/*
* Copyright (c) 1996, 2005, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Oracle designates this
* particular file as subject to the "Classpath" exception as provided
* by Oracle in the LICENSE file that accompanied this code.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
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/*
* (C) Copyright Taligent, Inc. 1996, 1997 - All Rights Reserved
* (C) Copyright IBM Corp. 1996 - 1998 - All Rights Reserved
*
* The original version of this source code and documentation is copyrighted
* and owned by Taligent, Inc., a wholly-owned subsidiary of IBM. These
* materials are provided under terms of a License Agreement between Taligent
* and Sun. This technology is protected by multiple US and International
* patents. This notice and attribution to Taligent may not be removed.
* Taligent is a registered trademark of Taligent, Inc.
*
*/
package java.text;
import java.io.InvalidObjectException;
import java.io.IOException;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
import java.math.BigInteger;
import java.math.RoundingMode;
import java.text.spi.NumberFormatProvider;
import java.util.Currency;
import java.util.HashMap;
import java.util.Hashtable;
import java.util.Locale;
import java.util.Map;
import java.util.ResourceBundle;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicLong;
import java.util.spi.LocaleServiceProvider;
import sun.util.LocaleServiceProviderPool;
import sun.util.resources.LocaleData;
/** {@collect.stats}
* <code>NumberFormat</code> is the abstract base class for all number
* formats. This class provides the interface for formatting and parsing
* numbers. <code>NumberFormat</code> also provides methods for determining
* which locales have number formats, and what their names are.
*
* <p>
* <code>NumberFormat</code> helps you to format and parse numbers for any locale.
* Your code can be completely independent of the locale conventions for
* decimal points, thousands-separators, or even the particular decimal
* digits used, or whether the number format is even decimal.
*
* <p>
* To format a number for the current Locale, use one of the factory
* class methods:
* <blockquote>
* <pre>
* myString = NumberFormat.getInstance().format(myNumber);
* </pre>
* </blockquote>
* If you are formatting multiple numbers, it is
* more efficient to get the format and use it multiple times so that
* the system doesn't have to fetch the information about the local
* language and country conventions multiple times.
* <blockquote>
* <pre>
* NumberFormat nf = NumberFormat.getInstance();
* for (int i = 0; i < myNumber.length; ++i) {
* output.println(nf.format(myNumber[i]) + "; ");
* }
* </pre>
* </blockquote>
* To format a number for a different Locale, specify it in the
* call to <code>getInstance</code>.
* <blockquote>
* <pre>
* NumberFormat nf = NumberFormat.getInstance(Locale.FRENCH);
* </pre>
* </blockquote>
* You can also use a <code>NumberFormat</code> to parse numbers:
* <blockquote>
* <pre>
* myNumber = nf.parse(myString);
* </pre>
* </blockquote>
* Use <code>getInstance</code> or <code>getNumberInstance</code> to get the
* normal number format. Use <code>getIntegerInstance</code> to get an
* integer number format. Use <code>getCurrencyInstance</code> to get the
* currency number format. And use <code>getPercentInstance</code> to get a
* format for displaying percentages. With this format, a fraction like
* 0.53 is displayed as 53%.
*
* <p>
* You can also control the display of numbers with such methods as
* <code>setMinimumFractionDigits</code>.
* If you want even more control over the format or parsing,
* or want to give your users more control,
* you can try casting the <code>NumberFormat</code> you get from the factory methods
* to a <code>DecimalFormat</code>. This will work for the vast majority
* of locales; just remember to put it in a <code>try</code> block in case you
* encounter an unusual one.
*
* <p>
* NumberFormat and DecimalFormat are designed such that some controls
* work for formatting and others work for parsing. The following is
* the detailed description for each these control methods,
* <p>
* setParseIntegerOnly : only affects parsing, e.g.
* if true, "3456.78" -> 3456 (and leaves the parse position just after index 6)
* if false, "3456.78" -> 3456.78 (and leaves the parse position just after index 8)
* This is independent of formatting. If you want to not show a decimal point
* where there might be no digits after the decimal point, use
* setDecimalSeparatorAlwaysShown.
* <p>
* setDecimalSeparatorAlwaysShown : only affects formatting, and only where
* there might be no digits after the decimal point, such as with a pattern
* like "#,##0.##", e.g.,
* if true, 3456.00 -> "3,456."
* if false, 3456.00 -> "3456"
* This is independent of parsing. If you want parsing to stop at the decimal
* point, use setParseIntegerOnly.
*
* <p>
* You can also use forms of the <code>parse</code> and <code>format</code>
* methods with <code>ParsePosition</code> and <code>FieldPosition</code> to
* allow you to:
* <ul>
* <li> progressively parse through pieces of a string
* <li> align the decimal point and other areas
* </ul>
* For example, you can align numbers in two ways:
* <ol>
* <li> If you are using a monospaced font with spacing for alignment,
* you can pass the <code>FieldPosition</code> in your format call, with
* <code>field</code> = <code>INTEGER_FIELD</code>. On output,
* <code>getEndIndex</code> will be set to the offset between the
* last character of the integer and the decimal. Add
* (desiredSpaceCount - getEndIndex) spaces at the front of the string.
*
* <li> If you are using proportional fonts,
* instead of padding with spaces, measure the width
* of the string in pixels from the start to <code>getEndIndex</code>.
* Then move the pen by
* (desiredPixelWidth - widthToAlignmentPoint) before drawing the text.
* It also works where there is no decimal, but possibly additional
* characters at the end, e.g., with parentheses in negative
* numbers: "(12)" for -12.
* </ol>
*
* <h4><a name="synchronization">Synchronization</a></h4>
*
* <p>
* Number 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.
*
* @see DecimalFormat
* @see ChoiceFormat
* @author Mark Davis
* @author Helena Shih
*/
public abstract class NumberFormat extends Format {
/** {@collect.stats}
* Field constant used to construct a FieldPosition object. Signifies that
* the position of the integer part of a formatted number should be returned.
* @see java.text.FieldPosition
*/
public static final int INTEGER_FIELD = 0;
/** {@collect.stats}
* Field constant used to construct a FieldPosition object. Signifies that
* the position of the fraction part of a formatted number should be returned.
* @see java.text.FieldPosition
*/
public static final int FRACTION_FIELD = 1;
/** {@collect.stats}
* Sole constructor. (For invocation by subclass constructors, typically
* implicit.)
*/
protected NumberFormat() {
}
/** {@collect.stats}
* 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 extracts the number's value using
* {@link java.lang.Number#longValue()} for all integral type values that
* can be converted to <code>long</code> without loss of information,
* including <code>BigInteger</code> values with a
* {@link java.math.BigInteger#bitLength() bit length} of less than 64,
* and {@link java.lang.Number#doubleValue()} for all other types. It
* then calls
* {@link #format(long,java.lang.StringBuffer,java.text.FieldPosition)}
* or {@link #format(double,java.lang.StringBuffer,java.text.FieldPosition)}.
* This may result in loss of magnitude information and precision for
* <code>BigInteger</code> and <code>BigDecimal</code> values.
* @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 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 Number) {
return format(((Number)number).doubleValue(), toAppendTo, pos);
} else {
throw new IllegalArgumentException("Cannot format given Object as a Number");
}
}
/** {@collect.stats}
* 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>
* See the {@link #parse(String, ParsePosition)} method for more information
* on number parsing.
*
* @param source A <code>String</code>, part of which should be parsed.
* @param pos A <code>ParsePosition</code> object with index and error
* index information as described above.
* @return A <code>Number</code> parsed from the string. In case of
* error, returns null.
* @exception NullPointerException if <code>pos</code> is null.
*/
public final Object parseObject(String source, ParsePosition pos) {
return parse(source, pos);
}
/** {@collect.stats}
* Specialization of format.
* @exception ArithmeticException if rounding is needed with rounding
* mode being set to RoundingMode.UNNECESSARY
* @see java.text.Format#format
*/
public final String format(double number) {
return format(number, new StringBuffer(),
DontCareFieldPosition.INSTANCE).toString();
}
/** {@collect.stats}
* Specialization of format.
* @exception ArithmeticException if rounding is needed with rounding
* mode being set to RoundingMode.UNNECESSARY
* @see java.text.Format#format
*/
public final String format(long number) {
return format(number, new StringBuffer(),
DontCareFieldPosition.INSTANCE).toString();
}
/** {@collect.stats}
* Specialization of format.
* @exception ArithmeticException if rounding is needed with rounding
* mode being set to RoundingMode.UNNECESSARY
* @see java.text.Format#format
*/
public abstract StringBuffer format(double number,
StringBuffer toAppendTo,
FieldPosition pos);
/** {@collect.stats}
* Specialization of format.
* @exception ArithmeticException if rounding is needed with rounding
* mode being set to RoundingMode.UNNECESSARY
* @see java.text.Format#format
*/
public abstract StringBuffer format(long number,
StringBuffer toAppendTo,
FieldPosition pos);
/** {@collect.stats}
* Returns a Long if possible (e.g., within the range [Long.MIN_VALUE,
* Long.MAX_VALUE] and with no decimals), otherwise a Double.
* If IntegerOnly is set, will stop at a decimal
* point (or equivalent; e.g., for rational numbers "1 2/3", will stop
* after the 1).
* Does not throw an exception; if no object can be parsed, index is
* unchanged!
* @see java.text.NumberFormat#isParseIntegerOnly
* @see java.text.Format#parseObject
*/
public abstract Number parse(String source, ParsePosition parsePosition);
/** {@collect.stats}
* Parses text from the beginning of the given string to produce a number.
* The method may not use the entire text of the given string.
* <p>
* See the {@link #parse(String, ParsePosition)} method for more information
* on number parsing.
*
* @param source A <code>String</code> whose beginning should be parsed.
* @return A <code>Number</code> parsed from the string.
* @exception ParseException if the beginning of the specified string
* cannot be parsed.
*/
public Number parse(String source) throws ParseException {
ParsePosition parsePosition = new ParsePosition(0);
Number result = parse(source, parsePosition);
if (parsePosition.index == 0) {
throw new ParseException("Unparseable number: \"" + source + "\"",
parsePosition.errorIndex);
}
return result;
}
/** {@collect.stats}
* Returns true if this format will parse numbers as integers only.
* For example in the English locale, with ParseIntegerOnly true, the
* string "1234." would be parsed as the integer value 1234 and parsing
* would stop at the "." character. Of course, the exact format accepted
* by the parse operation is locale dependant and determined by sub-classes
* of NumberFormat.
*/
public boolean isParseIntegerOnly() {
return parseIntegerOnly;
}
/** {@collect.stats}
* Sets whether or not numbers should be parsed as integers only.
* @see #isParseIntegerOnly
*/
public void setParseIntegerOnly(boolean value) {
parseIntegerOnly = value;
}
//============== Locale Stuff =====================
/** {@collect.stats}
* Returns a general-purpose number format for the current default locale.
* This is the same as calling
* {@link #getNumberInstance() getNumberInstance()}.
*/
public final static NumberFormat getInstance() {
return getInstance(Locale.getDefault(), NUMBERSTYLE);
}
/** {@collect.stats}
* Returns a general-purpose number format for the specified locale.
* This is the same as calling
* {@link #getNumberInstance(java.util.Locale) getNumberInstance(inLocale)}.
*/
public static NumberFormat getInstance(Locale inLocale) {
return getInstance(inLocale, NUMBERSTYLE);
}
/** {@collect.stats}
* Returns a general-purpose number format for the current default locale.
*/
public final static NumberFormat getNumberInstance() {
return getInstance(Locale.getDefault(), NUMBERSTYLE);
}
/** {@collect.stats}
* Returns a general-purpose number format for the specified locale.
*/
public static NumberFormat getNumberInstance(Locale inLocale) {
return getInstance(inLocale, NUMBERSTYLE);
}
/** {@collect.stats}
* Returns an integer number format for the current default locale. The
* returned number format is configured to round floating point numbers
* to the nearest integer using half-even rounding (see {@link
* java.math.RoundingMode#HALF_EVEN RoundingMode.HALF_EVEN}) for formatting,
* and to parse only the integer part of an input string (see {@link
* #isParseIntegerOnly isParseIntegerOnly}).
*
* @see #getRoundingMode()
* @return a number format for integer values
* @since 1.4
*/
public final static NumberFormat getIntegerInstance() {
return getInstance(Locale.getDefault(), INTEGERSTYLE);
}
/** {@collect.stats}
* Returns an integer number format for the specified locale. The
* returned number format is configured to round floating point numbers
* to the nearest integer using half-even rounding (see {@link
* java.math.RoundingMode#HALF_EVEN RoundingMode.HALF_EVEN}) for formatting,
* and to parse only the integer part of an input string (see {@link
* #isParseIntegerOnly isParseIntegerOnly}).
*
* @see #getRoundingMode()
* @return a number format for integer values
* @since 1.4
*/
public static NumberFormat getIntegerInstance(Locale inLocale) {
return getInstance(inLocale, INTEGERSTYLE);
}
/** {@collect.stats}
* Returns a currency format for the current default locale.
*/
public final static NumberFormat getCurrencyInstance() {
return getInstance(Locale.getDefault(), CURRENCYSTYLE);
}
/** {@collect.stats}
* Returns a currency format for the specified locale.
*/
public static NumberFormat getCurrencyInstance(Locale inLocale) {
return getInstance(inLocale, CURRENCYSTYLE);
}
/** {@collect.stats}
* Returns a percentage format for the current default locale.
*/
public final static NumberFormat getPercentInstance() {
return getInstance(Locale.getDefault(), PERCENTSTYLE);
}
/** {@collect.stats}
* Returns a percentage format for the specified locale.
*/
public static NumberFormat getPercentInstance(Locale inLocale) {
return getInstance(inLocale, PERCENTSTYLE);
}
/** {@collect.stats}
* Returns a scientific format for the current default locale.
*/
/*public*/ final static NumberFormat getScientificInstance() {
return getInstance(Locale.getDefault(), SCIENTIFICSTYLE);
}
/** {@collect.stats}
* Returns a scientific format for the specified locale.
*/
/*public*/ static NumberFormat getScientificInstance(Locale inLocale) {
return getInstance(inLocale, SCIENTIFICSTYLE);
}
/** {@collect.stats}
* Returns an array of all locales for which the
* <code>get*Instance</code> methods of this class can return
* localized instances.
* The returned array represents the union of locales supported by the Java
* runtime and by installed
* {@link java.text.spi.NumberFormatProvider NumberFormatProvider} implementations.
* It must contain at least a <code>Locale</code> instance equal to
* {@link java.util.Locale#US Locale.US}.
*
* @return An array of locales for which localized
* <code>NumberFormat</code> instances are available.
*/
public static Locale[] getAvailableLocales() {
LocaleServiceProviderPool pool =
LocaleServiceProviderPool.getPool(NumberFormatProvider.class);
return pool.getAvailableLocales();
}
/** {@collect.stats}
* Overrides hashCode
*/
public int hashCode() {
return maximumIntegerDigits * 37 + maxFractionDigits;
// just enough fields for a reasonable distribution
}
/** {@collect.stats}
* Overrides equals
*/
public boolean equals(Object obj) {
if (obj == null) {
return false;
}
if (this == obj) {
return true;
}
if (getClass() != obj.getClass()) {
return false;
}
NumberFormat other = (NumberFormat) obj;
return (maximumIntegerDigits == other.maximumIntegerDigits
&& minimumIntegerDigits == other.minimumIntegerDigits
&& maximumFractionDigits == other.maximumFractionDigits
&& minimumFractionDigits == other.minimumFractionDigits
&& groupingUsed == other.groupingUsed
&& parseIntegerOnly == other.parseIntegerOnly);
}
/** {@collect.stats}
* Overrides Cloneable
*/
public Object clone() {
NumberFormat other = (NumberFormat) super.clone();
return other;
}
/** {@collect.stats}
* Returns true if grouping is used in this format. For example, in the
* English locale, with grouping on, the number 1234567 might be formatted
* as "1,234,567". The grouping separator as well as the size of each group
* is locale dependant and is determined by sub-classes of NumberFormat.
* @see #setGroupingUsed
*/
public boolean isGroupingUsed() {
return groupingUsed;
}
/** {@collect.stats}
* Set whether or not grouping will be used in this format.
* @see #isGroupingUsed
*/
public void setGroupingUsed(boolean newValue) {
groupingUsed = newValue;
}
/** {@collect.stats}
* Returns the maximum number of digits allowed in the integer portion of a
* number.
* @see #setMaximumIntegerDigits
*/
public int getMaximumIntegerDigits() {
return maximumIntegerDigits;
}
/** {@collect.stats}
* Sets the maximum number of digits allowed in the integer portion of a
* number. maximumIntegerDigits must be >= minimumIntegerDigits. If the
* new value for maximumIntegerDigits is less than the current value
* of minimumIntegerDigits, then minimumIntegerDigits will also be set to
* the new value.
* @param newValue the maximum number of integer digits to be shown; if
* less than zero, then zero is used. The concrete subclass may enforce an
* upper limit to this value appropriate to the numeric type being formatted.
* @see #getMaximumIntegerDigits
*/
public void setMaximumIntegerDigits(int newValue) {
maximumIntegerDigits = Math.max(0,newValue);
if (minimumIntegerDigits > maximumIntegerDigits) {
minimumIntegerDigits = maximumIntegerDigits;
}
}
/** {@collect.stats}
* Returns the minimum number of digits allowed in the integer portion of a
* number.
* @see #setMinimumIntegerDigits
*/
public int getMinimumIntegerDigits() {
return minimumIntegerDigits;
}
/** {@collect.stats}
* Sets the minimum number of digits allowed in the integer portion of a
* number. minimumIntegerDigits must be <= maximumIntegerDigits. If the
* new value for minimumIntegerDigits exceeds the current value
* of maximumIntegerDigits, then maximumIntegerDigits will also be set to
* the new value
* @param newValue the minimum number of integer digits to be shown; if
* less than zero, then zero is used. The concrete subclass may enforce an
* upper limit to this value appropriate to the numeric type being formatted.
* @see #getMinimumIntegerDigits
*/
public void setMinimumIntegerDigits(int newValue) {
minimumIntegerDigits = Math.max(0,newValue);
if (minimumIntegerDigits > maximumIntegerDigits) {
maximumIntegerDigits = minimumIntegerDigits;
}
}
/** {@collect.stats}
* Returns the maximum number of digits allowed in the fraction portion of a
* number.
* @see #setMaximumFractionDigits
*/
public int getMaximumFractionDigits() {
return maximumFractionDigits;
}
/** {@collect.stats}
* Sets the maximum number of digits allowed in the fraction portion of a
* number. maximumFractionDigits must be >= minimumFractionDigits. If the
* new value for maximumFractionDigits is less than the current value
* of minimumFractionDigits, then minimumFractionDigits will also be set to
* the new value.
* @param newValue the maximum number of fraction digits to be shown; if
* less than zero, then zero is used. The concrete subclass may enforce an
* upper limit to this value appropriate to the numeric type being formatted.
* @see #getMaximumFractionDigits
*/
public void setMaximumFractionDigits(int newValue) {
maximumFractionDigits = Math.max(0,newValue);
if (maximumFractionDigits < minimumFractionDigits) {
minimumFractionDigits = maximumFractionDigits;
}
}
/** {@collect.stats}
* Returns the minimum number of digits allowed in the fraction portion of a
* number.
* @see #setMinimumFractionDigits
*/
public int getMinimumFractionDigits() {
return minimumFractionDigits;
}
/** {@collect.stats}
* Sets the minimum number of digits allowed in the fraction portion of a
* number. minimumFractionDigits must be <= maximumFractionDigits. If the
* new value for minimumFractionDigits exceeds the current value
* of maximumFractionDigits, then maximumIntegerDigits will also be set to
* the new value
* @param newValue the minimum number of fraction digits to be shown; if
* less than zero, then zero is used. The concrete subclass may enforce an
* upper limit to this value appropriate to the numeric type being formatted.
* @see #getMinimumFractionDigits
*/
public void setMinimumFractionDigits(int newValue) {
minimumFractionDigits = Math.max(0,newValue);
if (maximumFractionDigits < minimumFractionDigits) {
maximumFractionDigits = minimumFractionDigits;
}
}
/** {@collect.stats}
* Gets the currency used by this number format when formatting
* currency values. The initial value is derived in a locale dependent
* way. The returned value may be null if no valid
* currency could be determined and no currency has been set using
* {@link #setCurrency(java.util.Currency) setCurrency}.
* <p>
* The default implementation throws
* <code>UnsupportedOperationException</code>.
*
* @return the currency used by this number format, or <code>null</code>
* @exception UnsupportedOperationException if the number format class
* doesn't implement currency formatting
* @since 1.4
*/
public Currency getCurrency() {
throw new UnsupportedOperationException();
}
/** {@collect.stats}
* 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.
* <p>
* The default implementation throws
* <code>UnsupportedOperationException</code>.
*
* @param currency the new currency to be used by this number format
* @exception UnsupportedOperationException if the number format class
* doesn't implement currency formatting
* @exception NullPointerException if <code>currency</code> is null
* @since 1.4
*/
public void setCurrency(Currency currency) {
throw new UnsupportedOperationException();
}
/** {@collect.stats}
* Gets the {@link java.math.RoundingMode} used in this NumberFormat.
* The default implementation of this method in NumberFormat
* always throws {@link java.lang.UnsupportedOperationException}.
* Subclasses which handle different rounding modes should override
* this method.
*
* @exception UnsupportedOperationException The default implementation
* always throws this exception
* @return The <code>RoundingMode</code> used for this NumberFormat.
* @see #setRoundingMode(RoundingMode)
* @since 1.6
*/
public RoundingMode getRoundingMode() {
throw new UnsupportedOperationException();
}
/** {@collect.stats}
* Sets the {@link java.math.RoundingMode} used in this NumberFormat.
* The default implementation of this method in NumberFormat always
* throws {@link java.lang.UnsupportedOperationException}.
* Subclasses which handle different rounding modes should override
* this method.
*
* @exception UnsupportedOperationException The default implementation
* always throws this exception
* @exception NullPointerException if <code>roundingMode</code> is null
* @param roundingMode The <code>RoundingMode</code> to be used
* @see #getRoundingMode()
* @since 1.6
*/
public void setRoundingMode(RoundingMode roundingMode) {
throw new UnsupportedOperationException();
}
// =======================privates===============================
private static NumberFormat getInstance(Locale desiredLocale,
int choice) {
// Check whether a provider can provide an implementation that's closer
// to the requested locale than what the Java runtime itself can provide.
LocaleServiceProviderPool pool =
LocaleServiceProviderPool.getPool(NumberFormatProvider.class);
if (pool.hasProviders()) {
NumberFormat providersInstance = pool.getLocalizedObject(
NumberFormatGetter.INSTANCE,
desiredLocale,
choice);
if (providersInstance != null) {
return providersInstance;
}
}
/* try the cache first */
String[] numberPatterns = (String[])cachedLocaleData.get(desiredLocale);
if (numberPatterns == null) { /* cache miss */
ResourceBundle resource = LocaleData.getNumberFormatData(desiredLocale);
numberPatterns = resource.getStringArray("NumberPatterns");
/* update cache */
cachedLocaleData.put(desiredLocale, numberPatterns);
}
DecimalFormatSymbols symbols = DecimalFormatSymbols.getInstance(desiredLocale);
int entry = (choice == INTEGERSTYLE) ? NUMBERSTYLE : choice;
DecimalFormat format = new DecimalFormat(numberPatterns[entry], symbols);
if (choice == INTEGERSTYLE) {
format.setMaximumFractionDigits(0);
format.setDecimalSeparatorAlwaysShown(false);
format.setParseIntegerOnly(true);
} else if (choice == CURRENCYSTYLE) {
format.adjustForCurrencyDefaultFractionDigits();
}
return format;
}
/** {@collect.stats}
* First, read in the default serializable data.
*
* Then, if <code>serialVersionOnStream</code> is less than 1, indicating that
* the stream was written by JDK 1.1,
* set the <code>int</code> fields such as <code>maximumIntegerDigits</code>
* to be equal to the <code>byte</code> fields such as <code>maxIntegerDigits</code>,
* since the <code>int</code> fields were not present in JDK 1.1.
* Finally, set serialVersionOnStream back to the maximum allowed value so that
* default serialization will work properly if this object is streamed out again.
*
* <p>If <code>minimumIntegerDigits</code> is greater than
* <code>maximumIntegerDigits</code> or <code>minimumFractionDigits</code>
* is greater than <code>maximumFractionDigits</code>, then the stream data
* is invalid and this method throws an <code>InvalidObjectException</code>.
* In addition, if any of these values is negative, then this method throws
* an <code>InvalidObjectException</code>.
*
* @since 1.2
*/
private void readObject(ObjectInputStream stream)
throws IOException, ClassNotFoundException
{
stream.defaultReadObject();
if (serialVersionOnStream < 1) {
// Didn't have additional int fields, reassign to use them.
maximumIntegerDigits = maxIntegerDigits;
minimumIntegerDigits = minIntegerDigits;
maximumFractionDigits = maxFractionDigits;
minimumFractionDigits = minFractionDigits;
}
if (minimumIntegerDigits > maximumIntegerDigits ||
minimumFractionDigits > maximumFractionDigits ||
minimumIntegerDigits < 0 || minimumFractionDigits < 0) {
throw new InvalidObjectException("Digit count range invalid");
}
serialVersionOnStream = currentSerialVersion;
}
/** {@collect.stats}
* Write out the default serializable data, after first setting
* the <code>byte</code> fields such as <code>maxIntegerDigits</code> to be
* equal to the <code>int</code> fields such as <code>maximumIntegerDigits</code>
* (or to <code>Byte.MAX_VALUE</code>, whichever is smaller), for compatibility
* with the JDK 1.1 version of the stream format.
*
* @since 1.2
*/
private void writeObject(ObjectOutputStream stream)
throws IOException
{
maxIntegerDigits = (maximumIntegerDigits > Byte.MAX_VALUE) ?
Byte.MAX_VALUE : (byte)maximumIntegerDigits;
minIntegerDigits = (minimumIntegerDigits > Byte.MAX_VALUE) ?
Byte.MAX_VALUE : (byte)minimumIntegerDigits;
maxFractionDigits = (maximumFractionDigits > Byte.MAX_VALUE) ?
Byte.MAX_VALUE : (byte)maximumFractionDigits;
minFractionDigits = (minimumFractionDigits > Byte.MAX_VALUE) ?
Byte.MAX_VALUE : (byte)minimumFractionDigits;
stream.defaultWriteObject();
}
/** {@collect.stats}
* Cache to hold the NumberPatterns of a Locale.
*/
private static final Hashtable cachedLocaleData = new Hashtable(3);
// Constants used by factory methods to specify a style of format.
private static final int NUMBERSTYLE = 0;
private static final int CURRENCYSTYLE = 1;
private static final int PERCENTSTYLE = 2;
private static final int SCIENTIFICSTYLE = 3;
private static final int INTEGERSTYLE = 4;
/** {@collect.stats}
* True if the grouping (i.e. thousands) separator is used when
* formatting and parsing numbers.
*
* @serial
* @see #isGroupingUsed
*/
private boolean groupingUsed = true;
/** {@collect.stats}
* The maximum number of digits allowed in the integer portion of a
* number. <code>maxIntegerDigits</code> must be greater than or equal to
* <code>minIntegerDigits</code>.
* <p>
* <strong>Note:</strong> This field exists only for serialization
* compatibility with JDK 1.1. In Java platform 2 v1.2 and higher, the new
* <code>int</code> field <code>maximumIntegerDigits</code> is used instead.
* When writing to a stream, <code>maxIntegerDigits</code> is set to
* <code>maximumIntegerDigits</code> or <code>Byte.MAX_VALUE</code>,
* whichever is smaller. When reading from a stream, this field is used
* only if <code>serialVersionOnStream</code> is less than 1.
*
* @serial
* @see #getMaximumIntegerDigits
*/
private byte maxIntegerDigits = 40;
/** {@collect.stats}
* The minimum number of digits allowed in the integer portion of a
* number. <code>minimumIntegerDigits</code> must be less than or equal to
* <code>maximumIntegerDigits</code>.
* <p>
* <strong>Note:</strong> This field exists only for serialization
* compatibility with JDK 1.1. In Java platform 2 v1.2 and higher, the new
* <code>int</code> field <code>minimumIntegerDigits</code> is used instead.
* When writing to a stream, <code>minIntegerDigits</code> is set to
* <code>minimumIntegerDigits</code> or <code>Byte.MAX_VALUE</code>,
* whichever is smaller. When reading from a stream, this field is used
* only if <code>serialVersionOnStream</code> is less than 1.
*
* @serial
* @see #getMinimumIntegerDigits
*/
private byte minIntegerDigits = 1;
/** {@collect.stats}
* The maximum number of digits allowed in the fractional portion of a
* number. <code>maximumFractionDigits</code> must be greater than or equal to
* <code>minimumFractionDigits</code>.
* <p>
* <strong>Note:</strong> This field exists only for serialization
* compatibility with JDK 1.1. In Java platform 2 v1.2 and higher, the new
* <code>int</code> field <code>maximumFractionDigits</code> is used instead.
* When writing to a stream, <code>maxFractionDigits</code> is set to
* <code>maximumFractionDigits</code> or <code>Byte.MAX_VALUE</code>,
* whichever is smaller. When reading from a stream, this field is used
* only if <code>serialVersionOnStream</code> is less than 1.
*
* @serial
* @see #getMaximumFractionDigits
*/
private byte maxFractionDigits = 3; // invariant, >= minFractionDigits
/** {@collect.stats}
* The minimum number of digits allowed in the fractional portion of a
* number. <code>minimumFractionDigits</code> must be less than or equal to
* <code>maximumFractionDigits</code>.
* <p>
* <strong>Note:</strong> This field exists only for serialization
* compatibility with JDK 1.1. In Java platform 2 v1.2 and higher, the new
* <code>int</code> field <code>minimumFractionDigits</code> is used instead.
* When writing to a stream, <code>minFractionDigits</code> is set to
* <code>minimumFractionDigits</code> or <code>Byte.MAX_VALUE</code>,
* whichever is smaller. When reading from a stream, this field is used
* only if <code>serialVersionOnStream</code> is less than 1.
*
* @serial
* @see #getMinimumFractionDigits
*/
private byte minFractionDigits = 0;
/** {@collect.stats}
* True if this format will parse numbers as integers only.
*
* @serial
* @see #isParseIntegerOnly
*/
private boolean parseIntegerOnly = false;
// new fields for 1.2. byte is too small for integer digits.
/** {@collect.stats}
* The maximum number of digits allowed in the integer portion of a
* number. <code>maximumIntegerDigits</code> must be greater than or equal to
* <code>minimumIntegerDigits</code>.
*
* @serial
* @since 1.2
* @see #getMaximumIntegerDigits
*/
private int maximumIntegerDigits = 40;
/** {@collect.stats}
* The minimum number of digits allowed in the integer portion of a
* number. <code>minimumIntegerDigits</code> must be less than or equal to
* <code>maximumIntegerDigits</code>.
*
* @serial
* @since 1.2
* @see #getMinimumIntegerDigits
*/
private int minimumIntegerDigits = 1;
/** {@collect.stats}
* The maximum number of digits allowed in the fractional portion of a
* number. <code>maximumFractionDigits</code> must be greater than or equal to
* <code>minimumFractionDigits</code>.
*
* @serial
* @since 1.2
* @see #getMaximumFractionDigits
*/
private int maximumFractionDigits = 3; // invariant, >= minFractionDigits
/** {@collect.stats}
* The minimum number of digits allowed in the fractional portion of a
* number. <code>minimumFractionDigits</code> must be less than or equal to
* <code>maximumFractionDigits</code>.
*
* @serial
* @since 1.2
* @see #getMinimumFractionDigits
*/
private int minimumFractionDigits = 0;
static final int currentSerialVersion = 1;
/** {@collect.stats}
* Describes the version of <code>NumberFormat</code> present on the stream.
* Possible values are:
* <ul>
* <li><b>0</b> (or uninitialized): the JDK 1.1 version of the stream format.
* In this version, the <code>int</code> fields such as
* <code>maximumIntegerDigits</code> were not present, and the <code>byte</code>
* fields such as <code>maxIntegerDigits</code> are used instead.
*
* <li><b>1</b>: the 1.2 version of the stream format. The values of the
* <code>byte</code> fields such as <code>maxIntegerDigits</code> are ignored,
* and the <code>int</code> fields such as <code>maximumIntegerDigits</code>
* are used instead.
* </ul>
* When streaming out a <code>NumberFormat</code>, the most recent format
* (corresponding to the highest allowable <code>serialVersionOnStream</code>)
* is always written.
*
* @serial
* @since 1.2
*/
private int serialVersionOnStream = currentSerialVersion;
// Removed "implements Cloneable" clause. Needs to update serialization
// ID for backward compatibility.
static final long serialVersionUID = -2308460125733713944L;
//
// class for AttributedCharacterIterator attributes
//
/** {@collect.stats}
* Defines constants that are used as attribute keys in the
* <code>AttributedCharacterIterator</code> returned
* from <code>NumberFormat.formatToCharacterIterator</code> and as
* field identifiers in <code>FieldPosition</code>.
*
* @since 1.4
*/
public static class Field extends Format.Field {
// Proclaim serial compatibility with 1.4 FCS
private static final long serialVersionUID = 7494728892700160890L;
// table of all instances in this class, used by readResolve
private static final Map instanceMap = new HashMap(11);
/** {@collect.stats}
* Creates a Field instance with the specified
* name.
*
* @param name Name of the attribute
*/
protected Field(String name) {
super(name);
if (this.getClass() == NumberFormat.Field.class) {
instanceMap.put(name, this);
}
}
/** {@collect.stats}
* Resolves instances being deserialized to the predefined constants.
*
* @throws InvalidObjectException if the constant could not be resolved.
* @return resolved NumberFormat.Field constant
*/
protected Object readResolve() throws InvalidObjectException {
if (this.getClass() != NumberFormat.Field.class) {
throw new InvalidObjectException("subclass didn't correctly implement readResolve");
}
Object instance = instanceMap.get(getName());
if (instance != null) {
return instance;
} else {
throw new InvalidObjectException("unknown attribute name");
}
}
/** {@collect.stats}
* Constant identifying the integer field.
*/
public static final Field INTEGER = new Field("integer");
/** {@collect.stats}
* Constant identifying the fraction field.
*/
public static final Field FRACTION = new Field("fraction");
/** {@collect.stats}
* Constant identifying the exponent field.
*/
public static final Field EXPONENT = new Field("exponent");
/** {@collect.stats}
* Constant identifying the decimal separator field.
*/
public static final Field DECIMAL_SEPARATOR =
new Field("decimal separator");
/** {@collect.stats}
* Constant identifying the sign field.
*/
public static final Field SIGN = new Field("sign");
/** {@collect.stats}
* Constant identifying the grouping separator field.
*/
public static final Field GROUPING_SEPARATOR =
new Field("grouping separator");
/** {@collect.stats}
* Constant identifying the exponent symbol field.
*/
public static final Field EXPONENT_SYMBOL = new
Field("exponent symbol");
/** {@collect.stats}
* Constant identifying the percent field.
*/
public static final Field PERCENT = new Field("percent");
/** {@collect.stats}
* Constant identifying the permille field.
*/
public static final Field PERMILLE = new Field("per mille");
/** {@collect.stats}
* Constant identifying the currency field.
*/
public static final Field CURRENCY = new Field("currency");
/** {@collect.stats}
* Constant identifying the exponent sign field.
*/
public static final Field EXPONENT_SIGN = new Field("exponent sign");
}
/** {@collect.stats}
* Obtains a NumberFormat instance from a NumberFormatProvider implementation.
*/
private static class NumberFormatGetter
implements LocaleServiceProviderPool.LocalizedObjectGetter<NumberFormatProvider,
NumberFormat> {
private static final NumberFormatGetter INSTANCE = new NumberFormatGetter();
public NumberFormat getObject(NumberFormatProvider numberFormatProvider,
Locale locale,
String key,
Object... params) {
assert params.length == 1;
int choice = (Integer)params[0];
switch (choice) {
case NUMBERSTYLE:
return numberFormatProvider.getNumberInstance(locale);
case PERCENTSTYLE:
return numberFormatProvider.getPercentInstance(locale);
case CURRENCYSTYLE:
return numberFormatProvider.getCurrencyInstance(locale);
case INTEGERSTYLE:
return numberFormatProvider.getIntegerInstance(locale);
default:
assert false : choice;
}
return null;
}
}
}