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International Component for Unicode for Java (ICU4J) is a mature, widely used Java library providing Unicode and Globalization support

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// © 2017 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html#License
package com.ibm.icu.impl.number;

import java.math.BigDecimal;

import com.ibm.icu.impl.StandardPlural;
import com.ibm.icu.impl.number.Padder.PadPosition;
import com.ibm.icu.number.NumberFormatter.SignDisplay;
import com.ibm.icu.text.DecimalFormatSymbols;

/**
 * Assorted utilities relating to decimal formatting pattern strings.
 */
public class PatternStringUtils {

    /**
     * Determine whether a given roundingIncrement should be ignored for formatting
     * based on the current maxFrac value (maximum fraction digits). For example a
     * roundingIncrement of 0.01 should be ignored if maxFrac is 1, but not if maxFrac
     * is 2 or more. Note that roundingIncrements are rounded up in significance, so
     * a roundingIncrement of 0.006 is treated like 0.01 for this determination, i.e.
     * it should not be ignored if maxFrac is 2 or more (but a roundingIncrement of
     * 0.005 is treated like 0.001 for significance).
     *
     * This test is needed for both NumberPropertyMapper.oldToNew and 
     * PatternStringUtils.propertiesToPatternString, but NumberPropertyMapper
     * is package-private so we have it here.
     *
     * @param roundIncrDec
     *            The roundingIncrement to be checked. Must be non-null.
     * @param maxFrac
     *            The current maximum fraction digits value.
     * @return true if roundIncr should be ignored for formatting.
     */
    public static boolean ignoreRoundingIncrement(BigDecimal roundIncrDec, int maxFrac) {
        double roundIncr = roundIncrDec.doubleValue();
        if (roundIncr == 0.0) {
            return true;
        }
        if (maxFrac < 0) {
            return false;
        }
        int frac = 0;
        roundIncr *= 2.0; // This handles the rounding up of values above e.g. 0.005 or 0.0005
        for (frac = 0; frac <= maxFrac && roundIncr <= 1.0; frac++, roundIncr *= 10.0);
        return (frac > maxFrac);
    }

    /**
     * Creates a pattern string from a property bag.
     *
     * 

* Since pattern strings support only a subset of the functionality available in a property bag, a * new property bag created from the string returned by this function may not be the same as the * original property bag. * * @param properties * The property bag to serialize. * @return A pattern string approximately serializing the property bag. */ public static String propertiesToPatternString(DecimalFormatProperties properties) { StringBuilder sb = new StringBuilder(); // Convenience references // The Math.min() calls prevent DoS int dosMax = 100; int grouping1 = Math.max(0, Math.min(properties.getGroupingSize(), dosMax)); int grouping2 = Math.max(0, Math.min(properties.getSecondaryGroupingSize(), dosMax)); boolean useGrouping = properties.getGroupingUsed(); int paddingWidth = Math.min(properties.getFormatWidth(), dosMax); PadPosition paddingLocation = properties.getPadPosition(); String paddingString = properties.getPadString(); int minInt = Math.max(0, Math.min(properties.getMinimumIntegerDigits(), dosMax)); int maxInt = Math.min(properties.getMaximumIntegerDigits(), dosMax); int minFrac = Math.max(0, Math.min(properties.getMinimumFractionDigits(), dosMax)); int maxFrac = Math.min(properties.getMaximumFractionDigits(), dosMax); int minSig = Math.min(properties.getMinimumSignificantDigits(), dosMax); int maxSig = Math.min(properties.getMaximumSignificantDigits(), dosMax); boolean alwaysShowDecimal = properties.getDecimalSeparatorAlwaysShown(); int exponentDigits = Math.min(properties.getMinimumExponentDigits(), dosMax); boolean exponentShowPlusSign = properties.getExponentSignAlwaysShown(); PropertiesAffixPatternProvider affixes = new PropertiesAffixPatternProvider(properties); // Prefixes sb.append(affixes.getString(AffixPatternProvider.FLAG_POS_PREFIX)); int afterPrefixPos = sb.length(); // Figure out the grouping sizes. if (!useGrouping) { grouping1 = 0; grouping2 = 0; } else if (grouping1 == grouping2) { grouping1 = 0; } int groupingLength = grouping1 + grouping2 + 1; // Figure out the digits we need to put in the pattern. BigDecimal roundingInterval = properties.getRoundingIncrement(); StringBuilder digitsString = new StringBuilder(); int digitsStringScale = 0; if (maxSig != Math.min(dosMax, -1)) { // Significant Digits. while (digitsString.length() < minSig) { digitsString.append('@'); } while (digitsString.length() < maxSig) { digitsString.append('#'); } } else if (roundingInterval != null && !ignoreRoundingIncrement(roundingInterval,maxFrac)) { // Rounding Interval. digitsStringScale = -roundingInterval.scale(); // TODO: Check for DoS here? String str = roundingInterval.scaleByPowerOfTen(roundingInterval.scale()).toPlainString(); if (str.charAt(0) == '-') { // TODO: Unsupported operation exception or fail silently? digitsString.append(str, 1, str.length()); } else { digitsString.append(str); } } while (digitsString.length() + digitsStringScale < minInt) { digitsString.insert(0, '0'); } while (-digitsStringScale < minFrac) { digitsString.append('0'); digitsStringScale--; } // Write the digits to the string builder int m0 = Math.max(groupingLength, digitsString.length() + digitsStringScale); m0 = (maxInt != dosMax) ? Math.max(maxInt, m0) - 1 : m0 - 1; int mN = (maxFrac != dosMax) ? Math.min(-maxFrac, digitsStringScale) : digitsStringScale; for (int magnitude = m0; magnitude >= mN; magnitude--) { int di = digitsString.length() + digitsStringScale - magnitude - 1; if (di < 0 || di >= digitsString.length()) { sb.append('#'); } else { sb.append(digitsString.charAt(di)); } // Decimal separator if (magnitude == 0 && (alwaysShowDecimal || mN < 0)) { sb.append('.'); } if (!useGrouping) { continue; } // Least-significant grouping separator if (magnitude > 0 && magnitude == grouping1) { sb.append(','); } // All other grouping separators if (magnitude > grouping1 && grouping2 > 0 && (magnitude - grouping1) % grouping2 == 0) { sb.append(','); } } // Exponential notation if (exponentDigits != Math.min(dosMax, -1)) { sb.append('E'); if (exponentShowPlusSign) { sb.append('+'); } for (int i = 0; i < exponentDigits; i++) { sb.append('0'); } } // Suffixes int beforeSuffixPos = sb.length(); sb.append(affixes.getString(AffixPatternProvider.FLAG_POS_SUFFIX)); // Resolve Padding if (paddingWidth > 0) { while (paddingWidth - sb.length() > 0) { sb.insert(afterPrefixPos, '#'); beforeSuffixPos++; } int addedLength; switch (paddingLocation) { case BEFORE_PREFIX: addedLength = PatternStringUtils.escapePaddingString(paddingString, sb, 0); sb.insert(0, '*'); afterPrefixPos += addedLength + 1; beforeSuffixPos += addedLength + 1; break; case AFTER_PREFIX: addedLength = PatternStringUtils.escapePaddingString(paddingString, sb, afterPrefixPos); sb.insert(afterPrefixPos, '*'); afterPrefixPos += addedLength + 1; beforeSuffixPos += addedLength + 1; break; case BEFORE_SUFFIX: PatternStringUtils.escapePaddingString(paddingString, sb, beforeSuffixPos); sb.insert(beforeSuffixPos, '*'); break; case AFTER_SUFFIX: sb.append('*'); PatternStringUtils.escapePaddingString(paddingString, sb, sb.length()); break; } } // Negative affixes // Ignore if the negative prefix pattern is "-" and the negative suffix is empty if (affixes.hasNegativeSubpattern()) { sb.append(';'); sb.append(affixes.getString(AffixPatternProvider.FLAG_NEG_PREFIX)); // Copy the positive digit format into the negative. // This is optional; the pattern is the same as if '#' were appended here instead. sb.append(sb, afterPrefixPos, beforeSuffixPos); sb.append(affixes.getString(AffixPatternProvider.FLAG_NEG_SUFFIX)); } return sb.toString(); } /** @return The number of chars inserted. */ private static int escapePaddingString(CharSequence input, StringBuilder output, int startIndex) { if (input == null || input.length() == 0) input = Padder.FALLBACK_PADDING_STRING; int startLength = output.length(); if (input.length() == 1) { if (input.equals("'")) { output.insert(startIndex, "''"); } else { output.insert(startIndex, input); } } else { output.insert(startIndex, '\''); int offset = 1; for (int i = 0; i < input.length(); i++) { // it's okay to deal in chars here because the quote mark is the only interesting thing. char ch = input.charAt(i); if (ch == '\'') { output.insert(startIndex + offset, "''"); offset += 2; } else { output.insert(startIndex + offset, ch); offset += 1; } } output.insert(startIndex + offset, '\''); } return output.length() - startLength; } /** * Converts a pattern between standard notation and localized notation. Localized notation means that * instead of using generic placeholders in the pattern, you use the corresponding locale-specific * characters instead. For example, in locale fr-FR, the period in the pattern "0.000" means * "decimal" in standard notation (as it does in every other locale), but it means "grouping" in * localized notation. * *

* A greedy string-substitution strategy is used to substitute locale symbols. If two symbols are * ambiguous or have the same prefix, the result is not well-defined. * *

* Locale symbols are not allowed to contain the ASCII quote character. * *

* This method is provided for backwards compatibility and should not be used in any new code. * * @param input * The pattern to convert. * @param symbols * The symbols corresponding to the localized pattern. * @param toLocalized * true to convert from standard to localized notation; false to convert from localized to * standard notation. * @return The pattern expressed in the other notation. */ public static String convertLocalized( String input, DecimalFormatSymbols symbols, boolean toLocalized) { if (input == null) return null; // Construct a table of strings to be converted between localized and standard. String[][] table = new String[21][2]; int standIdx = toLocalized ? 0 : 1; int localIdx = toLocalized ? 1 : 0; table[0][standIdx] = "%"; table[0][localIdx] = symbols.getPercentString(); table[1][standIdx] = "‰"; table[1][localIdx] = symbols.getPerMillString(); table[2][standIdx] = "."; table[2][localIdx] = symbols.getDecimalSeparatorString(); table[3][standIdx] = ","; table[3][localIdx] = symbols.getGroupingSeparatorString(); table[4][standIdx] = "-"; table[4][localIdx] = symbols.getMinusSignString(); table[5][standIdx] = "+"; table[5][localIdx] = symbols.getPlusSignString(); table[6][standIdx] = ";"; table[6][localIdx] = Character.toString(symbols.getPatternSeparator()); table[7][standIdx] = "@"; table[7][localIdx] = Character.toString(symbols.getSignificantDigit()); table[8][standIdx] = "E"; table[8][localIdx] = symbols.getExponentSeparator(); table[9][standIdx] = "*"; table[9][localIdx] = Character.toString(symbols.getPadEscape()); table[10][standIdx] = "#"; table[10][localIdx] = Character.toString(symbols.getDigit()); for (int i = 0; i < 10; i++) { table[11 + i][standIdx] = Character.toString((char) ('0' + i)); table[11 + i][localIdx] = symbols.getDigitStringsLocal()[i]; } // Special case: quotes are NOT allowed to be in any localIdx strings. // Substitute them with '’' instead. for (int i = 0; i < table.length; i++) { table[i][localIdx] = table[i][localIdx].replace('\'', '’'); } // Iterate through the string and convert. // State table: // 0 => base state // 1 => first char inside a quoted sequence in input and output string // 2 => inside a quoted sequence in input and output string // 3 => first char after a close quote in input string; // close quote still needs to be written to output string // 4 => base state in input string; inside quoted sequence in output string // 5 => first char inside a quoted sequence in input string; // inside quoted sequence in output string StringBuilder result = new StringBuilder(); int state = 0; outer: for (int offset = 0; offset < input.length(); offset++) { char ch = input.charAt(offset); // Handle a quote character (state shift) if (ch == '\'') { if (state == 0) { result.append('\''); state = 1; continue; } else if (state == 1) { result.append('\''); state = 0; continue; } else if (state == 2) { state = 3; continue; } else if (state == 3) { result.append('\''); result.append('\''); state = 1; continue; } else if (state == 4) { state = 5; continue; } else { assert state == 5; result.append('\''); result.append('\''); state = 4; continue; } } if (state == 0 || state == 3 || state == 4) { for (String[] pair : table) { // Perform a greedy match on this symbol string if (input.regionMatches(offset, pair[0], 0, pair[0].length())) { // Skip ahead past this region for the next iteration offset += pair[0].length() - 1; if (state == 3 || state == 4) { result.append('\''); state = 0; } result.append(pair[1]); continue outer; } } // No replacement found. Check if a special quote is necessary for (String[] pair : table) { if (input.regionMatches(offset, pair[1], 0, pair[1].length())) { if (state == 0) { result.append('\''); state = 4; } result.append(ch); continue outer; } } // Still nothing. Copy the char verbatim. (Add a close quote if necessary) if (state == 3 || state == 4) { result.append('\''); state = 0; } result.append(ch); } else { assert state == 1 || state == 2 || state == 5; result.append(ch); state = 2; } } // Resolve final quotes if (state == 3 || state == 4) { result.append('\''); state = 0; } if (state != 0) { throw new IllegalArgumentException("Malformed localized pattern: unterminated quote"); } return result.toString(); } /** * This method contains the heart of the logic for rendering LDML affix strings. It handles * sign-always-shown resolution, whether to use the positive or negative subpattern, permille * substitution, and plural forms for CurrencyPluralInfo. */ public static void patternInfoToStringBuilder( AffixPatternProvider patternInfo, boolean isPrefix, int signum, SignDisplay signDisplay, StandardPlural plural, boolean perMilleReplacesPercent, StringBuilder output) { // Should the output render '+' where '-' would normally appear in the pattern? boolean plusReplacesMinusSign = signum != -1 && (signDisplay == SignDisplay.ALWAYS || signDisplay == SignDisplay.ACCOUNTING_ALWAYS || (signum == 1 && (signDisplay == SignDisplay.EXCEPT_ZERO || signDisplay == SignDisplay.ACCOUNTING_EXCEPT_ZERO))) && patternInfo.positiveHasPlusSign() == false; // Should we use the affix from the negative subpattern? (If not, we will use the positive // subpattern.) boolean useNegativeAffixPattern = patternInfo.hasNegativeSubpattern() && (signum == -1 || (patternInfo.negativeHasMinusSign() && plusReplacesMinusSign)); // Resolve the flags for the affix pattern. int flags = 0; if (useNegativeAffixPattern) { flags |= AffixPatternProvider.Flags.NEGATIVE_SUBPATTERN; } if (isPrefix) { flags |= AffixPatternProvider.Flags.PREFIX; } if (plural != null) { assert plural.ordinal() == (AffixPatternProvider.Flags.PLURAL_MASK & plural.ordinal()); flags |= plural.ordinal(); } // Should we prepend a sign to the pattern? boolean prependSign; if (!isPrefix || useNegativeAffixPattern) { prependSign = false; } else if (signum == -1) { prependSign = signDisplay != SignDisplay.NEVER; } else { prependSign = plusReplacesMinusSign; } // Compute the length of the affix pattern. int length = patternInfo.length(flags) + (prependSign ? 1 : 0); // Finally, set the result into the StringBuilder. output.setLength(0); for (int index = 0; index < length; index++) { char candidate; if (prependSign && index == 0) { candidate = '-'; } else if (prependSign) { candidate = patternInfo.charAt(flags, index - 1); } else { candidate = patternInfo.charAt(flags, index); } if (plusReplacesMinusSign && candidate == '-') { candidate = '+'; } if (perMilleReplacesPercent && candidate == '%') { candidate = '‰'; } output.append(candidate); } } }





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