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/*
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 */

package java.text;

import java.io.InvalidObjectException;
import java.io.IOException;
import java.io.ObjectInputStream;
import java.math.BigDecimal;
import java.math.BigInteger;
import java.math.RoundingMode;
import java.util.ArrayList;
import java.util.Currency;
import java.util.Hashtable;
import java.util.Locale;
import java.util.ResourceBundle;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicLong;
import sun.util.resources.LocaleData;

DecimalFormat is a concrete subclass of NumberFormat that formats decimal numbers. It has a variety of features designed to make it possible to parse and format numbers in any locale, including support for Western, Arabic, and Indic digits. It also supports different kinds of numbers, including integers (123), fixed-point numbers (123.4), scientific notation (1.23E4), percentages (12%), and currency amounts ($123). All of these can be localized.

To obtain a NumberFormat for a specific locale, including the default locale, call one of NumberFormat's factory methods, such as getInstance(). In general, do not call the DecimalFormat constructors directly, since the NumberFormat factory methods may return subclasses other than DecimalFormat. If you need to customize the format object, do something like this:

NumberFormat f = NumberFormat.getInstance(loc);
if (f instanceof DecimalFormat) {
    ((DecimalFormat) f).setDecimalSeparatorAlwaysShown(true);
}

A DecimalFormat comprises a pattern and a set of symbols. The pattern may be set directly using applyPattern(), or indirectly using the API methods. The symbols are stored in a DecimalFormatSymbols object. When using the NumberFormat factory methods, the pattern and symbols are read from localized ResourceBundles.

Patterns

DecimalFormat patterns have the following syntax:
Pattern:
        PositivePattern
        PositivePattern ; NegativePattern
PositivePattern:
        Prefixopt Number Suffixopt
NegativePattern:
        Prefixopt Number Suffixopt
Prefix:
        any Unicode characters except \uFFFE, \uFFFF, and special characters
Suffix:
        any Unicode characters except \uFFFE, \uFFFF, and special characters
Number:
        Integer Exponentopt
        Integer . Fraction Exponentopt
Integer:
        MinimumInteger
        #
        # Integer
        # , Integer
MinimumInteger:
        0
        0 MinimumInteger
        0 , MinimumInteger
Fraction:
        MinimumFractionopt OptionalFractionopt
MinimumFraction:
        0 MinimumFractionopt
OptionalFraction:
        # OptionalFractionopt
Exponent:
        E MinimumExponent
MinimumExponent:
        0 MinimumExponentopt

A DecimalFormat pattern contains a positive and negative subpattern, for example, "#,##0.00;(#,##0.00)". Each subpattern has a prefix, numeric part, and suffix. The negative subpattern is optional; if absent, then the positive subpattern prefixed with the localized minus sign ('-' in most locales) is used as the negative subpattern. That is, "0.00" alone is equivalent to "0.00;-0.00". If there is an explicit negative subpattern, it serves only to specify the negative prefix and suffix; the number of digits, minimal digits, and other characteristics are all the same as the positive pattern. That means that "#,##0.0#;(#)" produces precisely the same behavior as "#,##0.0#;(#,##0.0#)".

The prefixes, suffixes, and various symbols used for infinity, digits, thousands separators, decimal separators, etc. may be set to arbitrary values, and they will appear properly during formatting. However, care must be taken that the symbols and strings do not conflict, or parsing will be unreliable. For example, either the positive and negative prefixes or the suffixes must be distinct for DecimalFormat.parse() to be able to distinguish positive from negative values. (If they are identical, then DecimalFormat will behave as if no negative subpattern was specified.) Another example is that the decimal separator and thousands separator should be distinct characters, or parsing will be impossible.

The grouping separator is commonly used for thousands, but in some countries it separates ten-thousands. The grouping size is a constant number of digits between the grouping characters, such as 3 for 100,000,000 or 4 for 1,0000,0000. If you supply a pattern with multiple grouping characters, the interval between the last one and the end of the integer is the one that is used. So "#,##,###,####" == "######,####" == "##,####,####".

Special Pattern Characters

Many characters in a pattern are taken literally; they are matched during parsing and output unchanged during formatting. Special characters, on the other hand, stand for other characters, strings, or classes of characters. They must be quoted, unless noted otherwise, if they are to appear in the prefix or suffix as literals.

The characters listed here are used in non-localized patterns. Localized patterns use the corresponding characters taken from this formatter's DecimalFormatSymbols object instead, and these characters lose their special status. Two exceptions are the currency sign and quote, which are not localized.

Symbol Location Localized? Meaning
0 Number Yes Digit
# Number Yes Digit, zero shows as absent
. Number Yes Decimal separator or monetary decimal separator
- Number Yes Minus sign
, Number Yes Grouping separator
E Number Yes Separates mantissa and exponent in scientific notation. Need not be quoted in prefix or suffix.
; Subpattern boundary Yes Separates positive and negative subpatterns
% Prefix or suffix Yes Multiply by 100 and show as percentage
\u2030 Prefix or suffix Yes Multiply by 1000 and show as per mille value
¤ (\u00A4) Prefix or suffix No Currency sign, replaced by currency symbol. If doubled, replaced by international currency symbol. If present in a pattern, the monetary decimal separator is used instead of the decimal separator.
' Prefix or suffix No Used to quote special characters in a prefix or suffix, for example, "'#'#" formats 123 to "#123". To create a single quote itself, use two in a row: "# o''clock".

Scientific Notation

Numbers in scientific notation are expressed as the product of a mantissa and a power of ten, for example, 1234 can be expressed as 1.234 x 10^3. The mantissa is often in the range 1.0 <= x < 10.0, but it need not be. DecimalFormat can be instructed to format and parse scientific notation only via a pattern; there is currently no factory method that creates a scientific notation format. In a pattern, the exponent character immediately followed by one or more digit characters indicates scientific notation. Example: "0.###E0" formats the number 1234 as "1.234E3".

  • The number of digit characters after the exponent character gives the minimum exponent digit count. There is no maximum. Negative exponents are formatted using the localized minus sign, not the prefix and suffix from the pattern. This allows patterns such as "0.###E0 m/s".
  • The minimum and maximum number of integer digits are interpreted together:
    • If the maximum number of integer digits is greater than their minimum number and greater than 1, it forces the exponent to be a multiple of the maximum number of integer digits, and the minimum number of integer digits to be interpreted as 1. The most common use of this is to generate engineering notation, in which the exponent is a multiple of three, e.g., "##0.#####E0". Using this pattern, the number 12345 formats to "12.345E3", and 123456 formats to "123.456E3".
    • Otherwise, the minimum number of integer digits is achieved by adjusting the exponent. Example: 0.00123 formatted with "00.###E0" yields "12.3E-4".
  • The number of significant digits in the mantissa is the sum of the minimum integer and maximum fraction digits, and is unaffected by the maximum integer digits. For example, 12345 formatted with "##0.##E0" is "12.3E3". To show all digits, set the significant digits count to zero. The number of significant digits does not affect parsing.
  • Exponential patterns may not contain grouping separators.

Rounding

DecimalFormat provides rounding modes defined in RoundingMode for formatting. By default, it uses RoundingMode.HALF_EVEN.

Digits

For formatting, DecimalFormat uses the ten consecutive characters starting with the localized zero digit defined in the DecimalFormatSymbols object as digits. For parsing, these digits as well as all Unicode decimal digits, as defined by Character.digit, are recognized.

Special Values

NaN is formatted as a string, which typically has a single character \uFFFD. This string is determined by the DecimalFormatSymbols object. This is the only value for which the prefixes and suffixes are not used.

Infinity is formatted as a string, which typically has a single character \u221E, with the positive or negative prefixes and suffixes applied. The infinity string is determined by the DecimalFormatSymbols object.

Negative zero ("-0") parses to

  • BigDecimal(0) if isParseBigDecimal() is true,
  • Long(0) if isParseBigDecimal() is false and isParseIntegerOnly() is true,
  • Double(-0.0) if both isParseBigDecimal() and isParseIntegerOnly() are false.

Synchronization

Decimal formats are generally not synchronized. It is recommended to create separate format instances for each thread. If multiple threads access a format concurrently, it must be synchronized externally.

Example

// Print out a number using the localized number, integer, currency,
// and percent format for each locale
Locale[] locales = NumberFormat.getAvailableLocales();
double myNumber = -1234.56;
NumberFormat form;
for (int j=0; j<4; ++j) {
    System.out.println("FORMAT");
    for (int i = 0; i < locales.length; ++i) {
        if (locales[i].getCountry().length() == 0) {
           continue; // Skip language-only locales
        }
        System.out.print(locales[i].getDisplayName());
        switch (j) {
        case 0:
            form = NumberFormat.getInstance(locales[i]); break;
        case 1:
            form = NumberFormat.getIntegerInstance(locales[i]); break;
        case 2:
            form = NumberFormat.getCurrencyInstance(locales[i]); break;
        default:
            form = NumberFormat.getPercentInstance(locales[i]); break;
        }
        if (form instanceof DecimalFormat) {
            System.out.print(": " + ((DecimalFormat) form).toPattern());
        }
        System.out.print(" -> " + form.format(myNumber));
        try {
            System.out.println(" -> " + form.parse(form.format(myNumber)));
        } catch (ParseException e) {}
    }
}
Author: Mark Davis, Alan Liu
See Also:
/** * <code>DecimalFormat</code> is a concrete subclass of * <code>NumberFormat</code> that formats decimal numbers. It has a variety of * features designed to make it possible to parse and format numbers in any * locale, including support for Western, Arabic, and Indic digits. It also * supports different kinds of numbers, including integers (123), fixed-point * numbers (123.4), scientific notation (1.23E4), percentages (12%), and * currency amounts ($123). All of these can be localized. * * <p>To obtain a <code>NumberFormat</code> for a specific locale, including the * default locale, call one of <code>NumberFormat</code>'s factory methods, such * as <code>getInstance()</code>. In general, do not call the * <code>DecimalFormat</code> constructors directly, since the * <code>NumberFormat</code> factory methods may return subclasses other than * <code>DecimalFormat</code>. If you need to customize the format object, do * something like this: * * <blockquote><pre> * NumberFormat f = NumberFormat.getInstance(loc); * if (f instanceof DecimalFormat) { * ((DecimalFormat) f).setDecimalSeparatorAlwaysShown(true); * } * </pre></blockquote> * * <p>A <code>DecimalFormat</code> comprises a <em>pattern</em> and a set of * <em>symbols</em>. The pattern may be set directly using * <code>applyPattern()</code>, or indirectly using the API methods. The * symbols are stored in a <code>DecimalFormatSymbols</code> object. When using * the <code>NumberFormat</code> factory methods, the pattern and symbols are * read from localized <code>ResourceBundle</code>s. * * <h4>Patterns</h4> * * <code>DecimalFormat</code> patterns have the following syntax: * <blockquote><pre> * <i>Pattern:</i> * <i>PositivePattern</i> * <i>PositivePattern</i> ; <i>NegativePattern</i> * <i>PositivePattern:</i> * <i>Prefix<sub>opt</sub></i> <i>Number</i> <i>Suffix<sub>opt</sub></i> * <i>NegativePattern:</i> * <i>Prefix<sub>opt</sub></i> <i>Number</i> <i>Suffix<sub>opt</sub></i> * <i>Prefix:</i> * any Unicode characters except &#92;uFFFE, &#92;uFFFF, and special characters * <i>Suffix:</i> * any Unicode characters except &#92;uFFFE, &#92;uFFFF, and special characters * <i>Number:</i> * <i>Integer</i> <i>Exponent<sub>opt</sub></i> * <i>Integer</i> . <i>Fraction</i> <i>Exponent<sub>opt</sub></i> * <i>Integer:</i> * <i>MinimumInteger</i> * # * # <i>Integer</i> * # , <i>Integer</i> * <i>MinimumInteger:</i> * 0 * 0 <i>MinimumInteger</i> * 0 , <i>MinimumInteger</i> * <i>Fraction:</i> * <i>MinimumFraction<sub>opt</sub></i> <i>OptionalFraction<sub>opt</sub></i> * <i>MinimumFraction:</i> * 0 <i>MinimumFraction<sub>opt</sub></i> * <i>OptionalFraction:</i> * # <i>OptionalFraction<sub>opt</sub></i> * <i>Exponent:</i> * E <i>MinimumExponent</i> * <i>MinimumExponent:</i> * 0 <i>MinimumExponent<sub>opt</sub></i> * </pre></blockquote> * * <p>A <code>DecimalFormat</code> pattern contains a positive and negative * subpattern, for example, <code>"#,##0.00;(#,##0.00)"</code>. Each * subpattern has a prefix, numeric part, and suffix. The negative subpattern * is optional; if absent, then the positive subpattern prefixed with the * localized minus sign (<code>'-'</code> in most locales) is used as the * negative subpattern. That is, <code>"0.00"</code> alone is equivalent to * <code>"0.00;-0.00"</code>. If there is an explicit negative subpattern, it * serves only to specify the negative prefix and suffix; the number of digits, * minimal digits, and other characteristics are all the same as the positive * pattern. That means that <code>"#,##0.0#;(#)"</code> produces precisely * the same behavior as <code>"#,##0.0#;(#,##0.0#)"</code>. * * <p>The prefixes, suffixes, and various symbols used for infinity, digits, * thousands separators, decimal separators, etc. may be set to arbitrary * values, and they will appear properly during formatting. However, care must * be taken that the symbols and strings do not conflict, or parsing will be * unreliable. For example, either the positive and negative prefixes or the * suffixes must be distinct for <code>DecimalFormat.parse()</code> to be able * to distinguish positive from negative values. (If they are identical, then * <code>DecimalFormat</code> will behave as if no negative subpattern was * specified.) Another example is that the decimal separator and thousands * separator should be distinct characters, or parsing will be impossible. * * <p>The grouping separator is commonly used for thousands, but in some * countries it separates ten-thousands. The grouping size is a constant number * of digits between the grouping characters, such as 3 for 100,000,000 or 4 for * 1,0000,0000. If you supply a pattern with multiple grouping characters, the * interval between the last one and the end of the integer is the one that is * used. So <code>"#,##,###,####"</code> == <code>"######,####"</code> == * <code>"##,####,####"</code>. * * <h4>Special Pattern Characters</h4> * * <p>Many characters in a pattern are taken literally; they are matched during * parsing and output unchanged during formatting. Special characters, on the * other hand, stand for other characters, strings, or classes of characters. * They must be quoted, unless noted otherwise, if they are to appear in the * prefix or suffix as literals. * * <p>The characters listed here are used in non-localized patterns. Localized * patterns use the corresponding characters taken from this formatter's * <code>DecimalFormatSymbols</code> object instead, and these characters lose * their special status. Two exceptions are the currency sign and quote, which * are not localized. * * <blockquote> * <table border=0 cellspacing=3 cellpadding=0 summary="Chart showing symbol, * location, localized, and meaning."> * <tr bgcolor="#ccccff"> * <th align=left>Symbol * <th align=left>Location * <th align=left>Localized? * <th align=left>Meaning * <tr valign=top> * <td><code>0</code> * <td>Number * <td>Yes * <td>Digit * <tr valign=top bgcolor="#eeeeff"> * <td><code>#</code> * <td>Number * <td>Yes * <td>Digit, zero shows as absent * <tr valign=top> * <td><code>.</code> * <td>Number * <td>Yes * <td>Decimal separator or monetary decimal separator * <tr valign=top bgcolor="#eeeeff"> * <td><code>-</code> * <td>Number * <td>Yes * <td>Minus sign * <tr valign=top> * <td><code>,</code> * <td>Number * <td>Yes * <td>Grouping separator * <tr valign=top bgcolor="#eeeeff"> * <td><code>E</code> * <td>Number * <td>Yes * <td>Separates mantissa and exponent in scientific notation. * <em>Need not be quoted in prefix or suffix.</em> * <tr valign=top> * <td><code>;</code> * <td>Subpattern boundary * <td>Yes * <td>Separates positive and negative subpatterns * <tr valign=top bgcolor="#eeeeff"> * <td><code>%</code> * <td>Prefix or suffix * <td>Yes * <td>Multiply by 100 and show as percentage * <tr valign=top> * <td><code>&#92;u2030</code> * <td>Prefix or suffix * <td>Yes * <td>Multiply by 1000 and show as per mille value * <tr valign=top bgcolor="#eeeeff"> * <td><code>&#164;</code> (<code>&#92;u00A4</code>) * <td>Prefix or suffix * <td>No * <td>Currency sign, replaced by currency symbol. If * doubled, replaced by international currency symbol. * If present in a pattern, the monetary decimal separator * is used instead of the decimal separator. * <tr valign=top> * <td><code>'</code> * <td>Prefix or suffix * <td>No * <td>Used to quote special characters in a prefix or suffix, * for example, <code>"'#'#"</code> formats 123 to * <code>"#123"</code>. To create a single quote * itself, use two in a row: <code>"# o''clock"</code>. * </table> * </blockquote> * * <h4>Scientific Notation</h4> * * <p>Numbers in scientific notation are expressed as the product of a mantissa * and a power of ten, for example, 1234 can be expressed as 1.234 x 10^3. The * mantissa is often in the range 1.0 <= x < 10.0, but it need not be. * <code>DecimalFormat</code> can be instructed to format and parse scientific * notation <em>only via a pattern</em>; there is currently no factory method * that creates a scientific notation format. In a pattern, the exponent * character immediately followed by one or more digit characters indicates * scientific notation. Example: <code>"0.###E0"</code> formats the number * 1234 as <code>"1.234E3"</code>. * * <ul> * <li>The number of digit characters after the exponent character gives the * minimum exponent digit count. There is no maximum. Negative exponents are * formatted using the localized minus sign, <em>not</em> the prefix and suffix * from the pattern. This allows patterns such as <code>"0.###E0 m/s"</code>. * * <li>The minimum and maximum number of integer digits are interpreted * together: * * <ul> * <li>If the maximum number of integer digits is greater than their minimum number * and greater than 1, it forces the exponent to be a multiple of the maximum * number of integer digits, and the minimum number of integer digits to be * interpreted as 1. The most common use of this is to generate * <em>engineering notation</em>, in which the exponent is a multiple of three, * e.g., <code>"##0.#####E0"</code>. Using this pattern, the number 12345 * formats to <code>"12.345E3"</code>, and 123456 formats to * <code>"123.456E3"</code>. * * <li>Otherwise, the minimum number of integer digits is achieved by adjusting the * exponent. Example: 0.00123 formatted with <code>"00.###E0"</code> yields * <code>"12.3E-4"</code>. * </ul> * * <li>The number of significant digits in the mantissa is the sum of the * <em>minimum integer</em> and <em>maximum fraction</em> digits, and is * unaffected by the maximum integer digits. For example, 12345 formatted with * <code>"##0.##E0"</code> is <code>"12.3E3"</code>. To show all digits, set * the significant digits count to zero. The number of significant digits * does not affect parsing. * * <li>Exponential patterns may not contain grouping separators. * </ul> * * <h4>Rounding</h4> * * <code>DecimalFormat</code> provides rounding modes defined in * {@link java.math.RoundingMode} for formatting. By default, it uses * {@link java.math.RoundingMode#HALF_EVEN RoundingMode.HALF_EVEN}. * * <h4>Digits</h4> * * For formatting, <code>DecimalFormat</code> uses the ten consecutive * characters starting with the localized zero digit defined in the * <code>DecimalFormatSymbols</code> object as digits. For parsing, these * digits as well as all Unicode decimal digits, as defined by * {@link Character#digit Character.digit}, are recognized. * * <h4>Special Values</h4> * * <p><code>NaN</code> is formatted as a string, which typically has a single character * <code>&#92;uFFFD</code>. This string is determined by the * <code>DecimalFormatSymbols</code> object. This is the only value for which * the prefixes and suffixes are not used. * * <p>Infinity is formatted as a string, which typically has a single character * <code>&#92;u221E</code>, with the positive or negative prefixes and suffixes * applied. The infinity string is determined by the * <code>DecimalFormatSymbols</code> object. * * <p>Negative zero (<code>"-0"</code>) parses to * <ul> * <li><code>BigDecimal(0)</code> if <code>isParseBigDecimal()</code> is * true, * <li><code>Long(0)</code> if <code>isParseBigDecimal()</code> is false * and <code>isParseIntegerOnly()</code> is true, * <li><code>Double(-0.0)</code> if both <code>isParseBigDecimal()</code> * and <code>isParseIntegerOnly()</code> are false. * </ul> * * <h4><a name="synchronization">Synchronization</a></h4> * * <p> * Decimal formats are generally not synchronized. * It is recommended to create separate format instances for each thread. * If multiple threads access a format concurrently, it must be synchronized * externally. * * <h4>Example</h4> * * <blockquote><pre> * <strong>// Print out a number using the localized number, integer, currency, * // and percent format for each locale</strong> * Locale[] locales = NumberFormat.getAvailableLocales(); * double myNumber = -1234.56; * NumberFormat form; * for (int j=0; j<4; ++j) { * System.out.println("FORMAT"); * for (int i = 0; i < locales.length; ++i) { * if (locales[i].getCountry().length() == 0) { * continue; // Skip language-only locales * } * System.out.print(locales[i].getDisplayName()); * switch (j) { * case 0: * form = NumberFormat.getInstance(locales[i]); break; * case 1: * form = NumberFormat.getIntegerInstance(locales[i]); break; * case 2: * form = NumberFormat.getCurrencyInstance(locales[i]); break; * default: * form = NumberFormat.getPercentInstance(locales[i]); break; * } * if (form instanceof DecimalFormat) { * System.out.print(": " + ((DecimalFormat) form).toPattern()); * } * System.out.print(" -> " + form.format(myNumber)); * try { * System.out.println(" -> " + form.parse(form.format(myNumber))); * } catch (ParseException e) {} * } * } * </pre></blockquote> * * @see <a href="http://java.sun.com/docs/books/tutorial/i18n/format/decimalFormat.html">Java Tutorial</a> * @see NumberFormat * @see DecimalFormatSymbols * @see ParsePosition * @author Mark Davis * @author Alan Liu */
public class DecimalFormat extends NumberFormat {
Creates a DecimalFormat using the default pattern and symbols for the default locale. This is a convenient way to obtain a DecimalFormat when internationalization is not the main concern.

To obtain standard formats for a given locale, use the factory methods on NumberFormat such as getNumberInstance. These factories will return the most appropriate sub-class of NumberFormat for a given locale.

See Also:
/** * Creates a DecimalFormat using the default pattern and symbols * for the default locale. This is a convenient way to obtain a * DecimalFormat when internationalization is not the main concern. * <p> * To obtain standard formats for a given locale, use the factory methods * on NumberFormat such as getNumberInstance. These factories will * return the most appropriate sub-class of NumberFormat for a given * locale. * * @see java.text.NumberFormat#getInstance * @see java.text.NumberFormat#getNumberInstance * @see java.text.NumberFormat#getCurrencyInstance * @see java.text.NumberFormat#getPercentInstance */
public DecimalFormat() { Locale def = Locale.getDefault(); // try to get the pattern from the cache String pattern = (String) cachedLocaleData.get(def); if (pattern == null) { /* cache miss */ // Get the pattern for the default locale. ResourceBundle rb = LocaleData.getNumberFormatData(def); String[] all = rb.getStringArray("NumberPatterns"); pattern = all[0]; /* update cache */ cachedLocaleData.put(def, pattern); } // Always applyPattern after the symbols are set this.symbols = new DecimalFormatSymbols(def); applyPattern(pattern, false); }
Creates a DecimalFormat using the given pattern and the symbols for the default locale. This is a convenient way to obtain a DecimalFormat when internationalization is not the main concern.

To obtain standard formats for a given locale, use the factory methods on NumberFormat such as getNumberInstance. These factories will return the most appropriate sub-class of NumberFormat for a given locale.

Params:
  • pattern – A non-localized pattern string.
Throws:
See Also:
/** * Creates a DecimalFormat using the given pattern and the symbols * for the default locale. This is a convenient way to obtain a * DecimalFormat when internationalization is not the main concern. * <p> * To obtain standard formats for a given locale, use the factory methods * on NumberFormat such as getNumberInstance. These factories will * return the most appropriate sub-class of NumberFormat for a given * locale. * * @param pattern A non-localized pattern string. * @exception NullPointerException if <code>pattern</code> is null * @exception IllegalArgumentException if the given pattern is invalid. * @see java.text.NumberFormat#getInstance * @see java.text.NumberFormat#getNumberInstance * @see java.text.NumberFormat#getCurrencyInstance * @see java.text.NumberFormat#getPercentInstance */
public DecimalFormat(String pattern) { // Always applyPattern after the symbols are set this.symbols = new DecimalFormatSymbols(Locale.getDefault()); applyPattern(pattern, false); }
Creates a DecimalFormat using the given pattern and symbols. Use this constructor when you need to completely customize the behavior of the format.

To obtain standard formats for a given locale, use the factory methods on NumberFormat such as getInstance or getCurrencyInstance. If you need only minor adjustments to a standard format, you can modify the format returned by a NumberFormat factory method.

Params:
  • pattern – a non-localized pattern string
  • symbols – the set of symbols to be used
Throws:
See Also:
/** * Creates a DecimalFormat using the given pattern and symbols. * Use this constructor when you need to completely customize the * behavior of the format. * <p> * To obtain standard formats for a given * locale, use the factory methods on NumberFormat such as * getInstance or getCurrencyInstance. If you need only minor adjustments * to a standard format, you can modify the format returned by * a NumberFormat factory method. * * @param pattern a non-localized pattern string * @param symbols the set of symbols to be used * @exception NullPointerException if any of the given arguments is null * @exception IllegalArgumentException if the given pattern is invalid * @see java.text.NumberFormat#getInstance * @see java.text.NumberFormat#getNumberInstance * @see java.text.NumberFormat#getCurrencyInstance * @see java.text.NumberFormat#getPercentInstance * @see java.text.DecimalFormatSymbols */
public DecimalFormat (String pattern, DecimalFormatSymbols symbols) { // Always applyPattern after the symbols are set this.symbols = (DecimalFormatSymbols)symbols.clone(); applyPattern(pattern, false); } // Overrides
Formats a number and appends the resulting text to the given string buffer. The number can be of any subclass of Number.

This implementation uses the maximum precision permitted.

Params:
  • number – the number to format
  • toAppendTo – the StringBuffer to which the formatted text is to be appended
  • pos – On input: an alignment field, if desired. On output: the offsets of the alignment field.
Throws:
See Also:
Returns: the value passed in as toAppendTo
/** * Formats a number and appends the resulting text to the given string * buffer. * The number can be of any subclass of {@link java.lang.Number}. * <p> * This implementation uses the maximum precision permitted. * @param number the number to format * @param toAppendTo the <code>StringBuffer</code> to which the formatted * text is to be appended * @param pos On input: an alignment field, if desired. * On output: the offsets of the alignment field. * @return the value passed in as <code>toAppendTo</code> * @exception IllegalArgumentException if <code>number</code> is * null or not an instance of <code>Number</code>. * @exception NullPointerException if <code>toAppendTo</code> or * <code>pos</code> is null * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @see java.text.FieldPosition */
public final StringBuffer format(Object number, StringBuffer toAppendTo, FieldPosition pos) { if (number instanceof Long || number instanceof Integer || number instanceof Short || number instanceof Byte || number instanceof AtomicInteger || number instanceof AtomicLong || (number instanceof BigInteger && ((BigInteger)number).bitLength () < 64)) { return format(((Number)number).longValue(), toAppendTo, pos); } else if (number instanceof BigDecimal) { return format((BigDecimal)number, toAppendTo, pos); } else if (number instanceof BigInteger) { return format((BigInteger)number, toAppendTo, pos); } else if (number instanceof Number) { return format(((Number)number).doubleValue(), toAppendTo, pos); } else { throw new IllegalArgumentException("Cannot format given Object as a Number"); } }
Formats a double to produce a string.
Params:
  • number – The double to format
  • result – where the text is to be appended
  • fieldPosition – On input: an alignment field, if desired. On output: the offsets of the alignment field.
Throws:
  • ArithmeticException – if rounding is needed with rounding mode being set to RoundingMode.UNNECESSARY
See Also:
Returns:The formatted number string
/** * Formats a double to produce a string. * @param number The double to format * @param result where the text is to be appended * @param fieldPosition On input: an alignment field, if desired. * On output: the offsets of the alignment field. * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @return The formatted number string * @see java.text.FieldPosition */
public StringBuffer format(double number, StringBuffer result, FieldPosition fieldPosition) { fieldPosition.setBeginIndex(0); fieldPosition.setEndIndex(0); return format(number, result, fieldPosition.getFieldDelegate()); }
Formats a double to produce a string.
Params:
  • number – The double to format
  • result – where the text is to be appended
  • delegate – notified of locations of sub fields
Throws:
  • ArithmeticException – if rounding is needed with rounding mode being set to RoundingMode.UNNECESSARY
Returns:The formatted number string
/** * Formats a double to produce a string. * @param number The double to format * @param result where the text is to be appended * @param delegate notified of locations of sub fields * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @return The formatted number string */
private StringBuffer format(double number, StringBuffer result, FieldDelegate delegate) { if (Double.isNaN(number) || (Double.isInfinite(number) && multiplier == 0)) { int iFieldStart = result.length(); result.append(symbols.getNaN()); delegate.formatted(INTEGER_FIELD, Field.INTEGER, Field.INTEGER, iFieldStart, result.length(), result); return result; } /* Detecting whether a double is negative is easy with the exception of * the value -0.0. This is a double which has a zero mantissa (and * exponent), but a negative sign bit. It is semantically distinct from * a zero with a positive sign bit, and this distinction is important * to certain kinds of computations. However, it's a little tricky to * detect, since (-0.0 == 0.0) and !(-0.0 < 0.0). How then, you may * ask, does it behave distinctly from +0.0? Well, 1/(-0.0) == * -Infinity. Proper detection of -0.0 is needed to deal with the * issues raised by bugs 4106658, 4106667, and 4147706. Liu 7/6/98. */ boolean isNegative = ((number < 0.0) || (number == 0.0 && 1/number < 0.0)) ^ (multiplier < 0); if (multiplier != 1) { number *= multiplier; } if (Double.isInfinite(number)) { if (isNegative) { append(result, negativePrefix, delegate, getNegativePrefixFieldPositions(), Field.SIGN); } else { append(result, positivePrefix, delegate, getPositivePrefixFieldPositions(), Field.SIGN); } int iFieldStart = result.length(); result.append(symbols.getInfinity()); delegate.formatted(INTEGER_FIELD, Field.INTEGER, Field.INTEGER, iFieldStart, result.length(), result); if (isNegative) { append(result, negativeSuffix, delegate, getNegativeSuffixFieldPositions(), Field.SIGN); } else { append(result, positiveSuffix, delegate, getPositiveSuffixFieldPositions(), Field.SIGN); } return result; } if (isNegative) { number = -number; } // at this point we are guaranteed a nonnegative finite number. assert(number >= 0 && !Double.isInfinite(number)); synchronized(digitList) { int maxIntDigits = super.getMaximumIntegerDigits(); int minIntDigits = super.getMinimumIntegerDigits(); int maxFraDigits = super.getMaximumFractionDigits(); int minFraDigits = super.getMinimumFractionDigits(); digitList.set(isNegative, number, useExponentialNotation ? maxIntDigits + maxFraDigits : maxFraDigits, !useExponentialNotation); return subformat(result, delegate, isNegative, false, maxIntDigits, minIntDigits, maxFraDigits, minFraDigits); } }
Format a long to produce a string.
Params:
  • number – The long to format
  • result – where the text is to be appended
  • fieldPosition – On input: an alignment field, if desired. On output: the offsets of the alignment field.
Throws:
  • ArithmeticException – if rounding is needed with rounding mode being set to RoundingMode.UNNECESSARY
See Also:
Returns:The formatted number string
/** * Format a long to produce a string. * @param number The long to format * @param result where the text is to be appended * @param fieldPosition On input: an alignment field, if desired. * On output: the offsets of the alignment field. * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @return The formatted number string * @see java.text.FieldPosition */
public StringBuffer format(long number, StringBuffer result, FieldPosition fieldPosition) { fieldPosition.setBeginIndex(0); fieldPosition.setEndIndex(0); return format(number, result, fieldPosition.getFieldDelegate()); }
Format a long to produce a string.
Params:
  • number – The long to format
  • result – where the text is to be appended
  • delegate – notified of locations of sub fields
Throws:
  • ArithmeticException – if rounding is needed with rounding mode being set to RoundingMode.UNNECESSARY
See Also:
Returns:The formatted number string
/** * Format a long to produce a string. * @param number The long to format * @param result where the text is to be appended * @param delegate notified of locations of sub fields * @return The formatted number string * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @see java.text.FieldPosition */
private StringBuffer format(long number, StringBuffer result, FieldDelegate delegate) { boolean isNegative = (number < 0); if (isNegative) { number = -number; } // In general, long values always represent real finite numbers, so // we don't have to check for +/- Infinity or NaN. However, there // is one case we have to be careful of: The multiplier can push // a number near MIN_VALUE or MAX_VALUE outside the legal range. We // check for this before multiplying, and if it happens we use // BigInteger instead. boolean useBigInteger = false; if (number < 0) { // This can only happen if number == Long.MIN_VALUE. if (multiplier != 0) { useBigInteger = true; } } else if (multiplier != 1 && multiplier != 0) { long cutoff = Long.MAX_VALUE / multiplier; if (cutoff < 0) { cutoff = -cutoff; } useBigInteger = (number > cutoff); } if (useBigInteger) { if (isNegative) { number = -number; } BigInteger bigIntegerValue = BigInteger.valueOf(number); return format(bigIntegerValue, result, delegate, true); } number *= multiplier; if (number == 0) { isNegative = false; } else { if (multiplier < 0) { number = -number; isNegative = !isNegative; } } synchronized(digitList) { int maxIntDigits = super.getMaximumIntegerDigits(); int minIntDigits = super.getMinimumIntegerDigits(); int maxFraDigits = super.getMaximumFractionDigits(); int minFraDigits = super.getMinimumFractionDigits(); digitList.set(isNegative, number, useExponentialNotation ? maxIntDigits + maxFraDigits : 0); return subformat(result, delegate, isNegative, true, maxIntDigits, minIntDigits, maxFraDigits, minFraDigits); } }
Formats a BigDecimal to produce a string.
Params:
  • number – The BigDecimal to format
  • result – where the text is to be appended
  • fieldPosition – On input: an alignment field, if desired. On output: the offsets of the alignment field.
Throws:
  • ArithmeticException – if rounding is needed with rounding mode being set to RoundingMode.UNNECESSARY
See Also:
Returns:The formatted number string
/** * Formats a BigDecimal to produce a string. * @param number The BigDecimal to format * @param result where the text is to be appended * @param fieldPosition On input: an alignment field, if desired. * On output: the offsets of the alignment field. * @return The formatted number string * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @see java.text.FieldPosition */
private StringBuffer format(BigDecimal number, StringBuffer result, FieldPosition fieldPosition) { fieldPosition.setBeginIndex(0); fieldPosition.setEndIndex(0); return format(number, result, fieldPosition.getFieldDelegate()); }
Formats a BigDecimal to produce a string.
Params:
  • number – The BigDecimal to format
  • result – where the text is to be appended
  • delegate – notified of locations of sub fields
Throws:
  • ArithmeticException – if rounding is needed with rounding mode being set to RoundingMode.UNNECESSARY
Returns:The formatted number string
/** * Formats a BigDecimal to produce a string. * @param number The BigDecimal to format * @param result where the text is to be appended * @param delegate notified of locations of sub fields * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @return The formatted number string */
private StringBuffer format(BigDecimal number, StringBuffer result, FieldDelegate delegate) { if (multiplier != 1) { number = number.multiply(getBigDecimalMultiplier()); } boolean isNegative = number.signum() == -1; if (isNegative) { number = number.negate(); } synchronized(digitList) { int maxIntDigits = getMaximumIntegerDigits(); int minIntDigits = getMinimumIntegerDigits(); int maxFraDigits = getMaximumFractionDigits(); int minFraDigits = getMinimumFractionDigits(); int maximumDigits = maxIntDigits + maxFraDigits; digitList.set(isNegative, number, useExponentialNotation ? ((maximumDigits < 0) ? Integer.MAX_VALUE : maximumDigits) : maxFraDigits, !useExponentialNotation); return subformat(result, delegate, isNegative, false, maxIntDigits, minIntDigits, maxFraDigits, minFraDigits); } }
Format a BigInteger to produce a string.
Params:
  • number – The BigInteger to format
  • result – where the text is to be appended
  • fieldPosition – On input: an alignment field, if desired. On output: the offsets of the alignment field.
Throws:
  • ArithmeticException – if rounding is needed with rounding mode being set to RoundingMode.UNNECESSARY
See Also:
Returns:The formatted number string
/** * Format a BigInteger to produce a string. * @param number The BigInteger to format * @param result where the text is to be appended * @param fieldPosition On input: an alignment field, if desired. * On output: the offsets of the alignment field. * @return The formatted number string * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @see java.text.FieldPosition */
private StringBuffer format(BigInteger number, StringBuffer result, FieldPosition fieldPosition) { fieldPosition.setBeginIndex(0); fieldPosition.setEndIndex(0); return format(number, result, fieldPosition.getFieldDelegate(), false); }
Format a BigInteger to produce a string.
Params:
  • number – The BigInteger to format
  • result – where the text is to be appended
  • delegate – notified of locations of sub fields
Throws:
  • ArithmeticException – if rounding is needed with rounding mode being set to RoundingMode.UNNECESSARY
See Also:
Returns:The formatted number string
/** * Format a BigInteger to produce a string. * @param number The BigInteger to format * @param result where the text is to be appended * @param delegate notified of locations of sub fields * @return The formatted number string * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @see java.text.FieldPosition */
private StringBuffer format(BigInteger number, StringBuffer result, FieldDelegate delegate, boolean formatLong) { if (multiplier != 1) { number = number.multiply(getBigIntegerMultiplier()); } boolean isNegative = number.signum() == -1; if (isNegative) { number = number.negate(); } synchronized(digitList) { int maxIntDigits, minIntDigits, maxFraDigits, minFraDigits, maximumDigits; if (formatLong) { maxIntDigits = super.getMaximumIntegerDigits(); minIntDigits = super.getMinimumIntegerDigits(); maxFraDigits = super.getMaximumFractionDigits(); minFraDigits = super.getMinimumFractionDigits(); maximumDigits = maxIntDigits + maxFraDigits; } else { maxIntDigits = getMaximumIntegerDigits(); minIntDigits = getMinimumIntegerDigits(); maxFraDigits = getMaximumFractionDigits(); minFraDigits = getMinimumFractionDigits(); maximumDigits = maxIntDigits + maxFraDigits; if (maximumDigits < 0) { maximumDigits = Integer.MAX_VALUE; } } digitList.set(isNegative, number, useExponentialNotation ? maximumDigits : 0); return subformat(result, delegate, isNegative, true, maxIntDigits, minIntDigits, maxFraDigits, minFraDigits); } }
Formats an Object producing an AttributedCharacterIterator. You can use the returned AttributedCharacterIterator to build the resulting String, as well as to determine information about the resulting String.

Each attribute key of the AttributedCharacterIterator will be of type NumberFormat.Field, with the attribute value being the same as the attribute key.

Params:
  • obj – The object to format
Throws:
  • NullPointerException – if obj is null.
  • IllegalArgumentException – when the Format cannot format the given object.
  • ArithmeticException – if rounding is needed with rounding mode being set to RoundingMode.UNNECESSARY
Returns:AttributedCharacterIterator describing the formatted value.
Since:1.4
/** * Formats an Object producing an <code>AttributedCharacterIterator</code>. * You can use the returned <code>AttributedCharacterIterator</code> * to build the resulting String, as well as to determine information * about the resulting String. * <p> * Each attribute key of the AttributedCharacterIterator will be of type * <code>NumberFormat.Field</code>, with the attribute value being the * same as the attribute key. * * @exception NullPointerException if obj is null. * @exception IllegalArgumentException when the Format cannot format the * given object. * @exception ArithmeticException if rounding is needed with rounding * mode being set to RoundingMode.UNNECESSARY * @param obj The object to format * @return AttributedCharacterIterator describing the formatted value. * @since 1.4 */
public AttributedCharacterIterator formatToCharacterIterator(Object obj) { CharacterIteratorFieldDelegate delegate = new CharacterIteratorFieldDelegate(); StringBuffer sb = new StringBuffer(); if (obj instanceof Double || obj instanceof Float) { format(((Number)obj).doubleValue(), sb, delegate); } else if (obj instanceof Long || obj instanceof Integer || obj instanceof Short || obj instanceof Byte || obj instanceof AtomicInteger || obj instanceof AtomicLong) { format(((Number)obj).longValue(), sb, delegate); } else if (obj instanceof BigDecimal) { format((BigDecimal)obj, sb, delegate); } else if (obj instanceof BigInteger) { format((BigInteger)obj, sb, delegate, false); } else if (obj == null) { throw new NullPointerException( "formatToCharacterIterator must be passed non-null object"); } else { throw new IllegalArgumentException( "Cannot format given Object as a Number"); } return delegate.getIterator(sb.toString()); }
Complete the formatting of a finite number. On entry, the digitList must be filled in with the correct digits.
/** * Complete the formatting of a finite number. On entry, the digitList must * be filled in with the correct digits. */
private StringBuffer subformat(StringBuffer result, FieldDelegate delegate, boolean isNegative, boolean isInteger, int maxIntDigits, int minIntDigits, int maxFraDigits, int minFraDigits) { // NOTE: This isn't required anymore because DigitList takes care of this. // // // The negative of the exponent represents the number of leading // // zeros between the decimal and the first non-zero digit, for // // a value < 0.1 (e.g., for 0.00123, -fExponent == 2). If this // // is more than the maximum fraction digits, then we have an underflow // // for the printed representation. We recognize this here and set // // the DigitList representation to zero in this situation. // // if (-digitList.decimalAt >= getMaximumFractionDigits()) // { // digitList.count = 0; // } char zero = symbols.getZeroDigit(); int zeroDelta = zero - '0'; // '0' is the DigitList representation of zero char grouping = symbols.getGroupingSeparator(); char decimal = isCurrencyFormat ? symbols.getMonetaryDecimalSeparator() : symbols.getDecimalSeparator(); /* Per bug 4147706, DecimalFormat must respect the sign of numbers which * format as zero. This allows sensible computations and preserves * relations such as signum(1/x) = signum(x), where x is +Infinity or * -Infinity. Prior to this fix, we always formatted zero values as if * they were positive. Liu 7/6/98. */ if (digitList.isZero()) { digitList.decimalAt = 0; // Normalize } if (isNegative) { append(result, negativePrefix, delegate, getNegativePrefixFieldPositions(), Field.SIGN); } else { append(result, positivePrefix, delegate, getPositivePrefixFieldPositions(), Field.SIGN); } if (useExponentialNotation) { int iFieldStart = result.length(); int iFieldEnd = -1; int fFieldStart = -1; // Minimum integer digits are handled in exponential format by // adjusting the exponent. For example, 0.01234 with 3 minimum // integer digits is "123.4E-4". // Maximum integer digits are interpreted as indicating the // repeating range. This is useful for engineering notation, in // which the exponent is restricted to a multiple of 3. For // example, 0.01234 with 3 maximum integer digits is "12.34e-3". // If maximum integer digits are > 1 and are larger than // minimum integer digits, then minimum integer digits are // ignored. int exponent = digitList.decimalAt; int repeat = maxIntDigits; int minimumIntegerDigits = minIntDigits; if (repeat > 1 && repeat > minIntDigits) { // A repeating range is defined; adjust to it as follows. // If repeat == 3, we have 6,5,4=>3; 3,2,1=>0; 0,-1,-2=>-3; // -3,-4,-5=>-6, etc. This takes into account that the // exponent we have here is off by one from what we expect; // it is for the format 0.MMMMMx10^n. if (exponent >= 1) { exponent = ((exponent - 1) / repeat) * repeat; } else { // integer division rounds towards 0 exponent = ((exponent - repeat) / repeat) * repeat; } minimumIntegerDigits = 1; } else { // No repeating range is defined; use minimum integer digits. exponent -= minimumIntegerDigits; } // We now output a minimum number of digits, and more if there // are more digits, up to the maximum number of digits. We // place the decimal point after the "integer" digits, which // are the first (decimalAt - exponent) digits. int minimumDigits = minIntDigits + minFraDigits; if (minimumDigits < 0) { // overflow? minimumDigits = Integer.MAX_VALUE; } // The number of integer digits is handled specially if the number // is zero, since then there may be no digits. int integerDigits = digitList.isZero() ? minimumIntegerDigits : digitList.decimalAt - exponent; if (minimumDigits < integerDigits) { minimumDigits = integerDigits; } int totalDigits = digitList.count; if (minimumDigits > totalDigits) { totalDigits = minimumDigits; } boolean addedDecimalSeparator = false; for (int i=0; i<totalDigits; ++i) { if (i == integerDigits) { // Record field information for caller. iFieldEnd = result.length(); result.append(decimal); addedDecimalSeparator = true; // Record field information for caller. fFieldStart = result.length(); } result.append((i < digitList.count) ? (char)(digitList.digits[i] + zeroDelta) : zero); } if (decimalSeparatorAlwaysShown && totalDigits == integerDigits) { // Record field information for caller. iFieldEnd = result.length(); result.append(decimal); addedDecimalSeparator = true; // Record field information for caller. fFieldStart = result.length(); } // Record field information if (iFieldEnd == -1) { iFieldEnd = result.length(); } delegate.formatted(INTEGER_FIELD, Field.INTEGER, Field.INTEGER, iFieldStart, iFieldEnd, result); if (addedDecimalSeparator) { delegate.formatted(Field.DECIMAL_SEPARATOR, Field.DECIMAL_SEPARATOR, iFieldEnd, fFieldStart, result); } if (fFieldStart == -1) { fFieldStart = result.length(); } delegate.formatted(FRACTION_FIELD, Field.FRACTION, Field.FRACTION, fFieldStart, result.length(), result); // The exponent is output using the pattern-specified minimum // exponent digits. There is no maximum limit to the exponent // digits, since truncating the exponent would result in an // unacceptable inaccuracy. int fieldStart = result.length(); result.append(symbols.getExponentSeparator()); delegate.formatted(Field.EXPONENT_SYMBOL, Field.EXPONENT_SYMBOL, fieldStart, result.length(), result); // For zero values, we force the exponent to zero. We // must do this here, and not earlier, because the value // is used to determine integer digit count above. if (digitList.isZero()) { exponent = 0; } boolean negativeExponent = exponent < 0; if (negativeExponent) { exponent = -exponent; fieldStart = result.length(); result.append(symbols.getMinusSign()); delegate.formatted(Field.EXPONENT_SIGN, Field.EXPONENT_SIGN, fieldStart, result.length(), result); } digitList.set(negativeExponent, exponent); int eFieldStart = result.length(); for (int i=digitList.decimalAt; i<minExponentDigits; ++i) { result.append(zero); } for (int i=0; i<digitList.decimalAt; ++i) { result.append((i < digitList.count) ? (char)(digitList.digits[i] + zeroDelta) : zero); } delegate.formatted(Field.EXPONENT, Field.EXPONENT, eFieldStart, result.length(), result); } else { int iFieldStart = result.length(); // Output the integer portion. Here 'count' is the total // number of integer digits we will display, including both // leading zeros required to satisfy getMinimumIntegerDigits, // and actual digits present in the number. int count = minIntDigits; int digitIndex = 0; // Index into digitList.fDigits[] if (digitList.decimalAt > 0 && count < digitList.decimalAt) { count = digitList.decimalAt; } // Handle the case where getMaximumIntegerDigits() is smaller // than the real number of integer digits. If this is so, we // output the least significant max integer digits. For example, // the value 1997 printed with 2 max integer digits is just "97". if (count > maxIntDigits) { count = maxIntDigits; digitIndex = digitList.decimalAt - count; } int sizeBeforeIntegerPart = result.length(); for (int i=count-1; i>=0; --i) { if (i < digitList.decimalAt && digitIndex < digitList.count) { // Output a real digit result.append((char)(digitList.digits[digitIndex++] + zeroDelta)); } else { // Output a leading zero result.append(zero); } // Output grouping separator if necessary. Don't output a // grouping separator if i==0 though; that's at the end of // the integer part. if (isGroupingUsed() && i>0 && (groupingSize != 0) && (i % groupingSize == 0)) { int gStart = result.length(); result.append(grouping); delegate.formatted(Field.GROUPING_SEPARATOR, Field.GROUPING_SEPARATOR, gStart, result.length(), result); } } // Determine whether or not there are any printable fractional // digits. If we've used up the digits we know there aren't. boolean fractionPresent = (minFraDigits > 0) || (!isInteger && digitIndex < digitList.count); // If there is no fraction present, and we haven't printed any // integer digits, then print a zero. Otherwise we won't print // _any_ digits, and we won't be able to parse this string. if (!fractionPresent && result.length() == sizeBeforeIntegerPart) { result.append(zero); } delegate.formatted(INTEGER_FIELD, Field.INTEGER, Field.INTEGER, iFieldStart, result.length(), result); // Output the decimal separator if we always do so. int sStart = result.length(); if (decimalSeparatorAlwaysShown || fractionPresent) { result.append(decimal); } if (sStart != result.length()) { delegate.formatted(Field.DECIMAL_SEPARATOR, Field.DECIMAL_SEPARATOR, sStart, result.length(), result); } int fFieldStart = result.length(); for (int i=0; i < maxFraDigits; ++i) { // Here is where we escape from the loop. We escape if we've // output the maximum fraction digits (specified in the for // expression above). // We also stop when we've output the minimum digits and either: // we have an integer, so there is no fractional stuff to // display, or we're out of significant digits. if (i >= minFraDigits && (isInteger || digitIndex >= digitList.count)) { break; } // Output leading fractional zeros. These are zeros that come // after the decimal but before any significant digits. These // are only output if abs(number being formatted) < 1.0. if (-1-i > (digitList.decimalAt-1)) { result.append(zero); continue; } // Output a digit, if we have any precision left, or a // zero if we don't. We don't want to output noise digits. if (!isInteger && digitIndex < digitList.count) { result.append((char)(digitList.digits[digitIndex++] + zeroDelta)); } else { result.append(zero); } } // Record field information for caller. delegate.formatted(FRACTION_FIELD, Field.FRACTION, Field.FRACTION, fFieldStart, result.length(), result); } if (isNegative) { append(result, negativeSuffix, delegate, getNegativeSuffixFieldPositions(), Field.SIGN); } else { append(result, positiveSuffix, delegate, getPositiveSuffixFieldPositions(), Field.SIGN); } return result; }
Appends the String string to result. delegate is notified of all the FieldPositions in positions.

If one of the FieldPositions in positions identifies a SIGN attribute, it is mapped to signAttribute. This is used to map the SIGN attribute to the EXPONENT attribute as necessary.

This is used by subformat to add the prefix/suffix.

/** * Appends the String <code>string</code> to <code>result</code>. * <code>delegate</code> is notified of all the * <code>FieldPosition</code>s in <code>positions</code>. * <p> * If one of the <code>FieldPosition</code>s in <code>positions</code> * identifies a <code>SIGN</code> attribute, it is mapped to * <code>signAttribute</code>. This is used * to map the <code>SIGN</code> attribute to the <code>EXPONENT</code> * attribute as necessary. * <p> * This is used by <code>subformat</code> to add the prefix/suffix. */
private void append(StringBuffer result, String string, FieldDelegate delegate, FieldPosition[] positions, Format.Field signAttribute) { int start = result.length(); if (string.length() > 0) { result.append(string); for (int counter = 0, max = positions.length; counter < max; counter++) { FieldPosition fp = positions[counter]; Format.Field attribute = fp.getFieldAttribute(); if (attribute == Field.SIGN) { attribute = signAttribute; } delegate.formatted(attribute, attribute, start + fp.getBeginIndex(), start + fp.getEndIndex(), result); } } }
Parses text from a string to produce a Number.

The method attempts to parse text starting at the index given by pos. If parsing succeeds, then the index of pos is updated to the index after the last character used (parsing does not necessarily use all characters up to the end of the string), and the parsed number is returned. The updated pos can be used to indicate the starting point for the next call to this method. If an error occurs, then the index of pos is not changed, the error index of pos is set to the index of the character where the error occurred, and null is returned.

The subclass returned depends on the value of isParseBigDecimal as well as on the string being parsed.

  • If isParseBigDecimal() is false (the default), most integer values are returned as Long objects, no matter how they are written: "17" and "17.000" both parse to Long(17). Values that cannot fit into a Long are returned as Doubles. This includes values with a fractional part, infinite values, NaN, and the value -0.0. DecimalFormat does not decide whether to return a Double or a Long based on the presence of a decimal separator in the source string. Doing so would prevent integers that overflow the mantissa of a double, such as "-9,223,372,036,854,775,808.00", from being parsed accurately.

    Callers may use the Number methods doubleValue, longValue, etc., to obtain the type they want.

  • If isParseBigDecimal() is true, values are returned as BigDecimal objects. The values are the ones constructed by BigDecimal(String) for corresponding strings in locale-independent format. The special cases negative and positive infinity and NaN are returned as Double instances holding the values of the corresponding Double constants.

DecimalFormat parses all Unicode characters that represent decimal digits, as defined by Character.digit(). In addition, DecimalFormat also recognizes as digits the ten consecutive characters starting with the localized zero digit defined in the DecimalFormatSymbols object.

Params:
  • text – the string to be parsed
  • pos – A ParsePosition object with index and error index information as described above.
Throws:
Returns: the parsed value, or null if the parse fails
/** * Parses text from a string to produce a <code>Number</code>. * <p> * The method attempts to parse text starting at the index given by * <code>pos</code>. * If parsing succeeds, then the index of <code>pos</code> is updated * to the index after the last character used (parsing does not necessarily * use all characters up to the end of the string), and the parsed * number is returned. The updated <code>pos</code> can be used to * indicate the starting point for the next call to this method. * If an error occurs, then the index of <code>pos</code> is not * changed, the error index of <code>pos</code> is set to the index of * the character where the error occurred, and null is returned. * <p> * The subclass returned depends on the value of {@link #isParseBigDecimal} * as well as on the string being parsed. * <ul> * <li>If <code>isParseBigDecimal()</code> is false (the default), * most integer values are returned as <code>Long</code> * objects, no matter how they are written: <code>"17"</code> and * <code>"17.000"</code> both parse to <code>Long(17)</code>. * Values that cannot fit into a <code>Long</code> are returned as * <code>Double</code>s. This includes values with a fractional part, * infinite values, <code>NaN</code>, and the value -0.0. * <code>DecimalFormat</code> does <em>not</em> decide whether to * return a <code>Double</code> or a <code>Long</code> based on the * presence of a decimal separator in the source string. Doing so * would prevent integers that overflow the mantissa of a double, * such as <code>"-9,223,372,036,854,775,808.00"</code>, from being * parsed accurately. * <p> * Callers may use the <code>Number</code> methods * <code>doubleValue</code>, <code>longValue</code>, etc., to obtain * the type they want. * <li>If <code>isParseBigDecimal()</code> is true, values are returned * as <code>BigDecimal</code> objects. The values are the ones * constructed by {@link java.math.BigDecimal#BigDecimal(String)} * for corresponding strings in locale-independent format. The * special cases negative and positive infinity and NaN are returned * as <code>Double</code> instances holding the values of the * corresponding <code>Double</code> constants. * </ul> * <p> * <code>DecimalFormat</code> parses all Unicode characters that represent * decimal digits, as defined by <code>Character.digit()</code>. In * addition, <code>DecimalFormat</code> also recognizes as digits the ten * consecutive characters starting with the localized zero digit defined in * the <code>DecimalFormatSymbols</code> object. * * @param text the string to be parsed * @param pos A <code>ParsePosition</code> object with index and error * index information as described above. * @return the parsed value, or <code>null</code> if the parse fails * @exception NullPointerException if <code>text</code> or * <code>pos</code> is null. */
public Number parse(String text, ParsePosition pos) { // special case NaN if (text.regionMatches(pos.index, symbols.getNaN(), 0, symbols.getNaN().length())) { pos.index = pos.index + symbols.getNaN().length(); return new Double(Double.NaN); } boolean[] status = new boolean[STATUS_LENGTH]; if (!subparse(text, pos, positivePrefix, negativePrefix, digitList, false, status)) { return null; } // special case INFINITY if (status[STATUS_INFINITE]) { if (status[STATUS_POSITIVE] == (multiplier >= 0)) { return new Double(Double.POSITIVE_INFINITY); } else { return new Double(Double.NEGATIVE_INFINITY); } } if (multiplier == 0) { if (digitList.isZero()) { return new Double(Double.NaN); } else if (status[STATUS_POSITIVE]) { return new Double(Double.POSITIVE_INFINITY); } else { return new Double(Double.NEGATIVE_INFINITY); } } if (isParseBigDecimal()) { BigDecimal bigDecimalResult = digitList.getBigDecimal(); if (multiplier != 1) { try { bigDecimalResult = bigDecimalResult.divide(getBigDecimalMultiplier()); } catch (ArithmeticException e) { // non-terminating decimal expansion bigDecimalResult = bigDecimalResult.divide(getBigDecimalMultiplier(), roundingMode); } } if (!status[STATUS_POSITIVE]) { bigDecimalResult = bigDecimalResult.negate(); } return bigDecimalResult; } else { boolean gotDouble = true; boolean gotLongMinimum = false; double doubleResult = 0.0; long longResult = 0; // Finally, have DigitList parse the digits into a value. if (digitList.fitsIntoLong(status[STATUS_POSITIVE], isParseIntegerOnly())) { gotDouble = false; longResult = digitList.getLong(); if (longResult < 0) { // got Long.MIN_VALUE gotLongMinimum = true; } } else { doubleResult = digitList.getDouble(); } // Divide by multiplier. We have to be careful here not to do // unneeded conversions between double and long. if (multiplier != 1) { if (gotDouble) { doubleResult /= multiplier; } else { // Avoid converting to double if we can if (longResult % multiplier == 0) { longResult /= multiplier; } else { doubleResult = ((double)longResult) / multiplier; gotDouble = true; } } } if (!status[STATUS_POSITIVE] && !gotLongMinimum) { doubleResult = -doubleResult; longResult = -longResult; } // At this point, if we divided the result by the multiplier, the // result may fit into a long. We check for this case and return // a long if possible. // We must do this AFTER applying the negative (if appropriate) // in order to handle the case of LONG_MIN; otherwise, if we do // this with a positive value -LONG_MIN, the double is > 0, but // the long is < 0. We also must retain a double in the case of // -0.0, which will compare as == to a long 0 cast to a double // (bug 4162852). if (multiplier != 1 && gotDouble) { longResult = (long)doubleResult; gotDouble = ((doubleResult != (double)longResult) || (doubleResult == 0.0 && 1/doubleResult < 0.0)) && !isParseIntegerOnly(); } return gotDouble ? (Number)new Double(doubleResult) : (Number)new Long(longResult); } }
Return a BigInteger multiplier.
/** * Return a BigInteger multiplier. */
private BigInteger getBigIntegerMultiplier() { if (bigIntegerMultiplier == null) { bigIntegerMultiplier = BigInteger.valueOf(multiplier); } return bigIntegerMultiplier; } private transient BigInteger bigIntegerMultiplier;
Return a BigDecimal multiplier.
/** * Return a BigDecimal multiplier. */
private BigDecimal getBigDecimalMultiplier() { if (bigDecimalMultiplier == null) { bigDecimalMultiplier = new BigDecimal(multiplier); } return bigDecimalMultiplier; } private transient BigDecimal bigDecimalMultiplier; private static final int STATUS_INFINITE = 0; private static final int STATUS_POSITIVE = 1; private static final int STATUS_LENGTH = 2;
Parse the given text into a number. The text is parsed beginning at parsePosition, until an unparseable character is seen.
Params:
  • text – The string to parse.
  • parsePosition – The position at which to being parsing. Upon return, the first unparseable character.
  • digits – The DigitList to set to the parsed value.
  • isExponent – If true, parse an exponent. This means no infinite values and integer only.
  • status – Upon return contains boolean status flags indicating whether the value was infinite and whether it was positive.
/** * Parse the given text into a number. The text is parsed beginning at * parsePosition, until an unparseable character is seen. * @param text The string to parse. * @param parsePosition The position at which to being parsing. Upon * return, the first unparseable character. * @param digits The DigitList to set to the parsed value. * @param isExponent If true, parse an exponent. This means no * infinite values and integer only. * @param status Upon return contains boolean status flags indicating * whether the value was infinite and whether it was positive. */
private final boolean subparse(String text, ParsePosition parsePosition, String positivePrefix, String negativePrefix, DigitList digits, boolean isExponent, boolean status[]) { int position = parsePosition.index; int oldStart = parsePosition.index; int backup; boolean gotPositive, gotNegative; // check for positivePrefix; take longest gotPositive = text.regionMatches(position, positivePrefix, 0, positivePrefix.length()); gotNegative = text.regionMatches(position, negativePrefix, 0, negativePrefix.length()); if (gotPositive && gotNegative) { if (positivePrefix.length() > negativePrefix.length()) { gotNegative = false; } else if (positivePrefix.length() < negativePrefix.length()) { gotPositive = false; } } if (gotPositive) { position += positivePrefix.length(); } else if (gotNegative) { position += negativePrefix.length(); } else { parsePosition.errorIndex = position; return false; } // process digits or Inf, find decimal position status[STATUS_INFINITE] = false; if (!isExponent && text.regionMatches(position,symbols.getInfinity(),0, symbols.getInfinity().length())) { position += symbols.getInfinity().length(); status[STATUS_INFINITE] = true; } else { // We now have a string of digits, possibly with grouping symbols, // and decimal points. We want to process these into a DigitList. // We don't want to put a bunch of leading zeros into the DigitList // though, so we keep track of the location of the decimal point, // put only significant digits into the DigitList, and adjust the // exponent as needed. digits.decimalAt = digits.count = 0; char zero = symbols.getZeroDigit(); char decimal = isCurrencyFormat ? symbols.getMonetaryDecimalSeparator() : symbols.getDecimalSeparator(); char grouping = symbols.getGroupingSeparator(); String exponentString = symbols.getExponentSeparator(); boolean sawDecimal = false; boolean sawExponent = false; boolean sawDigit = false; int exponent = 0; // Set to the exponent value, if any // We have to track digitCount ourselves, because digits.count will // pin when the maximum allowable digits is reached. int digitCount = 0; backup = -1; for (; position < text.length(); ++position) { char ch = text.charAt(position); /* We recognize all digit ranges, not only the Latin digit range * '0'..'9'. We do so by using the Character.digit() method, * which converts a valid Unicode digit to the range 0..9. * * The character 'ch' may be a digit. If so, place its value * from 0 to 9 in 'digit'. First try using the locale digit, * which may or MAY NOT be a standard Unicode digit range. If * this fails, try using the standard Unicode digit ranges by * calling Character.digit(). If this also fails, digit will * have a value outside the range 0..9. */ int digit = ch - zero; if (digit < 0 || digit > 9) { digit = Character.digit(ch, 10); } if (digit == 0) { // Cancel out backup setting (see grouping handler below) backup = -1; // Do this BEFORE continue statement below!!! sawDigit = true; // Handle leading zeros if (digits.count == 0) { // Ignore leading zeros in integer part of number. if (!sawDecimal) { continue; } // If we have seen the decimal, but no significant // digits yet, then we account for leading zeros by // decrementing the digits.decimalAt into negative // values. --digits.decimalAt; } else { ++digitCount; digits.append((char)(digit + '0')); } } else if (digit > 0 && digit <= 9) { // [sic] digit==0 handled above sawDigit = true; ++digitCount; digits.append((char)(digit + '0')); // Cancel out backup setting (see grouping handler below) backup = -1; } else if (!isExponent && ch == decimal) { // If we're only parsing integers, or if we ALREADY saw the // decimal, then don't parse this one. if (isParseIntegerOnly() || sawDecimal) { break; } digits.decimalAt = digitCount; // Not digits.count! sawDecimal = true; } else if (!isExponent && ch == grouping && isGroupingUsed()) { if (sawDecimal) { break; } // Ignore grouping characters, if we are using them, but // require that they be followed by a digit. Otherwise // we backup and reprocess them. backup = position; } else if (!isExponent && text.regionMatches(position, exponentString, 0, exponentString.length()) && !sawExponent) { // Process the exponent by recursively calling this method. ParsePosition pos = new ParsePosition(position + exponentString.length()); boolean[] stat = new boolean[STATUS_LENGTH]; DigitList exponentDigits = new DigitList(); if (subparse(text, pos, "", Character.toString(symbols.getMinusSign()), exponentDigits, true, stat) && exponentDigits.fitsIntoLong(stat[STATUS_POSITIVE], true)) { position = pos.index; // Advance past the exponent exponent = (int)exponentDigits.getLong(); if (!stat[STATUS_POSITIVE]) { exponent = -exponent; } sawExponent = true; } break; // Whether we fail or succeed, we exit this loop } else { break; } } if (backup != -1) { position = backup; } // If there was no decimal point we have an integer if (!sawDecimal) { digits.decimalAt = digitCount; // Not digits.count! } // Adjust for exponent, if any digits.decimalAt += exponent; // If none of the text string was recognized. For example, parse // "x" with pattern "#0.00" (return index and error index both 0) // parse "$" with pattern "$#0.00". (return index 0 and error // index 1). if (!sawDigit && digitCount == 0) { parsePosition.index = oldStart; parsePosition.errorIndex = oldStart; return false; } } // check for suffix if (!isExponent) { if (gotPositive) { gotPositive = text.regionMatches(position,positiveSuffix,0, positiveSuffix.length()); } if (gotNegative) { gotNegative = text.regionMatches(position,negativeSuffix,0, negativeSuffix.length()); } // if both match, take longest if (gotPositive && gotNegative) { if (positiveSuffix.length() > negativeSuffix.length()) { gotNegative = false; } else if (positiveSuffix.length() < negativeSuffix.length()) { gotPositive = false; } } // fail if neither or both if (gotPositive == gotNegative) { parsePosition.errorIndex = position; return false; } parsePosition.index = position + (gotPositive ? positiveSuffix.length() : negativeSuffix.length()); // mark success! } else { parsePosition.index = position; } status[STATUS_POSITIVE] = gotPositive; if (parsePosition.index == oldStart) { parsePosition.errorIndex = position; return false; } return true; }
Returns a copy of the decimal format symbols, which is generally not changed by the programmer or user.
See Also:
Returns:a copy of the desired DecimalFormatSymbols
/** * Returns a copy of the decimal format symbols, which is generally not * changed by the programmer or user. * @return a copy of the desired DecimalFormatSymbols * @see java.text.DecimalFormatSymbols */
public DecimalFormatSymbols getDecimalFormatSymbols() { try { // don't allow multiple references return (DecimalFormatSymbols) symbols.clone(); } catch (Exception foo) { return null; // should never happen } }
Sets the decimal format symbols, which is generally not changed by the programmer or user.
Params:
  • newSymbols – desired DecimalFormatSymbols
See Also:
/** * Sets the decimal format symbols, which is generally not changed * by the programmer or user. * @param newSymbols desired DecimalFormatSymbols * @see java.text.DecimalFormatSymbols */
public void setDecimalFormatSymbols(DecimalFormatSymbols newSymbols) { try { // don't allow multiple references symbols = (DecimalFormatSymbols) newSymbols.clone(); expandAffixes(); } catch (Exception foo) { // should never happen } }
Get the positive prefix.

Examples: +123, $123, sFr123

/** * Get the positive prefix. * <P>Examples: +123, $123, sFr123 */
public String getPositivePrefix () { return positivePrefix; }
Set the positive prefix.

Examples: +123, $123, sFr123

/** * Set the positive prefix. * <P>Examples: +123, $123, sFr123 */
public void setPositivePrefix (String newValue) { positivePrefix = newValue; posPrefixPattern = null; positivePrefixFieldPositions = null; }
Returns the FieldPositions of the fields in the prefix used for positive numbers. This is not used if the user has explicitly set a positive prefix via setPositivePrefix. This is lazily created.
Returns:FieldPositions in positive prefix
/** * Returns the FieldPositions of the fields in the prefix used for * positive numbers. This is not used if the user has explicitly set * a positive prefix via <code>setPositivePrefix</code>. This is * lazily created. * * @return FieldPositions in positive prefix */
private FieldPosition[] getPositivePrefixFieldPositions() { if (positivePrefixFieldPositions == null) { if (posPrefixPattern != null) { positivePrefixFieldPositions = expandAffix(posPrefixPattern); } else { positivePrefixFieldPositions = EmptyFieldPositionArray; } } return positivePrefixFieldPositions; }
Get the negative prefix.

Examples: -123, ($123) (with negative suffix), sFr-123

/** * Get the negative prefix. * <P>Examples: -123, ($123) (with negative suffix), sFr-123 */
public String getNegativePrefix () { return negativePrefix; }
Set the negative prefix.

Examples: -123, ($123) (with negative suffix), sFr-123

/** * Set the negative prefix. * <P>Examples: -123, ($123) (with negative suffix), sFr-123 */
public void setNegativePrefix (String newValue) { negativePrefix = newValue; negPrefixPattern = null; }
Returns the FieldPositions of the fields in the prefix used for negative numbers. This is not used if the user has explicitly set a negative prefix via setNegativePrefix. This is lazily created.
Returns:FieldPositions in positive prefix
/** * Returns the FieldPositions of the fields in the prefix used for * negative numbers. This is not used if the user has explicitly set * a negative prefix via <code>setNegativePrefix</code>. This is * lazily created. * * @return FieldPositions in positive prefix */
private FieldPosition[] getNegativePrefixFieldPositions() { if (negativePrefixFieldPositions == null) { if (negPrefixPattern != null) { negativePrefixFieldPositions = expandAffix(negPrefixPattern); } else { negativePrefixFieldPositions = EmptyFieldPositionArray; } } return negativePrefixFieldPositions; }
Get the positive suffix.

Example: 123%

/** * Get the positive suffix. * <P>Example: 123% */
public String getPositiveSuffix () { return positiveSuffix; }
Set the positive suffix.

Example: 123%

/** * Set the positive suffix. * <P>Example: 123% */
public void setPositiveSuffix (String newValue) { positiveSuffix = newValue; posSuffixPattern = null; }
Returns the FieldPositions of the fields in the suffix used for positive numbers. This is not used if the user has explicitly set a positive suffix via setPositiveSuffix. This is lazily created.
Returns:FieldPositions in positive prefix
/** * Returns the FieldPositions of the fields in the suffix used for * positive numbers. This is not used if the user has explicitly set * a positive suffix via <code>setPositiveSuffix</code>. This is * lazily created. * * @return FieldPositions in positive prefix */
private FieldPosition[] getPositiveSuffixFieldPositions() { if (positiveSuffixFieldPositions == null) { if (posSuffixPattern != null) { positiveSuffixFieldPositions = expandAffix(posSuffixPattern); } else { positiveSuffixFieldPositions = EmptyFieldPositionArray; } } return positiveSuffixFieldPositions; }
Get the negative suffix.

Examples: -123%, ($123) (with positive suffixes)

/** * Get the negative suffix. * <P>Examples: -123%, ($123) (with positive suffixes) */
public String getNegativeSuffix () { return negativeSuffix; }
Set the negative suffix.

Examples: 123%

/** * Set the negative suffix. * <P>Examples: 123% */
public void setNegativeSuffix (String newValue) { negativeSuffix = newValue; negSuffixPattern = null; }
Returns the FieldPositions of the fields in the suffix used for negative numbers. This is not used if the user has explicitly set a negative suffix via setNegativeSuffix. This is lazily created.
Returns:FieldPositions in positive prefix
/** * Returns the FieldPositions of the fields in the suffix used for * negative numbers. This is not used if the user has explicitly set * a negative suffix via <code>setNegativeSuffix</code>. This is * lazily created. * * @return FieldPositions in positive prefix */
private FieldPosition[] getNegativeSuffixFieldPositions() { if (negativeSuffixFieldPositions == null) { if (negSuffixPattern != null) { negativeSuffixFieldPositions = expandAffix(negSuffixPattern); } else { negativeSuffixFieldPositions = EmptyFieldPositionArray; } } return negativeSuffixFieldPositions; }
Gets the multiplier for use in percent, per mille, and similar formats.
See Also:
  • setMultiplier(int)
/** * Gets the multiplier for use in percent, per mille, and similar * formats. * * @see #setMultiplier(int) */
public int getMultiplier () { return multiplier; }
Sets the multiplier for use in percent, per mille, and similar formats. For a percent format, set the multiplier to 100 and the suffixes to have '%' (for Arabic, use the Arabic percent sign). For a per mille format, set the multiplier to 1000 and the suffixes to have '\u2030'.

Example: with multiplier 100, 1.23 is formatted as "123", and "123" is parsed into 1.23.

See Also:
  • getMultiplier
/** * Sets the multiplier for use in percent, per mille, and similar * formats. * For a percent format, set the multiplier to 100 and the suffixes to * have '%' (for Arabic, use the Arabic percent sign). * For a per mille format, set the multiplier to 1000 and the suffixes to * have '&#92;u2030'. * * <P>Example: with multiplier 100, 1.23 is formatted as "123", and * "123" is parsed into 1.23. * * @see #getMultiplier */
public void setMultiplier (int newValue) { multiplier = newValue; bigDecimalMultiplier = null; bigIntegerMultiplier = null; }
Return the grouping size. Grouping size is the number of digits between grouping separators in the integer portion of a number. For example, in the number "123,456.78", the grouping size is 3.
See Also:
/** * Return the grouping size. Grouping size is the number of digits between * grouping separators in the integer portion of a number. For example, * in the number "123,456.78", the grouping size is 3. * @see #setGroupingSize * @see java.text.NumberFormat#isGroupingUsed * @see java.text.DecimalFormatSymbols#getGroupingSeparator */
public int getGroupingSize () { return groupingSize; }
Set the grouping size. Grouping size is the number of digits between grouping separators in the integer portion of a number. For example, in the number "123,456.78", the grouping size is 3.
The value passed in is converted to a byte, which may lose information.
See Also:
/** * Set the grouping size. Grouping size is the number of digits between * grouping separators in the integer portion of a number. For example, * in the number "123,456.78", the grouping size is 3. * <br> * The value passed in is converted to a byte, which may lose information. * @see #getGroupingSize * @see java.text.NumberFormat#setGroupingUsed * @see java.text.DecimalFormatSymbols#setGroupingSeparator */
public void setGroupingSize (int newValue) { groupingSize = (byte)newValue; }
Allows you to get the behavior of the decimal separator with integers. (The decimal separator will always appear with decimals.)

Example: Decimal ON: 12345 -> 12345.; OFF: 12345 -> 12345

/** * Allows you to get the behavior of the decimal separator with integers. * (The decimal separator will always appear with decimals.) * <P>Example: Decimal ON: 12345 -> 12345.; OFF: 12345 -> 12345 */
public boolean isDecimalSeparatorAlwaysShown() { return decimalSeparatorAlwaysShown; }
Allows you to set the behavior of the decimal separator with integers. (The decimal separator will always appear with decimals.)

Example: Decimal ON: 12345 -> 12345.; OFF: 12345 -> 12345

/** * Allows you to set the behavior of the decimal separator with integers. * (The decimal separator will always appear with decimals.) * <P>Example: Decimal ON: 12345 -> 12345.; OFF: 12345 -> 12345 */
public void setDecimalSeparatorAlwaysShown(boolean newValue) { decimalSeparatorAlwaysShown = newValue; }
Returns whether the parse(String, ParsePosition) method returns BigDecimal. The default value is false.
See Also:
Since:1.5
/** * Returns whether the {@link #parse(java.lang.String, java.text.ParsePosition)} * method returns <code>BigDecimal</code>. The default value is false. * @see #setParseBigDecimal * @since 1.5 */
public boolean isParseBigDecimal() { return parseBigDecimal; }
Sets whether the parse(String, ParsePosition) method returns BigDecimal.
See Also:
Since:1.5
/** * Sets whether the {@link #parse(java.lang.String, java.text.ParsePosition)} * method returns <code>BigDecimal</code>. * @see #isParseBigDecimal * @since 1.5 */
public void setParseBigDecimal(boolean newValue) { parseBigDecimal = newValue; }
Standard override; no change in semantics.
/** * Standard override; no change in semantics. */
public Object clone() { try { DecimalFormat other = (DecimalFormat) super.clone(); other.symbols = (DecimalFormatSymbols) symbols.clone(); other.digitList = (DigitList) digitList.clone(); return other; } catch (Exception e) { throw new InternalError(); } }
Overrides equals
/** * Overrides equals */
public boolean equals(Object obj) { if (obj == null) return false; if (!super.equals(obj)) return false; // super does class check DecimalFormat other = (DecimalFormat) obj; return ((posPrefixPattern == other.posPrefixPattern && positivePrefix.equals(other.positivePrefix)) || (posPrefixPattern != null && posPrefixPattern.equals(other.posPrefixPattern))) && ((posSuffixPattern == other.posSuffixPattern && positiveSuffix.equals(other.positiveSuffix)) || (posSuffixPattern != null && posSuffixPattern.equals(other.posSuffixPattern))) && ((negPrefixPattern == other.negPrefixPattern && negativePrefix.equals(other.negativePrefix)) || (negPrefixPattern != null && negPrefixPattern.equals(other.negPrefixPattern))) && ((negSuffixPattern == other.negSuffixPattern && negativeSuffix.equals(other.negativeSuffix)) || (negSuffixPattern != null && negSuffixPattern.equals(other.negSuffixPattern))) && multiplier == other.multiplier && groupingSize == other.groupingSize && decimalSeparatorAlwaysShown == other.decimalSeparatorAlwaysShown && parseBigDecimal == other.parseBigDecimal && useExponentialNotation == other.useExponentialNotation && (!useExponentialNotation || minExponentDigits == other.minExponentDigits) && maximumIntegerDigits == other.maximumIntegerDigits && minimumIntegerDigits == other.minimumIntegerDigits && maximumFractionDigits == other.maximumFractionDigits && minimumFractionDigits == other.minimumFractionDigits && roundingMode == other.roundingMode && symbols.equals(other.symbols); }
Overrides hashCode
/** * Overrides hashCode */
public int hashCode() { return super.hashCode() * 37 + positivePrefix.hashCode(); // just enough fields for a reasonable distribution }
Synthesizes a pattern string that represents the current state of this Format object.
See Also:
  • applyPattern
/** * Synthesizes a pattern string that represents the current state * of this Format object. * @see #applyPattern */
public String toPattern() { return toPattern( false ); }
Synthesizes a localized pattern string that represents the current state of this Format object.
See Also:
  • applyPattern
/** * Synthesizes a localized pattern string that represents the current * state of this Format object. * @see #applyPattern */
public String toLocalizedPattern() { return toPattern( true ); }
Expand the affix pattern strings into the expanded affix strings. If any affix pattern string is null, do not expand it. This method should be called any time the symbols or the affix patterns change in order to keep the expanded affix strings up to date.
/** * Expand the affix pattern strings into the expanded affix strings. If any * affix pattern string is null, do not expand it. This method should be * called any time the symbols or the affix patterns change in order to keep * the expanded affix strings up to date. */
private void expandAffixes() { // Reuse one StringBuffer for better performance StringBuffer buffer = new StringBuffer(); if (posPrefixPattern != null) { positivePrefix = expandAffix(posPrefixPattern, buffer); positivePrefixFieldPositions = null; } if (posSuffixPattern != null) { positiveSuffix = expandAffix(posSuffixPattern, buffer); positiveSuffixFieldPositions = null; } if (negPrefixPattern != null) { negativePrefix = expandAffix(negPrefixPattern, buffer); negativePrefixFieldPositions = null; } if (negSuffixPattern != null) { negativeSuffix = expandAffix(negSuffixPattern, buffer); negativeSuffixFieldPositions = null; } }
Expand an affix pattern into an affix string. All characters in the pattern are literal unless prefixed by QUOTE. The following characters after QUOTE are recognized: PATTERN_PERCENT, PATTERN_PER_MILLE, PATTERN_MINUS, and CURRENCY_SIGN. If CURRENCY_SIGN is doubled (QUOTE + CURRENCY_SIGN + CURRENCY_SIGN), it is interpreted as an ISO 4217 currency code. Any other character after a QUOTE represents itself. QUOTE must be followed by another character; QUOTE may not occur by itself at the end of the pattern.
Params:
  • pattern – the non-null, possibly empty pattern
  • buffer – a scratch StringBuffer; its contents will be lost
Returns:the expanded equivalent of pattern
/** * Expand an affix pattern into an affix string. All characters in the * pattern are literal unless prefixed by QUOTE. The following characters * after QUOTE are recognized: PATTERN_PERCENT, PATTERN_PER_MILLE, * PATTERN_MINUS, and CURRENCY_SIGN. If CURRENCY_SIGN is doubled (QUOTE + * CURRENCY_SIGN + CURRENCY_SIGN), it is interpreted as an ISO 4217 * currency code. Any other character after a QUOTE represents itself. * QUOTE must be followed by another character; QUOTE may not occur by * itself at the end of the pattern. * * @param pattern the non-null, possibly empty pattern * @param buffer a scratch StringBuffer; its contents will be lost * @return the expanded equivalent of pattern */
private String expandAffix(String pattern, StringBuffer buffer) { buffer.setLength(0); for (int i=0; i<pattern.length(); ) { char c = pattern.charAt(i++); if (c == QUOTE) { c = pattern.charAt(i++); switch (c) { case CURRENCY_SIGN: if (i<pattern.length() && pattern.charAt(i) == CURRENCY_SIGN) { ++i; buffer.append(symbols.getInternationalCurrencySymbol()); } else { buffer.append(symbols.getCurrencySymbol()); } continue; case PATTERN_PERCENT: c = symbols.getPercent(); break; case PATTERN_PER_MILLE: c = symbols.getPerMill(); break; case PATTERN_MINUS: c = symbols.getMinusSign(); break; } } buffer.append(c); } return buffer.toString(); }
Expand an affix pattern into an array of FieldPositions describing how the pattern would be expanded. All characters in the pattern are literal unless prefixed by QUOTE. The following characters after QUOTE are recognized: PATTERN_PERCENT, PATTERN_PER_MILLE, PATTERN_MINUS, and CURRENCY_SIGN. If CURRENCY_SIGN is doubled (QUOTE + CURRENCY_SIGN + CURRENCY_SIGN), it is interpreted as an ISO 4217 currency code. Any other character after a QUOTE represents itself. QUOTE must be followed by another character; QUOTE may not occur by itself at the end of the pattern.
Params:
  • pattern – the non-null, possibly empty pattern
Returns:FieldPosition array of the resulting fields.
/** * Expand an affix pattern into an array of FieldPositions describing * how the pattern would be expanded. * All characters in the * pattern are literal unless prefixed by QUOTE. The following characters * after QUOTE are recognized: PATTERN_PERCENT, PATTERN_PER_MILLE, * PATTERN_MINUS, and CURRENCY_SIGN. If CURRENCY_SIGN is doubled (QUOTE + * CURRENCY_SIGN + CURRENCY_SIGN), it is interpreted as an ISO 4217 * currency code. Any other character after a QUOTE represents itself. * QUOTE must be followed by another character; QUOTE may not occur by * itself at the end of the pattern. * * @param pattern the non-null, possibly empty pattern * @return FieldPosition array of the resulting fields. */
private FieldPosition[] expandAffix(String pattern) { ArrayList positions = null; int stringIndex = 0; for (int i=0; i<pattern.length(); ) { char c = pattern.charAt(i++); if (c == QUOTE) { int field = -1; Format.Field fieldID = null; c = pattern.charAt(i++); switch (c) { case CURRENCY_SIGN: String string; if (i<pattern.length() && pattern.charAt(i) == CURRENCY_SIGN) { ++i; string = symbols.getInternationalCurrencySymbol(); } else { string = symbols.getCurrencySymbol(); } if (string.length() > 0) { if (positions == null) { positions = new ArrayList(2); } FieldPosition fp = new FieldPosition(Field.CURRENCY); fp.setBeginIndex(stringIndex); fp.setEndIndex(stringIndex + string.length()); positions.add(fp); stringIndex += string.length(); } continue; case PATTERN_PERCENT: c = symbols.getPercent(); field = -1; fieldID = Field.PERCENT; break; case PATTERN_PER_MILLE: c = symbols.getPerMill(); field = -1; fieldID = Field.PERMILLE; break; case PATTERN_MINUS: c = symbols.getMinusSign(); field = -1; fieldID = Field.SIGN; break; } if (fieldID != null) { if (positions == null) { positions = new ArrayList(2); } FieldPosition fp = new FieldPosition(fieldID, field); fp.setBeginIndex(stringIndex); fp.setEndIndex(stringIndex + 1); positions.add(fp); } } stringIndex++; } if (positions != null) { return (FieldPosition[])positions.toArray(EmptyFieldPositionArray); } return EmptyFieldPositionArray; }
Appends an affix pattern to the given StringBuffer, quoting special characters as needed. Uses the internal affix pattern, if that exists, or the literal affix, if the internal affix pattern is null. The appended string will generate the same affix pattern (or literal affix) when passed to toPattern().
Params:
  • buffer – the affix string is appended to this
  • affixPattern – a pattern such as posPrefixPattern; may be null
  • expAffix – a corresponding expanded affix, such as positivePrefix. Ignored unless affixPattern is null. If affixPattern is null, then expAffix is appended as a literal affix.
  • localized – true if the appended pattern should contain localized pattern characters; otherwise, non-localized pattern chars are appended
/** * Appends an affix pattern to the given StringBuffer, quoting special * characters as needed. Uses the internal affix pattern, if that exists, * or the literal affix, if the internal affix pattern is null. The * appended string will generate the same affix pattern (or literal affix) * when passed to toPattern(). * * @param buffer the affix string is appended to this * @param affixPattern a pattern such as posPrefixPattern; may be null * @param expAffix a corresponding expanded affix, such as positivePrefix. * Ignored unless affixPattern is null. If affixPattern is null, then * expAffix is appended as a literal affix. * @param localized true if the appended pattern should contain localized * pattern characters; otherwise, non-localized pattern chars are appended */
private void appendAffix(StringBuffer buffer, String affixPattern, String expAffix, boolean localized) { if (affixPattern == null) { appendAffix(buffer, expAffix, localized); } else { int i; for (int pos=0; pos<affixPattern.length(); pos=i) { i = affixPattern.indexOf(QUOTE, pos); if (i < 0) { appendAffix(buffer, affixPattern.substring(pos), localized); break; } if (i > pos) { appendAffix(buffer, affixPattern.substring(pos, i), localized); } char c = affixPattern.charAt(++i); ++i; if (c == QUOTE) { buffer.append(c); // Fall through and append another QUOTE below } else if (c == CURRENCY_SIGN && i<affixPattern.length() && affixPattern.charAt(i) == CURRENCY_SIGN) { ++i; buffer.append(c); // Fall through and append another CURRENCY_SIGN below } else if (localized) { switch (c) { case PATTERN_PERCENT: c = symbols.getPercent(); break; case PATTERN_PER_MILLE: c = symbols.getPerMill(); break; case PATTERN_MINUS: c = symbols.getMinusSign(); break; } } buffer.append(c); } } }
Append an affix to the given StringBuffer, using quotes if there are special characters. Single quotes themselves must be escaped in either case.
/** * Append an affix to the given StringBuffer, using quotes if * there are special characters. Single quotes themselves must be * escaped in either case. */
private void appendAffix(StringBuffer buffer, String affix, boolean localized) { boolean needQuote; if (localized) { needQuote = affix.indexOf(symbols.getZeroDigit()) >= 0 || affix.indexOf(symbols.getGroupingSeparator()) >= 0 || affix.indexOf(symbols.getDecimalSeparator()) >= 0 || affix.indexOf(symbols.getPercent()) >= 0 || affix.indexOf(symbols.getPerMill()) >= 0 || affix.indexOf(symbols.getDigit()) >= 0 || affix.indexOf(symbols.getPatternSeparator()) >= 0 || affix.indexOf(symbols.getMinusSign()) >= 0 || affix.indexOf(CURRENCY_SIGN) >= 0; } else { needQuote = affix.indexOf(PATTERN_ZERO_DIGIT) >= 0 || affix.indexOf(PATTERN_GROUPING_SEPARATOR) >= 0 || affix.indexOf(PATTERN_DECIMAL_SEPARATOR) >= 0 || affix.indexOf(PATTERN_PERCENT) >= 0 || affix.indexOf(PATTERN_PER_MILLE) >= 0 || affix.indexOf(PATTERN_DIGIT) >= 0 || affix.indexOf(PATTERN_SEPARATOR) >= 0 || affix.indexOf(PATTERN_MINUS) >= 0 || affix.indexOf(CURRENCY_SIGN) >= 0; } if (needQuote) buffer.append('\''); if (affix.indexOf('\'') < 0) buffer.append(affix); else { for (int j=0; j<affix.length(); ++j) { char c = affix.charAt(j); buffer.append(c); if (c == '\'') buffer.append(c); } } if (needQuote) buffer.append('\''); }
Does the real work of generating a pattern.
/** * Does the real work of generating a pattern. */
private String toPattern(boolean localized) { StringBuffer result = new StringBuffer(); for (int j = 1; j >= 0; --j) { if (j == 1) appendAffix(result, posPrefixPattern, positivePrefix, localized); else appendAffix(result, negPrefixPattern, negativePrefix, localized); int i; int digitCount = useExponentialNotation ? getMaximumIntegerDigits() : Math.max(groupingSize, getMinimumIntegerDigits())+1; for (i = digitCount; i > 0; --i) { if (i != digitCount && isGroupingUsed() && groupingSize != 0 && i % groupingSize == 0) { result.append(localized ? symbols.getGroupingSeparator() : PATTERN_GROUPING_SEPARATOR); } result.append(i <= getMinimumIntegerDigits() ? (localized ? symbols.getZeroDigit() : PATTERN_ZERO_DIGIT) : (localized ? symbols.getDigit() : PATTERN_DIGIT)); } if (getMaximumFractionDigits() > 0 || decimalSeparatorAlwaysShown) result.append(localized ? symbols.getDecimalSeparator() : PATTERN_DECIMAL_SEPARATOR); for (i = 0; i < getMaximumFractionDigits(); ++i) { if (i < getMinimumFractionDigits()) { result.append(localized ? symbols.getZeroDigit() : PATTERN_ZERO_DIGIT); } else { result.append(localized ? symbols.getDigit() : PATTERN_DIGIT); } } if (useExponentialNotation) { result.append(localized ? symbols.getExponentSeparator() : PATTERN_EXPONENT); for (i=0; i<minExponentDigits; ++i) result.append(localized ? symbols.getZeroDigit() : PATTERN_ZERO_DIGIT); } if (j == 1) { appendAffix(result, posSuffixPattern, positiveSuffix, localized); if ((negSuffixPattern == posSuffixPattern && // n == p == null negativeSuffix.equals(positiveSuffix)) || (negSuffixPattern != null && negSuffixPattern.equals(posSuffixPattern))) { if ((negPrefixPattern != null && posPrefixPattern != null && negPrefixPattern.equals("'-" + posPrefixPattern)) || (negPrefixPattern == posPrefixPattern && // n == p == null negativePrefix.equals(symbols.getMinusSign() + positivePrefix))) break; } result.append(localized ? symbols.getPatternSeparator() : PATTERN_SEPARATOR); } else appendAffix(result, negSuffixPattern, negativeSuffix, localized); } return result.toString(); }
Apply the given pattern to this Format object. A pattern is a short-hand specification for the various formatting properties. These properties can also be changed individually through the various setter methods.

There is no limit to integer digits set by this routine, since that is the typical end-user desire; use setMaximumInteger if you want to set a real value. For negative numbers, use a second pattern, separated by a semicolon

Example "#,#00.0#" -> 1,234.56

This means a minimum of 2 integer digits, 1 fraction digit, and a maximum of 2 fraction digits.

Example: "#,#00.0#;(#,#00.0#)" for negatives in parentheses.

In negative patterns, the minimum and maximum counts are ignored; these are presumed to be set in the positive pattern.

Throws:
/** * Apply the given pattern to this Format object. A pattern is a * short-hand specification for the various formatting properties. * These properties can also be changed individually through the * various setter methods. * <p> * There is no limit to integer digits set * by this routine, since that is the typical end-user desire; * use setMaximumInteger if you want to set a real value. * For negative numbers, use a second pattern, separated by a semicolon * <P>Example <code>"#,#00.0#"</code> -> 1,234.56 * <P>This means a minimum of 2 integer digits, 1 fraction digit, and * a maximum of 2 fraction digits. * <p>Example: <code>"#,#00.0#;(#,#00.0#)"</code> for negatives in * parentheses. * <p>In negative patterns, the minimum and maximum counts are ignored; * these are presumed to be set in the positive pattern. * * @exception NullPointerException if <code>pattern</code> is null * @exception IllegalArgumentException if the given pattern is invalid. */
public void applyPattern(String pattern) { applyPattern(pattern, false); }
Apply the given pattern to this Format object. The pattern is assumed to be in a localized notation. A pattern is a short-hand specification for the various formatting properties. These properties can also be changed individually through the various setter methods.

There is no limit to integer digits set by this routine, since that is the typical end-user desire; use setMaximumInteger if you want to set a real value. For negative numbers, use a second pattern, separated by a semicolon

Example "#,#00.0#" -> 1,234.56

This means a minimum of 2 integer digits, 1 fraction digit, and a maximum of 2 fraction digits.

Example: "#,#00.0#;(#,#00.0#)" for negatives in parentheses.

In negative patterns, the minimum and maximum counts are ignored; these are presumed to be set in the positive pattern.

Throws:
/** * Apply the given pattern to this Format object. The pattern * is assumed to be in a localized notation. A pattern is a * short-hand specification for the various formatting properties. * These properties can also be changed individually through the * various setter methods. * <p> * There is no limit to integer digits set * by this routine, since that is the typical end-user desire; * use setMaximumInteger if you want to set a real value. * For negative numbers, use a second pattern, separated by a semicolon * <P>Example <code>"#,#00.0#"</code> -> 1,234.56 * <P>This means a minimum of 2 integer digits, 1 fraction digit, and * a maximum of 2 fraction digits. * <p>Example: <code>"#,#00.0#;(#,#00.0#)"</code> for negatives in * parentheses. * <p>In negative patterns, the minimum and maximum counts are ignored; * these are presumed to be set in the positive pattern. * * @exception NullPointerException if <code>pattern</code> is null * @exception IllegalArgumentException if the given pattern is invalid. */
public void applyLocalizedPattern(String pattern) { applyPattern(pattern, true); }
Does the real work of applying a pattern.
/** * Does the real work of applying a pattern. */
private void applyPattern(String pattern, boolean localized) { char zeroDigit = PATTERN_ZERO_DIGIT; char groupingSeparator = PATTERN_GROUPING_SEPARATOR; char decimalSeparator = PATTERN_DECIMAL_SEPARATOR; char percent = PATTERN_PERCENT; char perMill = PATTERN_PER_MILLE; char digit = PATTERN_DIGIT; char separator = PATTERN_SEPARATOR; String exponent = PATTERN_EXPONENT; char minus = PATTERN_MINUS; if (localized) { zeroDigit = symbols.getZeroDigit(); groupingSeparator = symbols.getGroupingSeparator(); decimalSeparator = symbols.getDecimalSeparator(); percent = symbols.getPercent(); perMill = symbols.getPerMill(); digit = symbols.getDigit(); separator = symbols.getPatternSeparator(); exponent = symbols.getExponentSeparator(); minus = symbols.getMinusSign(); } boolean gotNegative = false; decimalSeparatorAlwaysShown = false; isCurrencyFormat = false; useExponentialNotation = false; // Two variables are used to record the subrange of the pattern // occupied by phase 1. This is used during the processing of the // second pattern (the one representing negative numbers) to ensure // that no deviation exists in phase 1 between the two patterns. int phaseOneStart = 0; int phaseOneLength = 0; int start = 0; for (int j = 1; j >= 0 && start < pattern.length(); --j) { boolean inQuote = false; StringBuffer prefix = new StringBuffer(); StringBuffer suffix = new StringBuffer(); int decimalPos = -1; int multiplier = 1; int digitLeftCount = 0, zeroDigitCount = 0, digitRightCount = 0; byte groupingCount = -1; // The phase ranges from 0 to 2. Phase 0 is the prefix. Phase 1 is // the section of the pattern with digits, decimal separator, // grouping characters. Phase 2 is the suffix. In phases 0 and 2, // percent, per mille, and currency symbols are recognized and // translated. The separation of the characters into phases is // strictly enforced; if phase 1 characters are to appear in the // suffix, for example, they must be quoted. int phase = 0; // The affix is either the prefix or the suffix. StringBuffer affix = prefix; for (int pos = start; pos < pattern.length(); ++pos) { char ch = pattern.charAt(pos); switch (phase) { case 0: case 2: // Process the prefix / suffix characters if (inQuote) { // A quote within quotes indicates either the closing // quote or two quotes, which is a quote literal. That // is, we have the second quote in 'do' or 'don''t'. if (ch == QUOTE) { if ((pos+1) < pattern.length() && pattern.charAt(pos+1) == QUOTE) { ++pos; affix.append("''"); // 'don''t' } else { inQuote = false; // 'do' } continue; } } else { // Process unquoted characters seen in prefix or suffix // phase. if (ch == digit || ch == zeroDigit || ch == groupingSeparator || ch == decimalSeparator) { phase = 1; if (j == 1) { phaseOneStart = pos; } --pos; // Reprocess this character continue; } else if (ch == CURRENCY_SIGN) { // Use lookahead to determine if the currency sign // is doubled or not. boolean doubled = (pos + 1) < pattern.length() && pattern.charAt(pos + 1) == CURRENCY_SIGN; if (doubled) { // Skip over the doubled character ++pos; } isCurrencyFormat = true; affix.append(doubled ? "'\u00A4\u00A4" : "'\u00A4"); continue; } else if (ch == QUOTE) { // A quote outside quotes indicates either the // opening quote or two quotes, which is a quote // literal. That is, we have the first quote in 'do' // or o''clock. if (ch == QUOTE) { if ((pos+1) < pattern.length() && pattern.charAt(pos+1) == QUOTE) { ++pos; affix.append("''"); // o''clock } else { inQuote = true; // 'do' } continue; } } else if (ch == separator) { // Don't allow separators before we see digit // characters of phase 1, and don't allow separators // in the second pattern (j == 0). if (phase == 0 || j == 0) { throw new IllegalArgumentException("Unquoted special character '" + ch + "' in pattern \"" + pattern + '"'); } start = pos + 1; pos = pattern.length(); continue; } // Next handle characters which are appended directly. else if (ch == percent) { if (multiplier != 1) { throw new IllegalArgumentException("Too many percent/per mille characters in pattern \"" + pattern + '"'); } multiplier = 100; affix.append("'%"); continue; } else if (ch == perMill) { if (multiplier != 1) { throw new IllegalArgumentException("Too many percent/per mille characters in pattern \"" + pattern + '"'); } multiplier = 1000; affix.append("'\u2030"); continue; } else if (ch == minus) { affix.append("'-"); continue; } } // Note that if we are within quotes, or if this is an // unquoted, non-special character, then we usually fall // through to here. affix.append(ch); break; case 1: // Phase one must be identical in the two sub-patterns. We // enforce this by doing a direct comparison. While // processing the first sub-pattern, we just record its // length. While processing the second, we compare // characters. if (j == 1) { ++phaseOneLength; } else { if (--phaseOneLength == 0) { phase = 2; affix = suffix; } continue; } // Process the digits, decimal, and grouping characters. We // record five pieces of information. We expect the digits // to occur in the pattern ####0000.####, and we record the // number of left digits, zero (central) digits, and right // digits. The position of the last grouping character is // recorded (should be somewhere within the first two blocks // of characters), as is the position of the decimal point, // if any (should be in the zero digits). If there is no // decimal point, then there should be no right digits. if (ch == digit) { if (zeroDigitCount > 0) { ++digitRightCount; } else { ++digitLeftCount; } if (groupingCount >= 0 && decimalPos < 0) { ++groupingCount; } } else if (ch == zeroDigit) { if (digitRightCount > 0) { throw new IllegalArgumentException("Unexpected '0' in pattern \"" + pattern + '"'); } ++zeroDigitCount; if (groupingCount >= 0 && decimalPos < 0) { ++groupingCount; } } else if (ch == groupingSeparator) { groupingCount = 0; } else if (ch == decimalSeparator) { if (decimalPos >= 0) { throw new IllegalArgumentException("Multiple decimal separators in pattern \"" + pattern + '"'); } decimalPos = digitLeftCount + zeroDigitCount + digitRightCount; } else if (pattern.regionMatches(pos, exponent, 0, exponent.length())){ if (useExponentialNotation) { throw new IllegalArgumentException("Multiple exponential " + "symbols in pattern \"" + pattern + '"'); } useExponentialNotation = true; minExponentDigits = 0; // Use lookahead to parse out the exponential part // of the pattern, then jump into phase 2. pos = pos+exponent.length(); while (pos < pattern.length() && pattern.charAt(pos) == zeroDigit) { ++minExponentDigits; ++phaseOneLength; ++pos; } if ((digitLeftCount + zeroDigitCount) < 1 || minExponentDigits < 1) { throw new IllegalArgumentException("Malformed exponential " + "pattern \"" + pattern + '"'); } // Transition to phase 2 phase = 2; affix = suffix; --pos; continue; } else { phase = 2; affix = suffix; --pos; --phaseOneLength; continue; } break; } } // Handle patterns with no '0' pattern character. These patterns // are legal, but must be interpreted. "##.###" -> "#0.###". // ".###" -> ".0##". /* We allow patterns of the form "####" to produce a zeroDigitCount * of zero (got that?); although this seems like it might make it * possible for format() to produce empty strings, format() checks * for this condition and outputs a zero digit in this situation. * Having a zeroDigitCount of zero yields a minimum integer digits * of zero, which allows proper round-trip patterns. That is, we * don't want "#" to become "#0" when toPattern() is called (even * though that's what it really is, semantically). */ if (zeroDigitCount == 0 && digitLeftCount > 0 && decimalPos >= 0) { // Handle "###.###" and "###." and ".###" int n = decimalPos; if (n == 0) { // Handle ".###" ++n; } digitRightCount = digitLeftCount - n; digitLeftCount = n - 1; zeroDigitCount = 1; } // Do syntax checking on the digits. if ((decimalPos < 0 && digitRightCount > 0) || (decimalPos >= 0 && (decimalPos < digitLeftCount || decimalPos > (digitLeftCount + zeroDigitCount))) || groupingCount == 0 || inQuote) { throw new IllegalArgumentException("Malformed pattern \"" + pattern + '"'); } if (j == 1) { posPrefixPattern = prefix.toString(); posSuffixPattern = suffix.toString(); negPrefixPattern = posPrefixPattern; // assume these for now negSuffixPattern = posSuffixPattern; int digitTotalCount = digitLeftCount + zeroDigitCount + digitRightCount; /* The effectiveDecimalPos is the position the decimal is at or * would be at if there is no decimal. Note that if decimalPos<0, * then digitTotalCount == digitLeftCount + zeroDigitCount. */ int effectiveDecimalPos = decimalPos >= 0 ? decimalPos : digitTotalCount; setMinimumIntegerDigits(effectiveDecimalPos - digitLeftCount); setMaximumIntegerDigits(useExponentialNotation ? digitLeftCount + getMinimumIntegerDigits() : MAXIMUM_INTEGER_DIGITS); setMaximumFractionDigits(decimalPos >= 0 ? (digitTotalCount - decimalPos) : 0); setMinimumFractionDigits(decimalPos >= 0 ? (digitLeftCount + zeroDigitCount - decimalPos) : 0); setGroupingUsed(groupingCount > 0); this.groupingSize = (groupingCount > 0) ? groupingCount : 0; this.multiplier = multiplier; setDecimalSeparatorAlwaysShown(decimalPos == 0 || decimalPos == digitTotalCount); } else { negPrefixPattern = prefix.toString(); negSuffixPattern = suffix.toString(); gotNegative = true; } } if (pattern.length() == 0) { posPrefixPattern = posSuffixPattern = ""; setMinimumIntegerDigits(0); setMaximumIntegerDigits(MAXIMUM_INTEGER_DIGITS); setMinimumFractionDigits(0); setMaximumFractionDigits(MAXIMUM_FRACTION_DIGITS); } // If there was no negative pattern, or if the negative pattern is // identical to the positive pattern, then prepend the minus sign to // the positive pattern to form the negative pattern. if (!gotNegative || (negPrefixPattern.equals(posPrefixPattern) && negSuffixPattern.equals(posSuffixPattern))) { negSuffixPattern = posSuffixPattern; negPrefixPattern = "'-" + posPrefixPattern; } expandAffixes(); }
Sets the maximum number of digits allowed in the integer portion of a number. For formatting numbers other than BigInteger and BigDecimal objects, the lower of newValue and 309 is used. Negative input values are replaced with 0.
See Also:
  • setMaximumIntegerDigits.setMaximumIntegerDigits
/** * Sets the maximum number of digits allowed in the integer portion of a * number. * For formatting numbers other than <code>BigInteger</code> and * <code>BigDecimal</code> objects, the lower of <code>newValue</code> and * 309 is used. Negative input values are replaced with 0. * @see NumberFormat#setMaximumIntegerDigits */
public void setMaximumIntegerDigits(int newValue) { maximumIntegerDigits = Math.min(Math.max(0, newValue), MAXIMUM_INTEGER_DIGITS); super.setMaximumIntegerDigits((maximumIntegerDigits > DOUBLE_INTEGER_DIGITS) ? DOUBLE_INTEGER_DIGITS : maximumIntegerDigits); if (minimumIntegerDigits > maximumIntegerDigits) { minimumIntegerDigits = maximumIntegerDigits; super.setMinimumIntegerDigits((minimumIntegerDigits > DOUBLE_INTEGER_DIGITS) ? DOUBLE_INTEGER_DIGITS : minimumIntegerDigits); } }
Sets the minimum number of digits allowed in the integer portion of a number. For formatting numbers other than BigInteger and BigDecimal objects, the lower of newValue and 309 is used. Negative input values are replaced with 0.
See Also:
  • setMinimumIntegerDigits.setMinimumIntegerDigits
/** * Sets the minimum number of digits allowed in the integer portion of a * number. * For formatting numbers other than <code>BigInteger</code> and * <code>BigDecimal</code> objects, the lower of <code>newValue</code> and * 309 is used. Negative input values are replaced with 0. * @see NumberFormat#setMinimumIntegerDigits */
public void setMinimumIntegerDigits(int newValue) { minimumIntegerDigits = Math.min(Math.max(0, newValue), MAXIMUM_INTEGER_DIGITS); super.setMinimumIntegerDigits((minimumIntegerDigits > DOUBLE_INTEGER_DIGITS) ? DOUBLE_INTEGER_DIGITS : minimumIntegerDigits); if (minimumIntegerDigits > maximumIntegerDigits) { maximumIntegerDigits = minimumIntegerDigits; super.setMaximumIntegerDigits((maximumIntegerDigits > DOUBLE_INTEGER_DIGITS) ? DOUBLE_INTEGER_DIGITS : maximumIntegerDigits); } }
Sets the maximum number of digits allowed in the fraction portion of a number. For formatting numbers other than BigInteger and BigDecimal objects, the lower of newValue and 340 is used. Negative input values are replaced with 0.
See Also:
  • setMaximumFractionDigits.setMaximumFractionDigits
/** * Sets the maximum number of digits allowed in the fraction portion of a * number. * For formatting numbers other than <code>BigInteger</code> and * <code>BigDecimal</code> objects, the lower of <code>newValue</code> and * 340 is used. Negative input values are replaced with 0. * @see NumberFormat#setMaximumFractionDigits */
public void setMaximumFractionDigits(int newValue) { maximumFractionDigits = Math.min(Math.max(0, newValue), MAXIMUM_FRACTION_DIGITS); super.setMaximumFractionDigits((maximumFractionDigits > DOUBLE_FRACTION_DIGITS) ? DOUBLE_FRACTION_DIGITS : maximumFractionDigits); if (minimumFractionDigits > maximumFractionDigits) { minimumFractionDigits = maximumFractionDigits; super.setMinimumFractionDigits((minimumFractionDigits > DOUBLE_FRACTION_DIGITS) ? DOUBLE_FRACTION_DIGITS : minimumFractionDigits); } }
Sets the minimum number of digits allowed in the fraction portion of a number. For formatting numbers other than BigInteger and BigDecimal objects, the lower of newValue and 340 is used. Negative input values are replaced with 0.
See Also:
  • setMinimumFractionDigits.setMinimumFractionDigits
/** * Sets the minimum number of digits allowed in the fraction portion of a * number. * For formatting numbers other than <code>BigInteger</code> and * <code>BigDecimal</code> objects, the lower of <code>newValue</code> and * 340 is used. Negative input values are replaced with 0. * @see NumberFormat#setMinimumFractionDigits */
public void setMinimumFractionDigits(int newValue) { minimumFractionDigits = Math.min(Math.max(0, newValue), MAXIMUM_FRACTION_DIGITS); super.setMinimumFractionDigits((minimumFractionDigits > DOUBLE_FRACTION_DIGITS) ? DOUBLE_FRACTION_DIGITS : minimumFractionDigits); if (minimumFractionDigits > maximumFractionDigits) { maximumFractionDigits = minimumFractionDigits; super.setMaximumFractionDigits((maximumFractionDigits > DOUBLE_FRACTION_DIGITS) ? DOUBLE_FRACTION_DIGITS : maximumFractionDigits); } }
Gets the maximum number of digits allowed in the integer portion of a number. For formatting numbers other than BigInteger and BigDecimal objects, the lower of the return value and 309 is used.
See Also:
  • setMaximumIntegerDigits
/** * Gets the maximum number of digits allowed in the integer portion of a * number. * For formatting numbers other than <code>BigInteger</code> and * <code>BigDecimal</code> objects, the lower of the return value and * 309 is used. * @see #setMaximumIntegerDigits */
public int getMaximumIntegerDigits() { return maximumIntegerDigits; }
Gets the minimum number of digits allowed in the integer portion of a number. For formatting numbers other than BigInteger and BigDecimal objects, the lower of the return value and 309 is used.
See Also:
  • setMinimumIntegerDigits
/** * Gets the minimum number of digits allowed in the integer portion of a * number. * For formatting numbers other than <code>BigInteger</code> and * <code>BigDecimal</code> objects, the lower of the return value and * 309 is used. * @see #setMinimumIntegerDigits */
public int getMinimumIntegerDigits() { return minimumIntegerDigits; }
Gets the maximum number of digits allowed in the fraction portion of a number. For formatting numbers other than BigInteger and BigDecimal objects, the lower of the return value and 340 is used.
See Also:
  • setMaximumFractionDigits
/** * Gets the maximum number of digits allowed in the fraction portion of a * number. * For formatting numbers other than <code>BigInteger</code> and * <code>BigDecimal</code> objects, the lower of the return value and * 340 is used. * @see #setMaximumFractionDigits */
public int getMaximumFractionDigits() { return maximumFractionDigits; }
Gets the minimum number of digits allowed in the fraction portion of a number. For formatting numbers other than BigInteger and BigDecimal objects, the lower of the return value and 340 is used.
See Also:
  • setMinimumFractionDigits
/** * Gets the minimum number of digits allowed in the fraction portion of a * number. * For formatting numbers other than <code>BigInteger</code> and * <code>BigDecimal</code> objects, the lower of the return value and * 340 is used. * @see #setMinimumFractionDigits */
public int getMinimumFractionDigits() { return minimumFractionDigits; }
Gets the currency used by this decimal format when formatting currency values. The currency is obtained by calling DecimalFormatSymbols.getCurrency on this number format's symbols.
Returns:the currency used by this decimal format, or null
Since:1.4
/** * Gets the currency used by this decimal format when formatting * currency values. * The currency is obtained by calling * {@link DecimalFormatSymbols#getCurrency DecimalFormatSymbols.getCurrency} * on this number format's symbols. * * @return the currency used by this decimal format, or <code>null</code> * @since 1.4 */
public Currency getCurrency() { return symbols.getCurrency(); }
Sets the currency used by this number format when formatting currency values. This does not update the minimum or maximum number of fraction digits used by the number format. The currency is set by calling DecimalFormatSymbols.setCurrency on this number format's symbols.
Params:
  • currency – the new currency to be used by this decimal format
Throws:
Since:1.4
/** * Sets the currency used by this number format when formatting * currency values. This does not update the minimum or maximum * number of fraction digits used by the number format. * The currency is set by calling * {@link DecimalFormatSymbols#setCurrency DecimalFormatSymbols.setCurrency} * on this number format's symbols. * * @param currency the new currency to be used by this decimal format * @exception NullPointerException if <code>currency</code> is null * @since 1.4 */
public void setCurrency(Currency currency) { if (currency != symbols.getCurrency()) { symbols.setCurrency(currency); if (isCurrencyFormat) { expandAffixes(); } } }
Gets the RoundingMode used in this DecimalFormat.
See Also:
Returns:The RoundingMode used for this DecimalFormat.
Since:1.6
/** * Gets the {@link java.math.RoundingMode} used in this DecimalFormat. * * @return The <code>RoundingMode</code> used for this DecimalFormat. * @see #setRoundingMode(RoundingMode) * @since 1.6 */
public RoundingMode getRoundingMode() { return roundingMode; }
Sets the RoundingMode used in this DecimalFormat.
Params:
  • roundingMode – The RoundingMode to be used
Throws:
See Also:
Since:1.6
/** * Sets the {@link java.math.RoundingMode} used in this DecimalFormat. * * @param roundingMode The <code>RoundingMode</code> to be used * @see #getRoundingMode() * @exception NullPointerException if <code>roundingMode</code> is null. * @since 1.6 */
public void setRoundingMode(RoundingMode roundingMode) { if (roundingMode == null) { throw new NullPointerException(); } this.roundingMode = roundingMode; digitList.setRoundingMode(roundingMode); }
Adjusts the minimum and maximum fraction digits to values that are reasonable for the currency's default fraction digits.
/** * Adjusts the minimum and maximum fraction digits to values that * are reasonable for the currency's default fraction digits. */
void adjustForCurrencyDefaultFractionDigits() { Currency currency = symbols.getCurrency(); if (currency == null) { try { currency = Currency.getInstance(symbols.getInternationalCurrencySymbol()); } catch (IllegalArgumentException e) { } } if (currency != null) { int digits = currency.getDefaultFractionDigits(); if (digits != -1) { int oldMinDigits = getMinimumFractionDigits(); // Common patterns are "#.##", "#.00", "#". // Try to adjust all of them in a reasonable way. if (oldMinDigits == getMaximumFractionDigits()) { setMinimumFractionDigits(digits); setMaximumFractionDigits(digits); } else { setMinimumFractionDigits(Math.min(digits, oldMinDigits)); setMaximumFractionDigits(digits); } } } }
Reads the default serializable fields from the stream and performs validations and adjustments for older serialized versions. The validations and adjustments are:
  1. Verify that the superclass's digit count fields correctly reflect the limits imposed on formatting numbers other than BigInteger and BigDecimal objects. These limits are stored in the superclass for serialization compatibility with older versions, while the limits for BigInteger and BigDecimal objects are kept in this class. If, in the superclass, the minimum or maximum integer digit count is larger than DOUBLE_INTEGER_DIGITS or if the minimum or maximum fraction digit count is larger than DOUBLE_FRACTION_DIGITS, then the stream data is invalid and this method throws an InvalidObjectException.
  2. If serialVersionOnStream is less than 4, initialize roundingMode to RoundingMode.HALF_EVEN. This field is new with version 4.
  3. If serialVersionOnStream is less than 3, then call the setters for the minimum and maximum integer and fraction digits with the values of the corresponding superclass getters to initialize the fields in this class. The fields in this class are new with version 3.
  4. If serialVersionOnStream is less than 1, indicating that the stream was written by JDK 1.1, initialize useExponentialNotation to false, since it was not present in JDK 1.1.
  5. Set serialVersionOnStream to the maximum allowed value so that default serialization will work properly if this object is streamed out again.

Stream versions older than 2 will not have the affix pattern variables posPrefixPattern etc. As a result, they will be initialized to null, which means the affix strings will be taken as literal values. This is exactly what we want, since that corresponds to the pre-version-2 behavior.

/** * Reads the default serializable fields from the stream and performs * validations and adjustments for older serialized versions. The * validations and adjustments are: * <ol> * <li> * Verify that the superclass's digit count fields correctly reflect * the limits imposed on formatting numbers other than * <code>BigInteger</code> and <code>BigDecimal</code> objects. These * limits are stored in the superclass for serialization compatibility * with older versions, while the limits for <code>BigInteger</code> and * <code>BigDecimal</code> objects are kept in this class. * If, in the superclass, the minimum or maximum integer digit count is * larger than <code>DOUBLE_INTEGER_DIGITS</code> or if the minimum or * maximum fraction digit count is larger than * <code>DOUBLE_FRACTION_DIGITS</code>, then the stream data is invalid * and this method throws an <code>InvalidObjectException</code>. * <li> * If <code>serialVersionOnStream</code> is less than 4, initialize * <code>roundingMode</code> to {@link java.math.RoundingMode#HALF_EVEN * RoundingMode.HALF_EVEN}. This field is new with version 4. * <li> * If <code>serialVersionOnStream</code> is less than 3, then call * the setters for the minimum and maximum integer and fraction digits with * the values of the corresponding superclass getters to initialize the * fields in this class. The fields in this class are new with version 3. * <li> * If <code>serialVersionOnStream</code> is less than 1, indicating that * the stream was written by JDK 1.1, initialize * <code>useExponentialNotation</code> * to false, since it was not present in JDK 1.1. * <li> * Set <code>serialVersionOnStream</code> to the maximum allowed value so * that default serialization will work properly if this object is streamed * out again. * </ol> * * <p>Stream versions older than 2 will not have the affix pattern variables * <code>posPrefixPattern</code> etc. As a result, they will be initialized * to <code>null</code>, which means the affix strings will be taken as * literal values. This is exactly what we want, since that corresponds to * the pre-version-2 behavior. */
private void readObject(ObjectInputStream stream) throws IOException, ClassNotFoundException { stream.defaultReadObject(); digitList = new DigitList(); if (serialVersionOnStream < 4) { setRoundingMode(RoundingMode.HALF_EVEN); } // We only need to check the maximum counts because NumberFormat // .readObject has already ensured that the maximum is greater than the // minimum count. if (super.getMaximumIntegerDigits() > DOUBLE_INTEGER_DIGITS || super.getMaximumFractionDigits() > DOUBLE_FRACTION_DIGITS) { throw new InvalidObjectException("Digit count out of range"); } if (serialVersionOnStream < 3) { setMaximumIntegerDigits(super.getMaximumIntegerDigits()); setMinimumIntegerDigits(super.getMinimumIntegerDigits()); setMaximumFractionDigits(super.getMaximumFractionDigits()); setMinimumFractionDigits(super.getMinimumFractionDigits()); } if (serialVersionOnStream < 1) { // Didn't have exponential fields useExponentialNotation = false; } serialVersionOnStream = currentSerialVersion; } //---------------------------------------------------------------------- // INSTANCE VARIABLES //---------------------------------------------------------------------- private transient DigitList digitList = new DigitList();
The symbol used as a prefix when formatting positive numbers, e.g. "+".
See Also:
@serial
/** * The symbol used as a prefix when formatting positive numbers, e.g. "+". * * @serial * @see #getPositivePrefix */
private String positivePrefix = "";
The symbol used as a suffix when formatting positive numbers. This is often an empty string.
See Also:
@serial
/** * The symbol used as a suffix when formatting positive numbers. * This is often an empty string. * * @serial * @see #getPositiveSuffix */
private String positiveSuffix = "";
The symbol used as a prefix when formatting negative numbers, e.g. "-".
See Also:
@serial
/** * The symbol used as a prefix when formatting negative numbers, e.g. "-". * * @serial * @see #getNegativePrefix */
private String negativePrefix = "-";
The symbol used as a suffix when formatting negative numbers. This is often an empty string.
See Also:
@serial
/** * The symbol used as a suffix when formatting negative numbers. * This is often an empty string. * * @serial * @see #getNegativeSuffix */
private String negativeSuffix = "";
The prefix pattern for non-negative numbers. This variable corresponds to positivePrefix.

This pattern is expanded by the method expandAffix() to positivePrefix to update the latter to reflect changes in symbols. If this variable is null then positivePrefix is taken as a literal value that does not change when symbols changes. This variable is always null for DecimalFormat objects older than stream version 2 restored from stream.

@serial
Since:1.3
/** * The prefix pattern for non-negative numbers. This variable corresponds * to <code>positivePrefix</code>. * * <p>This pattern is expanded by the method <code>expandAffix()</code> to * <code>positivePrefix</code> to update the latter to reflect changes in * <code>symbols</code>. If this variable is <code>null</code> then * <code>positivePrefix</code> is taken as a literal value that does not * change when <code>symbols</code> changes. This variable is always * <code>null</code> for <code>DecimalFormat</code> objects older than * stream version 2 restored from stream. * * @serial * @since 1.3 */
private String posPrefixPattern;
The suffix pattern for non-negative numbers. This variable corresponds to positiveSuffix. This variable is analogous to posPrefixPattern; see that variable for further documentation.
@serial
Since:1.3
/** * The suffix pattern for non-negative numbers. This variable corresponds * to <code>positiveSuffix</code>. This variable is analogous to * <code>posPrefixPattern</code>; see that variable for further * documentation. * * @serial * @since 1.3 */
private String posSuffixPattern;
The prefix pattern for negative numbers. This variable corresponds to negativePrefix. This variable is analogous to posPrefixPattern; see that variable for further documentation.
@serial
Since:1.3
/** * The prefix pattern for negative numbers. This variable corresponds * to <code>negativePrefix</code>. This variable is analogous to * <code>posPrefixPattern</code>; see that variable for further * documentation. * * @serial * @since 1.3 */
private String negPrefixPattern;
The suffix pattern for negative numbers. This variable corresponds to negativeSuffix. This variable is analogous to posPrefixPattern; see that variable for further documentation.
@serial
Since:1.3
/** * The suffix pattern for negative numbers. This variable corresponds * to <code>negativeSuffix</code>. This variable is analogous to * <code>posPrefixPattern</code>; see that variable for further * documentation. * * @serial * @since 1.3 */
private String negSuffixPattern;
The multiplier for use in percent, per mille, etc.
See Also:
@serial
/** * The multiplier for use in percent, per mille, etc. * * @serial * @see #getMultiplier */
private int multiplier = 1;
The number of digits between grouping separators in the integer portion of a number. Must be greater than 0 if NumberFormat.groupingUsed is true.
See Also:
@serial
/** * The number of digits between grouping separators in the integer * portion of a number. Must be greater than 0 if * <code>NumberFormat.groupingUsed</code> is true. * * @serial * @see #getGroupingSize * @see java.text.NumberFormat#isGroupingUsed */
private byte groupingSize = 3; // invariant, > 0 if useThousands
If true, forces the decimal separator to always appear in a formatted number, even if the fractional part of the number is zero.
See Also:
@serial
/** * If true, forces the decimal separator to always appear in a formatted * number, even if the fractional part of the number is zero. * * @serial * @see #isDecimalSeparatorAlwaysShown */
private boolean decimalSeparatorAlwaysShown = false;
If true, parse returns BigDecimal wherever possible.
See Also:
@serial
Since:1.5
/** * If true, parse returns BigDecimal wherever possible. * * @serial * @see #isParseBigDecimal * @since 1.5 */
private boolean parseBigDecimal = false;
True if this object represents a currency format. This determines whether the monetary decimal separator is used instead of the normal one.
/** * True if this object represents a currency format. This determines * whether the monetary decimal separator is used instead of the normal one. */
private transient boolean isCurrencyFormat = false;
The DecimalFormatSymbols object used by this format. It contains the symbols used to format numbers, e.g. the grouping separator, decimal separator, and so on.
See Also:
@serial
/** * The <code>DecimalFormatSymbols</code> object used by this format. * It contains the symbols used to format numbers, e.g. the grouping separator, * decimal separator, and so on. * * @serial * @see #setDecimalFormatSymbols * @see java.text.DecimalFormatSymbols */
private DecimalFormatSymbols symbols = null; // LIU new DecimalFormatSymbols();
True to force the use of exponential (i.e. scientific) notation when formatting numbers.
@serial
Since:1.2
/** * True to force the use of exponential (i.e. scientific) notation when formatting * numbers. * * @serial * @since 1.2 */
private boolean useExponentialNotation; // Newly persistent in the Java 2 platform v.1.2
FieldPositions describing the positive prefix String. This is lazily created. Use getPositivePrefixFieldPositions when needed.
/** * FieldPositions describing the positive prefix String. This is * lazily created. Use <code>getPositivePrefixFieldPositions</code> * when needed. */
private transient FieldPosition[] positivePrefixFieldPositions;
FieldPositions describing the positive suffix String. This is lazily created. Use getPositiveSuffixFieldPositions when needed.
/** * FieldPositions describing the positive suffix String. This is * lazily created. Use <code>getPositiveSuffixFieldPositions</code> * when needed. */
private transient FieldPosition[] positiveSuffixFieldPositions;
FieldPositions describing the negative prefix String. This is lazily created. Use getNegativePrefixFieldPositions when needed.
/** * FieldPositions describing the negative prefix String. This is * lazily created. Use <code>getNegativePrefixFieldPositions</code> * when needed. */
private transient FieldPosition[] negativePrefixFieldPositions;
FieldPositions describing the negative suffix String. This is lazily created. Use getNegativeSuffixFieldPositions when needed.
/** * FieldPositions describing the negative suffix String. This is * lazily created. Use <code>getNegativeSuffixFieldPositions</code> * when needed. */
private transient FieldPosition[] negativeSuffixFieldPositions;
The minimum number of digits used to display the exponent when a number is formatted in exponential notation. This field is ignored if useExponentialNotation is not true.
@serial
Since:1.2
/** * The minimum number of digits used to display the exponent when a number is * formatted in exponential notation. This field is ignored if * <code>useExponentialNotation</code> is not true. * * @serial * @since 1.2 */
private byte minExponentDigits; // Newly persistent in the Java 2 platform v.1.2
The maximum number of digits allowed in the integer portion of a BigInteger or BigDecimal number. maximumIntegerDigits must be greater than or equal to minimumIntegerDigits.
See Also:
@serial
Since:1.5
/** * The maximum number of digits allowed in the integer portion of a * <code>BigInteger</code> or <code>BigDecimal</code> number. * <code>maximumIntegerDigits</code> must be greater than or equal to * <code>minimumIntegerDigits</code>. * * @serial * @see #getMaximumIntegerDigits * @since 1.5 */
private int maximumIntegerDigits = super.getMaximumIntegerDigits();
The minimum number of digits allowed in the integer portion of a BigInteger or BigDecimal number. minimumIntegerDigits must be less than or equal to maximumIntegerDigits.
See Also:
@serial
Since:1.5
/** * The minimum number of digits allowed in the integer portion of a * <code>BigInteger</code> or <code>BigDecimal</code> number. * <code>minimumIntegerDigits</code> must be less than or equal to * <code>maximumIntegerDigits</code>. * * @serial * @see #getMinimumIntegerDigits * @since 1.5 */
private int minimumIntegerDigits = super.getMinimumIntegerDigits();
The maximum number of digits allowed in the fractional portion of a BigInteger or BigDecimal number. maximumFractionDigits must be greater than or equal to minimumFractionDigits.
See Also:
@serial
Since:1.5
/** * The maximum number of digits allowed in the fractional portion of a * <code>BigInteger</code> or <code>BigDecimal</code> number. * <code>maximumFractionDigits</code> must be greater than or equal to * <code>minimumFractionDigits</code>. * * @serial * @see #getMaximumFractionDigits * @since 1.5 */
private int maximumFractionDigits = super.getMaximumFractionDigits();
The minimum number of digits allowed in the fractional portion of a BigInteger or BigDecimal number. minimumFractionDigits must be less than or equal to maximumFractionDigits.
See Also:
@serial
Since:1.5
/** * The minimum number of digits allowed in the fractional portion of a * <code>BigInteger</code> or <code>BigDecimal</code> number. * <code>minimumFractionDigits</code> must be less than or equal to * <code>maximumFractionDigits</code>. * * @serial * @see #getMinimumFractionDigits * @since 1.5 */
private int minimumFractionDigits = super.getMinimumFractionDigits();
The RoundingMode used in this DecimalFormat.
@serial
Since:1.6
/** * The {@link java.math.RoundingMode} used in this DecimalFormat. * * @serial * @since 1.6 */
private RoundingMode roundingMode = RoundingMode.HALF_EVEN; //---------------------------------------------------------------------- static final int currentSerialVersion = 4;
The internal serial version which says which version was written. Possible values are:
  • 0 (default): versions before the Java 2 platform v1.2
  • 1: version for 1.2, which includes the two new fields useExponentialNotation and minExponentDigits.
  • 2: version for 1.3 and later, which adds four new fields: posPrefixPattern, posSuffixPattern, negPrefixPattern, and negSuffixPattern.
  • 3: version for 1.5 and later, which adds five new fields: maximumIntegerDigits, minimumIntegerDigits, maximumFractionDigits, minimumFractionDigits, and parseBigDecimal.
  • 4: version for 1.6 and later, which adds one new field: roundingMode.
Since:1.2
@serial
/** * The internal serial version which says which version was written. * Possible values are: * <ul> * <li><b>0</b> (default): versions before the Java 2 platform v1.2 * <li><b>1</b>: version for 1.2, which includes the two new fields * <code>useExponentialNotation</code> and * <code>minExponentDigits</code>. * <li><b>2</b>: version for 1.3 and later, which adds four new fields: * <code>posPrefixPattern</code>, <code>posSuffixPattern</code>, * <code>negPrefixPattern</code>, and <code>negSuffixPattern</code>. * <li><b>3</b>: version for 1.5 and later, which adds five new fields: * <code>maximumIntegerDigits</code>, * <code>minimumIntegerDigits</code>, * <code>maximumFractionDigits</code>, * <code>minimumFractionDigits</code>, and * <code>parseBigDecimal</code>. * <li><b>4</b>: version for 1.6 and later, which adds one new field: * <code>roundingMode</code>. * </ul> * @since 1.2 * @serial */
private int serialVersionOnStream = currentSerialVersion; //---------------------------------------------------------------------- // CONSTANTS //---------------------------------------------------------------------- // Constants for characters used in programmatic (unlocalized) patterns. private static final char PATTERN_ZERO_DIGIT = '0'; private static final char PATTERN_GROUPING_SEPARATOR = ','; private static final char PATTERN_DECIMAL_SEPARATOR = '.'; private static final char PATTERN_PER_MILLE = '\u2030'; private static final char PATTERN_PERCENT = '%'; private static final char PATTERN_DIGIT = '#'; private static final char PATTERN_SEPARATOR = ';'; private static final String PATTERN_EXPONENT = "E"; private static final char PATTERN_MINUS = '-';
The CURRENCY_SIGN is the standard Unicode symbol for currency. It is used in patterns and substituted with either the currency symbol, or if it is doubled, with the international currency symbol. If the CURRENCY_SIGN is seen in a pattern, then the decimal separator is replaced with the monetary decimal separator. The CURRENCY_SIGN is not localized.
/** * The CURRENCY_SIGN is the standard Unicode symbol for currency. It * is used in patterns and substituted with either the currency symbol, * or if it is doubled, with the international currency symbol. If the * CURRENCY_SIGN is seen in a pattern, then the decimal separator is * replaced with the monetary decimal separator. * * The CURRENCY_SIGN is not localized. */
private static final char CURRENCY_SIGN = '\u00A4'; private static final char QUOTE = '\''; private static FieldPosition[] EmptyFieldPositionArray = new FieldPosition[0]; // Upper limit on integer and fraction digits for a Java double static final int DOUBLE_INTEGER_DIGITS = 309; static final int DOUBLE_FRACTION_DIGITS = 340; // Upper limit on integer and fraction digits for BigDecimal and BigInteger static final int MAXIMUM_INTEGER_DIGITS = Integer.MAX_VALUE; static final int MAXIMUM_FRACTION_DIGITS = Integer.MAX_VALUE; // Proclaim JDK 1.1 serial compatibility. static final long serialVersionUID = 864413376551465018L;
Cache to hold the NumberPattern of a Locale.
/** * Cache to hold the NumberPattern of a Locale. */
private static Hashtable cachedLocaleData = new Hashtable(3); }