* will use Unicode case folding. On Android, {@code UNICODE_CASE} is always on:
	* case-insensitive matching will always be Unicode-aware. If your code is intended to
	* be portable and uses case-insensitive matching on non-ASCII characters, you should
	* use this flag. Corresponds to {@code (?u)}.
	*/
	public static final int UNICODE_CASE = 0x40;

	/**
	* This constant specifies that a character in a {@code Pattern} and a
	* character in the input string only match if they are canonically
	* equivalent. It is (currently) not supported in Android.
	*/
	public static final int CANON_EQ = 0x80;

	private final String pattern;
	private final int flags;

	transient int address;

	/**
	* Returns a {@link Matcher} for this pattern applied to the given {@code input}.
	* The {@code Matcher} can be used to match the {@code Pattern} against the
	* whole input, find occurrences of the {@code Pattern} in the input, or
	* replace parts of the input.
	*/
	public Matcher matcher(CharSequence input) {
	return new Matcher(this, input);
	}

	/**
	* Splits the given {@code input} at occurrences of this pattern.
	*
	* <p>If this pattern does not occur in the input, the result is an
	* array containing the input (converted from a {@code CharSequence} to
	* a {@code String}).
	*
	* <p>Otherwise, the {@code limit} parameter controls the contents of the
	* returned array as described below.
	*
	* @param limit
	* Determines the maximum number of entries in the resulting
	* array, and the treatment of trailing empty strings.
	* <ul>
	* <li>For n > 0, the resulting array contains at most n
	* entries. If this is fewer than the number of matches, the
	* final entry will contain all remaining input.
	* <li>For n < 0, the length of the resulting array is
	* exactly the number of occurrences of the {@code Pattern}
	* plus one for the text after the final separator.
	* All entries are included.
	* <li>For n == 0, the result is as for n < 0, except
	* trailing empty strings will not be returned. (Note that
	* the case where the input is itself an empty string is
	* special, as described above, and the limit parameter does
	* not apply there.)
	* </ul>
	*/
	public String[] split(CharSequence input, int limit) {
	return Splitter.split(this, pattern, input.toString(), limit);
	}

	/**
	* Equivalent to {@code split(input, 0)}.
	*/
	public String[] split(CharSequence input) {
	return split(input, 0);
	}

	/**
	* Returns the regular expression supplied to {@code compile}.
	*/
	public String pattern() {
	return pattern;
	}

	@Override
	public String toString() {
	return pattern;
	}

	/**
	* Returns the flags supplied to {@code compile}.
	*/
	public int flags() {
	return flags;
	}

	/**
	* Returns a compiled form of the given {@code regularExpression}, as modified by the
	* given {@code flags}. See the <a href="#flags">flags overview</a> for more on flags.
	*
	* @throws PatternSyntaxException if the regular expression is syntactically incorrect.
	*
	* @see #CANON_EQ
	* @see #CASE_INSENSITIVE
	* @see #COMMENTS
	* @see #DOTALL
	* @see #LITERAL
	* @see #MULTILINE
	* @see #UNICODE_CASE
	* @see #UNIX_LINES
	*/
	public static Pattern compile(String regularExpression, int flags) throws PatternSyntaxException {
	return new Pattern(regularExpression, flags);
	}

	/**
	* Equivalent to {@code Pattern.compile(pattern, 0)}.
	*/
	public static Pattern compile(String pattern) {
	return new Pattern(pattern, 0);
	}

	private Pattern(String pattern, int flags) throws PatternSyntaxException {
	if ((flags & CANON_EQ) != 0) {
	throw new UnsupportedOperationException("CANON_EQ flag not supported");
	}
	this.pattern = pattern;
	this.flags = flags;
	compile();
	}

	private void compile() throws PatternSyntaxException {
	if (pattern == null) {
	throw new NullPointerException("pattern == null");
	}

	String icuPattern = pattern;
	if ((flags & LITERAL) != 0) {
	icuPattern = quote(pattern);
	}

	// These are the flags natively supported by ICU.
	// They even have the same value in native code.
	int icuFlags = flags & (CASE_INSENSITIVE \| COMMENTS \| MULTILINE \| DOTALL \| UNIX_LINES);

	address = compileImpl(icuPattern, icuFlags);
	}

	/**
	* Tests whether the given {@code regularExpression} matches the given {@code input}.
	* Equivalent to {@code Pattern.compile(regularExpression).matcher(input).matches()}.
	* If the same regular expression is to be used for multiple operations, it may be more
	* efficient to reuse a compiled {@code Pattern}.
	*
	* @see Pattern#compile(java.lang.String, int)
	* @see Matcher#matches()
	*/
	public static boolean matches(String regularExpression, CharSequence input) {
	return new Matcher(new Pattern(regularExpression, 0), input).matches();
	}

	/**
	* Quotes the given {@code string} using "\Q" and "\E", so that all
	* meta-characters lose their special meaning. This method correctly
	* escapes embedded instances of "\Q" or "\E". If the entire result
	* is to be passed verbatim to {@link #compile}, it's usually clearer
	* to use the {@link #LITERAL} flag instead.
	*/
	public static String quote(String string) {
	StringBuilder sb = new StringBuilder();
	sb.append("\\Q");
	int apos = 0;
	int k;
	while ((k = string.indexOf("\\E", apos)) >= 0) {
	sb.append(string.substring(apos, k + 2)).append("\\\\E\\Q");
	apos = k + 2;
	}
	return sb.append(string.substring(apos)).append("\\E").toString();
	}

	@Override protected void finalize() throws Throwable {
	try {
	closeImpl(address);
	} finally {
	super.finalize();
	}
	}

	private void readObject(ObjectInputStream s) throws IOException, ClassNotFoundException {
	s.defaultReadObject();
	compile();
	}

	private static native void closeImpl(int addr);
	private static native int compileImpl(String regex, int flags);
	}