/* GENERATED SOURCE. DO NOT MODIFY. */ /* ******************************************************************************* * Copyright (C) 1996-2015, International Business Machines Corporation and * * others. All Rights Reserved. * ******************************************************************************* */ package android.icu.impl; import java.io.IOException; import java.util.ArrayList; import java.util.Locale; import java.util.regex.Pattern; import android.icu.lang.UCharacter; import android.icu.text.Replaceable; import android.icu.text.UTF16; import android.icu.text.UnicodeMatcher; /** * @hide Only a subset of ICU is exposed in Android */ public final class Utility { private static final char APOSTROPHE = '\''; private static final char BACKSLASH = '\\'; private static final int MAGIC_UNSIGNED = 0x80000000; /** * Convenience utility to compare two Object[]s. * Ought to be in System */ public final static boolean arrayEquals(Object[] source, Object target) { if (source == null) return (target == null); if (!(target instanceof Object[])) return false; Object[] targ = (Object[]) target; return (source.length == targ.length && arrayRegionMatches(source, 0, targ, 0, source.length)); } /** * Convenience utility to compare two int[]s * Ought to be in System */ public final static boolean arrayEquals(int[] source, Object target) { if (source == null) return (target == null); if (!(target instanceof int[])) return false; int[] targ = (int[]) target; return (source.length == targ.length && arrayRegionMatches(source, 0, targ, 0, source.length)); } /** * Convenience utility to compare two double[]s * Ought to be in System */ public final static boolean arrayEquals(double[] source, Object target) { if (source == null) return (target == null); if (!(target instanceof double[])) return false; double[] targ = (double[]) target; return (source.length == targ.length && arrayRegionMatches(source, 0, targ, 0, source.length)); } public final static boolean arrayEquals(byte[] source, Object target) { if (source == null) return (target == null); if (!(target instanceof byte[])) return false; byte[] targ = (byte[]) target; return (source.length == targ.length && arrayRegionMatches(source, 0, targ, 0, source.length)); } /** * Convenience utility to compare two Object[]s * Ought to be in System */ public final static boolean arrayEquals(Object source, Object target) { if (source == null) return (target == null); // for some reason, the correct arrayEquals is not being called // so do it by hand for now. if (source instanceof Object[]) return(arrayEquals((Object[]) source,target)); if (source instanceof int[]) return(arrayEquals((int[]) source,target)); if (source instanceof double[]) return(arrayEquals((double[]) source, target)); if (source instanceof byte[]) return(arrayEquals((byte[]) source,target)); return source.equals(target); } /** * Convenience utility to compare two Object[]s * Ought to be in System. * @param len the length to compare. * The start indices and start+len must be valid. */ public final static boolean arrayRegionMatches(Object[] source, int sourceStart, Object[] target, int targetStart, int len) { int sourceEnd = sourceStart + len; int delta = targetStart - sourceStart; for (int i = sourceStart; i < sourceEnd; i++) { if (!arrayEquals(source[i],target[i + delta])) return false; } return true; } /** * Convenience utility to compare two Object[]s * Ought to be in System. * @param len the length to compare. * The start indices and start+len must be valid. */ public final static boolean arrayRegionMatches(char[] source, int sourceStart, char[] target, int targetStart, int len) { int sourceEnd = sourceStart + len; int delta = targetStart - sourceStart; for (int i = sourceStart; i < sourceEnd; i++) { if (source[i]!=target[i + delta]) return false; } return true; } /** * Convenience utility to compare two int[]s. * @param len the length to compare. * The start indices and start+len must be valid. * Ought to be in System */ public final static boolean arrayRegionMatches(int[] source, int sourceStart, int[] target, int targetStart, int len) { int sourceEnd = sourceStart + len; int delta = targetStart - sourceStart; for (int i = sourceStart; i < sourceEnd; i++) { if (source[i] != target[i + delta]) return false; } return true; } /** * Convenience utility to compare two arrays of doubles. * @param len the length to compare. * The start indices and start+len must be valid. * Ought to be in System */ public final static boolean arrayRegionMatches(double[] source, int sourceStart, double[] target, int targetStart, int len) { int sourceEnd = sourceStart + len; int delta = targetStart - sourceStart; for (int i = sourceStart; i < sourceEnd; i++) { if (source[i] != target[i + delta]) return false; } return true; } public final static boolean arrayRegionMatches(byte[] source, int sourceStart, byte[] target, int targetStart, int len){ int sourceEnd = sourceStart + len; int delta = targetStart - sourceStart; for (int i = sourceStart; i < sourceEnd; i++) { if (source[i] != target[i + delta]) return false; } return true; } /** * Convenience utility. Does null checks on objects, then calls equals. */ public final static boolean objectEquals(Object a, Object b) { return a == null ? b == null ? true : false : b == null ? false : a.equals(b); } /** * Convenience utility. Does null checks on objects, then calls compare. */ public static > int checkCompare(T a, T b) { return a == null ? b == null ? 0 : -1 : b == null ? 1 : a.compareTo(b); } /** * Convenience utility. Does null checks on object, then calls hashCode. */ public static int checkHash(Object a) { return a == null ? 0 : a.hashCode(); } /** * The ESCAPE character is used during run-length encoding. It signals * a run of identical chars. */ private static final char ESCAPE = '\uA5A5'; /** * The ESCAPE_BYTE character is used during run-length encoding. It signals * a run of identical bytes. */ static final byte ESCAPE_BYTE = (byte)0xA5; /** * Construct a string representing an int array. Use run-length encoding. * A character represents itself, unless it is the ESCAPE character. Then * the following notations are possible: * ESCAPE ESCAPE ESCAPE literal * ESCAPE n c n instances of character c * Since an encoded run occupies 3 characters, we only encode runs of 4 or * more characters. Thus we have n > 0 and n != ESCAPE and n <= 0xFFFF. * If we encounter a run where n == ESCAPE, we represent this as: * c ESCAPE n-1 c * The ESCAPE value is chosen so as not to collide with commonly * seen values. */ static public final String arrayToRLEString(int[] a) { StringBuilder buffer = new StringBuilder(); appendInt(buffer, a.length); int runValue = a[0]; int runLength = 1; for (int i=1; i 0 and n != ESCAPE and n <= 0xFFFF. * If we encounter a run where n == ESCAPE, we represent this as: * c ESCAPE n-1 c * The ESCAPE value is chosen so as not to collide with commonly * seen values. */ static public final String arrayToRLEString(short[] a) { StringBuilder buffer = new StringBuilder(); // for (int i=0; i> 16)); buffer.append((char) a.length); short runValue = a[0]; int runLength = 1; for (int i=1; i 0 and n != ESCAPE and n <= 0xFFFF. * If we encounter a run where n == ESCAPE, we represent this as: * c ESCAPE n-1 c * The ESCAPE value is chosen so as not to collide with commonly * seen values. */ static public final String arrayToRLEString(char[] a) { StringBuilder buffer = new StringBuilder(); buffer.append((char) (a.length >> 16)); buffer.append((char) a.length); char runValue = a[0]; int runLength = 1; for (int i=1; i 0 and n != ESCAPE_BYTE and n <= 0xFF. * If we encounter a run where n == ESCAPE_BYTE, we represent this as: * b ESCAPE_BYTE n-1 b * The ESCAPE_BYTE value is chosen so as not to collide with commonly * seen values. */ static public final String arrayToRLEString(byte[] a) { StringBuilder buffer = new StringBuilder(); buffer.append((char) (a.length >> 16)); buffer.append((char) a.length); byte runValue = a[0]; int runLength = 1; byte[] state = new byte[2]; for (int i=1; i 0 && <= 0xFFFF. */ private static final void encodeRun(T buffer, int value, int length) { if (length < 4) { for (int j=0; j void appendInt(T buffer, int value) { try { buffer.append((char)(value >>> 16)); buffer.append((char)(value & 0xFFFF)); } catch (IOException e) { throw new IllegalIcuArgumentException(e); } } /** * Encode a run, possibly a degenerate run (of < 4 values). * @param length The length of the run; must be > 0 && <= 0xFFFF. */ private static final void encodeRun(T buffer, short value, int length) { try { if (length < 4) { for (int j=0; j 0 && <= 0xFF. */ private static final void encodeRun(T buffer, byte value, int length, byte[] state) { if (length < 4) { for (int j=0; j void appendEncodedByte(T buffer, byte value, byte[] state) { try { if (state[0] != 0) { char c = (char) ((state[1] << 8) | (((int) value) & 0xFF)); buffer.append(c); state[0] = 0; } else { state[0] = 1; state[1] = value; } } catch (IOException e) { throw new IllegalIcuArgumentException(e); } } /** * Construct an array of ints from a run-length encoded string. */ static public final int[] RLEStringToIntArray(String s) { int length = getInt(s, 0); int[] array = new int[length]; int ai = 0, i = 1; int maxI = s.length() / 2; while (ai < length && i < maxI) { int c = getInt(s, i++); if (c == ESCAPE) { c = getInt(s, i++); if (c == ESCAPE) { array[ai++] = c; } else { int runLength = c; int runValue = getInt(s, i++); for (int j=0; j> 8); nextChar = false; } else { b = (byte) (c & 0xFF); nextChar = true; } // This part of the loop is a tiny state machine which handles // the parsing of the run-length encoding. This would be simpler // if we could look ahead, but we can't, so we use 'node' to // move between three nodes in the state machine. switch (node) { case 0: // Normal idle node if (b == ESCAPE_BYTE) { node = 1; } else { array[ai++] = b; } break; case 1: // We have seen one ESCAPE_BYTE; we expect either a second // one, or a run length and value. if (b == ESCAPE_BYTE) { array[ai++] = ESCAPE_BYTE; node = 0; } else { runLength = b; // Interpret signed byte as unsigned if (runLength < 0) runLength += 0x100; node = 2; } break; case 2: // We have seen an ESCAPE_BYTE and length byte. We interpret // the next byte as the value to be repeated. for (int j=0; j 0) buffer.append('+').append(LINE_SEPARATOR); buffer.append(" \""); int count = 11; while (i> 6]); // HEX_DIGIT works for octal buffer.append(HEX_DIGIT[(c & 0070) >> 3]); buffer.append(HEX_DIGIT[(c & 0007)]); count += 4; } } else if (c <= '\u007E') { buffer.append(c); count += 1; } else { buffer.append("\\u"); buffer.append(HEX_DIGIT[(c & 0xF000) >> 12]); buffer.append(HEX_DIGIT[(c & 0x0F00) >> 8]); buffer.append(HEX_DIGIT[(c & 0x00F0) >> 4]); buffer.append(HEX_DIGIT[(c & 0x000F)]); count += 6; } } buffer.append('"'); } return buffer.toString(); } static final char[] HEX_DIGIT = {'0','1','2','3','4','5','6','7', '8','9','A','B','C','D','E','F'}; /** * Format a String for representation in a source file. Like * formatForSource but does not do line breaking. */ static public final String format1ForSource(String s) { StringBuilder buffer = new StringBuilder(); buffer.append("\""); for (int i=0; i> 6]); // HEX_DIGIT works for octal buffer.append(HEX_DIGIT[(c & 0070) >> 3]); buffer.append(HEX_DIGIT[(c & 0007)]); } } else if (c <= '\u007E') { buffer.append(c); } else { buffer.append("\\u"); buffer.append(HEX_DIGIT[(c & 0xF000) >> 12]); buffer.append(HEX_DIGIT[(c & 0x0F00) >> 8]); buffer.append(HEX_DIGIT[(c & 0x00F0) >> 4]); buffer.append(HEX_DIGIT[(c & 0x000F)]); } } buffer.append('"'); return buffer.toString(); } /** * Convert characters outside the range U+0020 to U+007F to * Unicode escapes, and convert backslash to a double backslash. */ public static final String escape(String s) { StringBuilder buf = new StringBuilder(); for (int i=0; i= ' ' && c <= 0x007F) { if (c == '\\') { buf.append("\\\\"); // That is, "\\" } else { buf.append((char)c); } } else { boolean four = c <= 0xFFFF; buf.append(four ? "\\u" : "\\U"); buf.append(hex(c, four ? 4 : 8)); } } return buf.toString(); } /* This map must be in ASCENDING ORDER OF THE ESCAPE CODE */ static private final char[] UNESCAPE_MAP = { /*" 0x22, 0x22 */ /*' 0x27, 0x27 */ /*? 0x3F, 0x3F */ /*\ 0x5C, 0x5C */ /*a*/ 0x61, 0x07, /*b*/ 0x62, 0x08, /*e*/ 0x65, 0x1b, /*f*/ 0x66, 0x0c, /*n*/ 0x6E, 0x0a, /*r*/ 0x72, 0x0d, /*t*/ 0x74, 0x09, /*v*/ 0x76, 0x0b }; /** * Convert an escape to a 32-bit code point value. We attempt * to parallel the icu4c unescapeAt() function. * @param offset16 an array containing offset to the character * after the backslash. Upon return offset16[0] will * be updated to point after the escape sequence. * @return character value from 0 to 10FFFF, or -1 on error. */ public static int unescapeAt(String s, int[] offset16) { int c; int result = 0; int n = 0; int minDig = 0; int maxDig = 0; int bitsPerDigit = 4; int dig; int i; boolean braces = false; /* Check that offset is in range */ int offset = offset16[0]; int length = s.length(); if (offset < 0 || offset >= length) { return -1; } /* Fetch first UChar after '\\' */ c = Character.codePointAt(s, offset); offset += UTF16.getCharCount(c); /* Convert hexadecimal and octal escapes */ switch (c) { case 'u': minDig = maxDig = 4; break; case 'U': minDig = maxDig = 8; break; case 'x': minDig = 1; if (offset < length && UTF16.charAt(s, offset) == 0x7B /*{*/) { ++offset; braces = true; maxDig = 8; } else { maxDig = 2; } break; default: dig = UCharacter.digit(c, 8); if (dig >= 0) { minDig = 1; maxDig = 3; n = 1; /* Already have first octal digit */ bitsPerDigit = 3; result = dig; } break; } if (minDig != 0) { while (offset < length && n < maxDig) { c = UTF16.charAt(s, offset); dig = UCharacter.digit(c, (bitsPerDigit == 3) ? 8 : 16); if (dig < 0) { break; } result = (result << bitsPerDigit) | dig; offset += UTF16.getCharCount(c); ++n; } if (n < minDig) { return -1; } if (braces) { if (c != 0x7D /*}*/) { return -1; } ++offset; } if (result < 0 || result >= 0x110000) { return -1; } // If an escape sequence specifies a lead surrogate, see // if there is a trail surrogate after it, either as an // escape or as a literal. If so, join them up into a // supplementary. if (offset < length && UTF16.isLeadSurrogate((char) result)) { int ahead = offset+1; c = s.charAt(offset); // [sic] get 16-bit code unit if (c == '\\' && ahead < length) { int o[] = new int[] { ahead }; c = unescapeAt(s, o); ahead = o[0]; } if (UTF16.isTrailSurrogate((char) c)) { offset = ahead; result = Character.toCodePoint((char) result, (char) c); } } offset16[0] = offset; return result; } /* Convert C-style escapes in table */ for (i=0; i * "0041". */ public static String hex(long ch) { return hex(ch, 4); } /** * Supplies a zero-padded hex representation of an integer (without 0x) */ static public String hex(long i, int places) { if (i == Long.MIN_VALUE) return "-8000000000000000"; boolean negative = i < 0; if (negative) { i = -i; } String result = Long.toString(i, 16).toUpperCase(Locale.ENGLISH); if (result.length() < places) { result = "0000000000000000".substring(result.length(),places) + result; } if (negative) { return '-' + result; } return result; } /** * Convert a string to comma-separated groups of 4 hex uppercase * digits. E.g., hex('ab') => "0041,0042". */ public static String hex(CharSequence s) { return hex(s, 4, ",", true, new StringBuilder()).toString(); } /** * Convert a string to separated groups of hex uppercase * digits. E.g., hex('ab'...) => "0041,0042". Append the output * to the given Appendable. */ public static T hex(S s, int width, U separator, boolean useCodePoints, T result) { try { if (useCodePoints) { int cp; for (int i = 0; i < s.length(); i += UTF16.getCharCount(cp)) { cp = Character.codePointAt(s, i); if (i != 0) { result.append(separator); } result.append(hex(cp,width)); } } else { for (int i = 0; i < s.length(); ++i) { if (i != 0) { result.append(separator); } result.append(hex(s.charAt(i),width)); } } return result; } catch (IOException e) { throw new IllegalIcuArgumentException(e); } } public static String hex(byte[] o, int start, int end, String separator) { StringBuilder result = new StringBuilder(); //int ch; for (int i = start; i < end; ++i) { if (i != 0) result.append(separator); result.append(hex(o[i])); } return result.toString(); } /** * Convert a string to comma-separated groups of 4 hex uppercase * digits. E.g., hex('ab') => "0041,0042". */ public static String hex(S s, int width, S separator) { return hex(s, width, separator, true, new StringBuilder()).toString(); } /** * Split a string into pieces based on the given divider character * @param s the string to split * @param divider the character on which to split. Occurrences of * this character are not included in the output * @param output an array to receive the substrings between * instances of divider. It must be large enough on entry to * accomodate all output. Adjacent instances of the divider * character will place empty strings into output. Before * returning, output is padded out with empty strings. */ public static void split(String s, char divider, String[] output) { int last = 0; int current = 0; int i; for (i = 0; i < s.length(); ++i) { if (s.charAt(i) == divider) { output[current++] = s.substring(last,i); last = i+1; } } output[current++] = s.substring(last,i); while (current < output.length) { output[current++] = ""; } } /** * Split a string into pieces based on the given divider character * @param s the string to split * @param divider the character on which to split. Occurrences of * this character are not included in the output * @return output an array to receive the substrings between * instances of divider. Adjacent instances of the divider * character will place empty strings into output. */ public static String[] split(String s, char divider) { int last = 0; int i; ArrayList output = new ArrayList(); for (i = 0; i < s.length(); ++i) { if (s.charAt(i) == divider) { output.add(s.substring(last,i)); last = i+1; } } output.add( s.substring(last,i)); return output.toArray(new String[output.size()]); } /** * Look up a given string in a string array. Returns the index at * which the first occurrence of the string was found in the * array, or -1 if it was not found. * @param source the string to search for * @param target the array of zero or more strings in which to * look for source * @return the index of target at which source first occurs, or -1 * if not found */ public static int lookup(String source, String[] target) { for (int i = 0; i < target.length; ++i) { if (source.equals(target[i])) return i; } return -1; } /** * Parse a single non-whitespace character 'ch', optionally * preceded by whitespace. * @param id the string to be parsed * @param pos INPUT-OUTPUT parameter. On input, pos[0] is the * offset of the first character to be parsed. On output, pos[0] * is the index after the last parsed character. If the parse * fails, pos[0] will be unchanged. * @param ch the non-whitespace character to be parsed. * @return true if 'ch' is seen preceded by zero or more * whitespace characters. */ public static boolean parseChar(String id, int[] pos, char ch) { int start = pos[0]; pos[0] = PatternProps.skipWhiteSpace(id, pos[0]); if (pos[0] == id.length() || id.charAt(pos[0]) != ch) { pos[0] = start; return false; } ++pos[0]; return true; } /** * Parse a pattern string starting at offset pos. Keywords are * matched case-insensitively. Spaces may be skipped and may be * optional or required. Integer values may be parsed, and if * they are, they will be returned in the given array. If * successful, the offset of the next non-space character is * returned. On failure, -1 is returned. * @param pattern must only contain lowercase characters, which * will match their uppercase equivalents as well. A space * character matches one or more required spaces. A '~' character * matches zero or more optional spaces. A '#' character matches * an integer and stores it in parsedInts, which the caller must * ensure has enough capacity. * @param parsedInts array to receive parsed integers. Caller * must ensure that parsedInts.length is >= the number of '#' * signs in 'pattern'. * @return the position after the last character parsed, or -1 if * the parse failed */ @SuppressWarnings("fallthrough") public static int parsePattern(String rule, int pos, int limit, String pattern, int[] parsedInts) { // TODO Update this to handle surrogates int[] p = new int[1]; int intCount = 0; // number of integers parsed for (int i=0; i= limit) { return -1; } c = rule.charAt(pos++); if (!PatternProps.isWhiteSpace(c)) { return -1; } // FALL THROUGH to skipWhitespace case '~': pos = PatternProps.skipWhiteSpace(rule, pos); break; case '#': p[0] = pos; parsedInts[intCount++] = parseInteger(rule, p, limit); if (p[0] == pos) { // Syntax error; failed to parse integer return -1; } pos = p[0]; break; default: if (pos >= limit) { return -1; } c = (char) UCharacter.toLowerCase(rule.charAt(pos++)); if (c != cpat) { return -1; } break; } } return pos; } /** * Parse a pattern string within the given Replaceable and a parsing * pattern. Characters are matched literally and case-sensitively * except for the following special characters: * * ~ zero or more Pattern_White_Space chars * * If end of pattern is reached with all matches along the way, * pos is advanced to the first unparsed index and returned. * Otherwise -1 is returned. * @param pat pattern that controls parsing * @param text text to be parsed, starting at index * @param index offset to first character to parse * @param limit offset after last character to parse * @return index after last parsed character, or -1 on parse failure. */ public static int parsePattern(String pat, Replaceable text, int index, int limit) { int ipat = 0; // empty pattern matches immediately if (ipat == pat.length()) { return index; } int cpat = Character.codePointAt(pat, ipat); while (index < limit) { int c = text.char32At(index); // parse \s* if (cpat == '~') { if (PatternProps.isWhiteSpace(c)) { index += UTF16.getCharCount(c); continue; } else { if (++ipat == pat.length()) { return index; // success; c unparsed } // fall thru; process c again with next cpat } } // parse literal else if (c == cpat) { int n = UTF16.getCharCount(c); index += n; ipat += n; if (ipat == pat.length()) { return index; // success; c parsed } // fall thru; get next cpat } // match failure of literal else { return -1; } cpat = UTF16.charAt(pat, ipat); } return -1; // text ended before end of pat } /** * Parse an integer at pos, either of the form \d+ or of the form * 0x[0-9A-Fa-f]+ or 0[0-7]+, that is, in standard decimal, hex, * or octal format. * @param pos INPUT-OUTPUT parameter. On input, the first * character to parse. On output, the character after the last * parsed character. */ public static int parseInteger(String rule, int[] pos, int limit) { int count = 0; int value = 0; int p = pos[0]; int radix = 10; if (rule.regionMatches(true, p, "0x", 0, 2)) { p += 2; radix = 16; } else if (p < limit && rule.charAt(p) == '0') { p++; count = 1; radix = 8; } while (p < limit) { int d = UCharacter.digit(rule.charAt(p++), radix); if (d < 0) { --p; break; } ++count; int v = (value * radix) + d; if (v <= value) { // If there are too many input digits, at some point // the value will go negative, e.g., if we have seen // "0x8000000" already and there is another '0', when // we parse the next 0 the value will go negative. return 0; } value = v; } if (count > 0) { pos[0] = p; } return value; } /** * Parse a Unicode identifier from the given string at the given * position. Return the identifier, or null if there is no * identifier. * @param str the string to parse * @param pos INPUT-OUPUT parameter. On INPUT, pos[0] is the * first character to examine. It must be less than str.length(), * and it must not point to a whitespace character. That is, must * have pos[0] < str.length(). On * OUTPUT, the position after the last parsed character. * @return the Unicode identifier, or null if there is no valid * identifier at pos[0]. */ public static String parseUnicodeIdentifier(String str, int[] pos) { // assert(pos[0] < str.length()); StringBuilder buf = new StringBuilder(); int p = pos[0]; while (p < str.length()) { int ch = Character.codePointAt(str, p); if (buf.length() == 0) { if (UCharacter.isUnicodeIdentifierStart(ch)) { buf.appendCodePoint(ch); } else { return null; } } else { if (UCharacter.isUnicodeIdentifierPart(ch)) { buf.appendCodePoint(ch); } else { break; } } p += UTF16.getCharCount(ch); } pos[0] = p; return buf.toString(); } static final char DIGITS[] = { '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P', 'Q', 'R', 'S', 'T', 'U', 'V', 'W', 'X', 'Y', 'Z' }; /** * Append the digits of a positive integer to the given * Appendable in the given radix. This is * done recursively since it is easiest to generate the low- * order digit first, but it must be appended last. * * @param result is the Appendable to append to * @param n is the positive integer * @param radix is the radix, from 2 to 36 inclusive * @param minDigits is the minimum number of digits to append. */ private static void recursiveAppendNumber(T result, int n, int radix, int minDigits) { try { int digit = n % radix; if (n >= radix || minDigits > 1) { recursiveAppendNumber(result, n / radix, radix, minDigits - 1); } result.append(DIGITS[digit]); } catch (IOException e) { throw new IllegalIcuArgumentException(e); } } /** * Append a number to the given Appendable in the given radix. * Standard digits '0'-'9' are used and letters 'A'-'Z' for * radices 11 through 36. * @param result the digits of the number are appended here * @param n the number to be converted to digits; may be negative. * If negative, a '-' is prepended to the digits. * @param radix a radix from 2 to 36 inclusive. * @param minDigits the minimum number of digits, not including * any '-', to produce. Values less than 2 have no effect. One * digit is always emitted regardless of this parameter. * @return a reference to result */ public static T appendNumber(T result, int n, int radix, int minDigits) { try { if (radix < 2 || radix > 36) { throw new IllegalArgumentException("Illegal radix " + radix); } int abs = n; if (n < 0) { abs = -n; result.append("-"); } recursiveAppendNumber(result, abs, radix, minDigits); return result; } catch (IOException e) { throw new IllegalIcuArgumentException(e); } } /** * Parse an unsigned 31-bit integer at the given offset. Use * UCharacter.digit() to parse individual characters into digits. * @param text the text to be parsed * @param pos INPUT-OUTPUT parameter. On entry, pos[0] is the * offset within text at which to start parsing; it should point * to a valid digit. On exit, pos[0] is the offset after the last * parsed character. If the parse failed, it will be unchanged on * exit. Must be >= 0 on entry. * @param radix the radix in which to parse; must be >= 2 and <= * 36. * @return a non-negative parsed number, or -1 upon parse failure. * Parse fails if there are no digits, that is, if pos[0] does not * point to a valid digit on entry, or if the number to be parsed * does not fit into a 31-bit unsigned integer. */ public static int parseNumber(String text, int[] pos, int radix) { // assert(pos[0] >= 0); // assert(radix >= 2); // assert(radix <= 36); int n = 0; int p = pos[0]; while (p < text.length()) { int ch = Character.codePointAt(text, p); int d = UCharacter.digit(ch, radix); if (d < 0) { break; } n = radix*n + d; // ASSUME that when a 32-bit integer overflows it becomes // negative. E.g., 214748364 * 10 + 8 => negative value. if (n < 0) { return -1; } ++p; } if (p == pos[0]) { return -1; } pos[0] = p; return n; } /** * Return true if the character is NOT printable ASCII. The tab, * newline and linefeed characters are considered unprintable. */ public static boolean isUnprintable(int c) { //0x20 = 32 and 0x7E = 126 return !(c >= 0x20 && c <= 0x7E); } /** * Escape unprintable characters using uxxxx notation * for U+0000 to U+FFFF and Uxxxxxxxx for U+10000 and * above. If the character is printable ASCII, then do nothing * and return FALSE. Otherwise, append the escaped notation and * return TRUE. */ public static boolean escapeUnprintable(T result, int c) { try { if (isUnprintable(c)) { result.append('\\'); if ((c & ~0xFFFF) != 0) { result.append('U'); result.append(DIGITS[0xF&(c>>28)]); result.append(DIGITS[0xF&(c>>24)]); result.append(DIGITS[0xF&(c>>20)]); result.append(DIGITS[0xF&(c>>16)]); } else { result.append('u'); } result.append(DIGITS[0xF&(c>>12)]); result.append(DIGITS[0xF&(c>>8)]); result.append(DIGITS[0xF&(c>>4)]); result.append(DIGITS[0xF&c]); return true; } return false; } catch (IOException e) { throw new IllegalIcuArgumentException(e); } } /** * Returns the index of the first character in a set, ignoring quoted text. * For example, in the string "abc'hide'h", the 'h' in "hide" will not be * found by a search for "h". Unlike String.indexOf(), this method searches * not for a single character, but for any character of the string * setOfChars. * @param text text to be searched * @param start the beginning index, inclusive; 0 <= start * <= limit. * @param limit the ending index, exclusive; start <= limit * <= text.length(). * @param setOfChars string with one or more distinct characters * @return Offset of the first character in setOfChars * found, or -1 if not found. * @see String#indexOf */ public static int quotedIndexOf(String text, int start, int limit, String setOfChars) { for (int i=start; i= 0) { return i; } } return -1; } /** * Append a character to a rule that is being built up. To flush * the quoteBuf to rule, make one final call with isLiteral == true. * If there is no final character, pass in (int)-1 as c. * @param rule the string to append the character to * @param c the character to append, or (int)-1 if none. * @param isLiteral if true, then the given character should not be * quoted or escaped. Usually this means it is a syntactic element * such as > or $ * @param escapeUnprintable if true, then unprintable characters * should be escaped using escapeUnprintable(). These escapes will * appear outside of quotes. * @param quoteBuf a buffer which is used to build up quoted * substrings. The caller should initially supply an empty buffer, * and thereafter should not modify the buffer. The buffer should be * cleared out by, at the end, calling this method with a literal * character (which may be -1). */ public static void appendToRule(StringBuffer rule, int c, boolean isLiteral, boolean escapeUnprintable, StringBuffer quoteBuf) { // If we are escaping unprintables, then escape them outside // quotes. \\u and \\U are not recognized within quotes. The same // logic applies to literals, but literals are never escaped. if (isLiteral || (escapeUnprintable && Utility.isUnprintable(c))) { if (quoteBuf.length() > 0) { // We prefer backslash APOSTROPHE to double APOSTROPHE // (more readable, less similar to ") so if there are // double APOSTROPHEs at the ends, we pull them outside // of the quote. // If the first thing in the quoteBuf is APOSTROPHE // (doubled) then pull it out. while (quoteBuf.length() >= 2 && quoteBuf.charAt(0) == APOSTROPHE && quoteBuf.charAt(1) == APOSTROPHE) { rule.append(BACKSLASH).append(APOSTROPHE); quoteBuf.delete(0, 2); } // If the last thing in the quoteBuf is APOSTROPHE // (doubled) then remove and count it and add it after. int trailingCount = 0; while (quoteBuf.length() >= 2 && quoteBuf.charAt(quoteBuf.length()-2) == APOSTROPHE && quoteBuf.charAt(quoteBuf.length()-1) == APOSTROPHE) { quoteBuf.setLength(quoteBuf.length()-2); ++trailingCount; } if (quoteBuf.length() > 0) { rule.append(APOSTROPHE); rule.append(quoteBuf); rule.append(APOSTROPHE); quoteBuf.setLength(0); } while (trailingCount-- > 0) { rule.append(BACKSLASH).append(APOSTROPHE); } } if (c != -1) { /* Since spaces are ignored during parsing, they are * emitted only for readability. We emit one here * only if there isn't already one at the end of the * rule. */ if (c == ' ') { int len = rule.length(); if (len > 0 && rule.charAt(len-1) != ' ') { rule.append(' '); } } else if (!escapeUnprintable || !Utility.escapeUnprintable(rule, c)) { rule.appendCodePoint(c); } } } // Escape ' and '\' and don't begin a quote just for them else if (quoteBuf.length() == 0 && (c == APOSTROPHE || c == BACKSLASH)) { rule.append(BACKSLASH).append((char)c); } // Specials (printable ascii that isn't [0-9a-zA-Z]) and // whitespace need quoting. Also append stuff to quotes if we are // building up a quoted substring already. else if (quoteBuf.length() > 0 || (c >= 0x0021 && c <= 0x007E && !((c >= 0x0030/*'0'*/ && c <= 0x0039/*'9'*/) || (c >= 0x0041/*'A'*/ && c <= 0x005A/*'Z'*/) || (c >= 0x0061/*'a'*/ && c <= 0x007A/*'z'*/))) || PatternProps.isWhiteSpace(c)) { quoteBuf.appendCodePoint(c); // Double ' within a quote if (c == APOSTROPHE) { quoteBuf.append((char)c); } } // Otherwise just append else { rule.appendCodePoint(c); } } /** * Append the given string to the rule. Calls the single-character * version of appendToRule for each character. */ public static void appendToRule(StringBuffer rule, String text, boolean isLiteral, boolean escapeUnprintable, StringBuffer quoteBuf) { for (int i=0; i target) { return 1; } return 0; } /** * Find the highest bit in a positive integer. This is done * by doing a binary search through the bits. * * @param n is the integer * * @return the bit number of the highest bit, with 0 being * the low order bit, or -1 if n is not positive */ public static final byte highBit(int n) { if (n <= 0) { return -1; } byte bit = 0; if (n >= 1 << 16) { n >>= 16; bit += 16; } if (n >= 1 << 8) { n >>= 8; bit += 8; } if (n >= 1 << 4) { n >>= 4; bit += 4; } if (n >= 1 << 2) { n >>= 2; bit += 2; } if (n >= 1 << 1) { n >>= 1; bit += 1; } return bit; } /** * Utility method to take a int[] containing codepoints and return * a string representation with code units. */ public static String valueOf(int[]source){ // TODO: Investigate why this method is not on UTF16 class StringBuilder result = new StringBuilder(source.length); for(int i=0; i