/* * Copyright (c) 1996, 2024, 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. */ /* * (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.IOException; import java.io.InvalidObjectException; import java.io.ObjectInputStream; import java.io.ObjectStreamException; import java.time.format.DateTimeFormatter; import java.util.ArrayList; import java.util.Arrays; import java.util.Date; import java.util.List; import java.util.Locale; import java.util.Objects; /** * {@code MessageFormat} provides a means to produce concatenated * messages in a language-neutral way. Use this class to construct messages * displayed for end users. * *

* {@code MessageFormat} takes a set of objects, formats them, then * inserts the formatted strings into the pattern at the appropriate places. * *

* Note: * {@code MessageFormat} differs from the other {@code Format} * classes in that you create a {@code MessageFormat} object with one * of its constructors (not with a {@code getInstance} style factory * method). The factory methods aren't necessary because {@code MessageFormat} * itself doesn't implement locale specific behavior. Any locale specific * behavior is defined by the pattern that you provide as well as the * subformats used for inserted arguments. * *

Patterns and Their Interpretation

* * {@code MessageFormat} uses patterns of the following form: * 
 * MessageFormatPattern:
 *         String
 *         MessageFormatPattern FormatElement String
 *
 * FormatElement:
 *         { ArgumentIndex }
 *         { ArgumentIndex , FormatType }
 *         { ArgumentIndex , FormatType , FormatStyle }
 *
 * FormatType:
 *         number
 *         dtf_date
 *         dtf_time
 *         dtf_datetime
 *         pre-defined DateTimeFormatter(s)
 *         date
 *         time
 *         choice
 *         list
 *
 * FormatStyle:
 *         short
 *         medium
 *         long
 *         full
 *         integer
 *         currency
 *         percent
 *         compact_short
 *         compact_long
 *         or
 *         unit
 *         SubformatPattern
 *
* *

* The ArgumentIndex value is a non-negative integer written * using the digits {@code '0'} through {@code '9'}, and represents an index into the * {@code arguments} array passed to the {@code format} methods * or the result array returned by the {@code parse} methods. *

* The FormatType and FormatStyle values are used to create * a {@code Format} instance for the format element. The following * table shows how the values map to {@code Format} instances. These values * are case-insensitive when passed to {@link #applyPattern(String)}. Combinations * not shown in the table are illegal. A SubformatPattern must * be a valid pattern string for the {@code Format} subclass used. * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
Shows how FormatType and FormatStyle values map to Format instances
FormatType * FormatStyle * Subformat Created *
(none) * (none) * {@code null} *
{@code number} * (none) * {@link NumberFormat#getInstance(Locale) NumberFormat.getInstance}{@code (getLocale())} *
{@code integer} * {@link NumberFormat#getIntegerInstance(Locale) NumberFormat.getIntegerInstance}{@code (getLocale())} *
{@code currency} * {@link NumberFormat#getCurrencyInstance(Locale) NumberFormat.getCurrencyInstance}{@code (getLocale())} *
{@code percent} * {@link NumberFormat#getPercentInstance(Locale) NumberFormat.getPercentInstance}{@code (getLocale())} *
{@code compact_short} * {@link NumberFormat#getCompactNumberInstance(Locale, NumberFormat.Style) * NumberFormat.getCompactNumberInstance}{@code (getLocale(),} {@link NumberFormat.Style#SHORT}) *
{@code compact_long} * {@link NumberFormat#getCompactNumberInstance(Locale, NumberFormat.Style) * NumberFormat.getCompactNumberInstance}{@code (getLocale(),} {@link NumberFormat.Style#LONG}) *
SubformatPattern * {@code new} {@link DecimalFormat#DecimalFormat(String,DecimalFormatSymbols) * DecimalFormat}{@code (subformatPattern,} {@link DecimalFormatSymbols#getInstance(Locale) * DecimalFormatSymbols.getInstance}{@code (getLocale()))} *
{@code dtf_date} * (none) * {@link DateTimeFormatter#ofLocalizedDate(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDate(}{@link java.time.format.FormatStyle#MEDIUM}{@code ).withLocale(getLocale())} *
{@code short} * {@link DateTimeFormatter#ofLocalizedDate(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDate(}{@link java.time.format.FormatStyle#SHORT}{@code ).withLocale(getLocale())} *
{@code medium} * {@link DateTimeFormatter#ofLocalizedDate(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDate(}{@link java.time.format.FormatStyle#MEDIUM}{@code ).withLocale(getLocale())} *
{@code long} * {@link DateTimeFormatter#ofLocalizedDate(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDate(}{@link java.time.format.FormatStyle#LONG}{@code ).withLocale(getLocale())} *
{@code full} * {@link DateTimeFormatter#ofLocalizedDate(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDate(}{@link java.time.format.FormatStyle#FULL}{@code ).withLocale(getLocale())} *
SubformatPattern * {@link DateTimeFormatter#ofPattern(String, Locale) * DateTimeFormatter.ofPattern}{@code (subformatPattern, getLocale())} *
{@code dtf_time} * (none) * {@link DateTimeFormatter#ofLocalizedTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedTime(}{@link java.time.format.FormatStyle#MEDIUM}{@code ).withLocale(getLocale())} *
{@code short} * {@link DateTimeFormatter#ofLocalizedTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedTime(}{@link java.time.format.FormatStyle#SHORT}{@code ).withLocale(getLocale())} *
{@code medium} * {@link DateTimeFormatter#ofLocalizedTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedTime(}{@link java.time.format.FormatStyle#MEDIUM}{@code ).withLocale(getLocale())} *
{@code long} * {@link DateTimeFormatter#ofLocalizedTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedTime(}{@link java.time.format.FormatStyle#LONG}{@code ).withLocale(getLocale())} *
{@code full} * {@link DateTimeFormatter#ofLocalizedTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedTime(}{@link java.time.format.FormatStyle#FULL}{@code ).withLocale(getLocale())} *
SubformatPattern * {@link DateTimeFormatter#ofPattern(String, Locale) DateTimeFormatter.ofPattern}{@code (subformatPattern, getLocale())} *
{@code dtf_datetime} * (none) * {@link DateTimeFormatter#ofLocalizedDateTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDateTime(}{@link java.time.format.FormatStyle#MEDIUM}{@code ).withLocale(getLocale())} *
{@code short} * {@link DateTimeFormatter#ofLocalizedDateTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDateTime(}{@link java.time.format.FormatStyle#SHORT}{@code ).withLocale(getLocale())} *
{@code medium} * {@link DateTimeFormatter#ofLocalizedDateTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDateTime(}{@link java.time.format.FormatStyle#MEDIUM}{@code ).withLocale(getLocale())} *
{@code long} * {@link DateTimeFormatter#ofLocalizedDateTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDateTime(}{@link java.time.format.FormatStyle#LONG}{@code ).withLocale(getLocale())} *
{@code full} * {@link DateTimeFormatter#ofLocalizedDateTime(java.time.format.FormatStyle) * DateTimeFormatter.ofLocalizedDateTime(}{@link java.time.format.FormatStyle#FULL}{@code ).withLocale(getLocale())} *
SubformatPattern * {@link DateTimeFormatter#ofPattern(String, Locale) * DateTimeFormatter.ofPattern}{@code (subformatPattern, getLocale())} *
{@code pre-defined DateTimeFormatter(s)} * (none) * The {@code pre-defined DateTimeFormatter(s)} are used as a {@code FormatType} : * {@link DateTimeFormatter#BASIC_ISO_DATE BASIC_ISO_DATE}, * {@link DateTimeFormatter#ISO_LOCAL_DATE ISO_LOCAL_DATE}, * {@link DateTimeFormatter#ISO_OFFSET_DATE ISO_OFFSET_DATE}, * {@link DateTimeFormatter#ISO_DATE ISO_DATE}, * {@link DateTimeFormatter#ISO_LOCAL_TIME ISO_LOCAL_TIME}, * {@link DateTimeFormatter#ISO_OFFSET_TIME ISO_OFFSET_TIME}, * {@link DateTimeFormatter#ISO_TIME ISO_TIME}, * {@link DateTimeFormatter#ISO_LOCAL_DATE_TIME ISO_LOCAL_DATE_TIME}, * {@link DateTimeFormatter#ISO_OFFSET_DATE_TIME ISO_OFFSET_DATE_TIME}, * {@link DateTimeFormatter#ISO_ZONED_DATE_TIME ISO_ZONED_DATE_TIME}, * {@link DateTimeFormatter#ISO_DATE_TIME ISO_DATE_TIME}, * {@link DateTimeFormatter#ISO_ORDINAL_DATE ISO_ORDINAL_DATE}, * {@link DateTimeFormatter#ISO_WEEK_DATE ISO_WEEK_DATE}, * {@link DateTimeFormatter#ISO_INSTANT ISO_INSTANT}, * {@link DateTimeFormatter#RFC_1123_DATE_TIME RFC_1123_DATE_TIME} *
{@code date} * (none) * {@link DateFormat#getDateInstance(int,Locale) * DateFormat.getDateInstance}{@code (}{@link DateFormat#DEFAULT}{@code , getLocale())} *
{@code short} * {@link DateFormat#getDateInstance(int,Locale) * DateFormat.getDateInstance}{@code (}{@link DateFormat#SHORT}{@code , getLocale())} *
{@code medium} * {@link DateFormat#getDateInstance(int,Locale) * DateFormat.getDateInstance}{@code (}{@link DateFormat#MEDIUM}{@code , getLocale())} *
{@code long} * {@link DateFormat#getDateInstance(int,Locale) * DateFormat.getDateInstance}{@code (}{@link DateFormat#LONG}{@code , getLocale())} *
{@code full} * {@link DateFormat#getDateInstance(int,Locale) * DateFormat.getDateInstance}{@code (}{@link DateFormat#FULL}{@code , getLocale())} *
SubformatPattern * {@code new} {@link SimpleDateFormat#SimpleDateFormat(String,Locale) * SimpleDateFormat}{@code (subformatPattern, getLocale())} *
{@code time} * (none) * {@link DateFormat#getTimeInstance(int,Locale) * DateFormat.getTimeInstance}{@code (}{@link DateFormat#DEFAULT}{@code , getLocale())} *
{@code short} * {@link DateFormat#getTimeInstance(int,Locale) * DateFormat.getTimeInstance}{@code (}{@link DateFormat#SHORT}{@code , getLocale())} *
{@code medium} * {@link DateFormat#getTimeInstance(int,Locale) * DateFormat.getTimeInstance}{@code (}{@link DateFormat#MEDIUM}{@code , getLocale())} *
{@code long} * {@link DateFormat#getTimeInstance(int,Locale) * DateFormat.getTimeInstance}{@code (}{@link DateFormat#LONG}{@code , getLocale())} *
{@code full} * {@link DateFormat#getTimeInstance(int,Locale) * DateFormat.getTimeInstance}{@code (}{@link DateFormat#FULL}{@code , getLocale())} *
SubformatPattern * {@code new} {@link SimpleDateFormat#SimpleDateFormat(String,Locale) * SimpleDateFormat}{@code (subformatPattern, getLocale())} *
{@code choice} * SubformatPattern * {@code new} {@link ChoiceFormat#ChoiceFormat(String) ChoiceFormat}{@code (subformatPattern)} *
{@code list} * (none) * {@link ListFormat#getInstance(Locale, ListFormat.Type, ListFormat.Style) * ListFormat.getInstance}{@code (getLocale()}, {@link ListFormat.Type#STANDARD}, {@link ListFormat.Style#FULL}) *
{@code or} * {@link ListFormat#getInstance(Locale, ListFormat.Type, ListFormat.Style) * ListFormat.getInstance}{@code (getLocale()}, {@link ListFormat.Type#OR}, {@link ListFormat.Style#FULL}) *
{@code unit} * {@link ListFormat#getInstance(Locale, ListFormat.Type, ListFormat.Style) * ListFormat.getInstance}{@code (getLocale()}, {@link ListFormat.Type#UNIT}, {@link ListFormat.Style#FULL}} *
* *

Quoting Rules in Patterns

* *

Within a String, a pair of single quotes can be used to * quote any arbitrary characters except single quotes. For example, * pattern string "'{0}'" represents string * "{0}", not a FormatElement. A single quote itself * must be represented by doubled single quotes {@code ''} throughout a * String. For example, pattern string "'{''}'" is * interpreted as a sequence of '{ (start of quoting and a * left curly brace), {@code ''} (a single quote), and * }' (a right curly brace and end of quoting), * not '{' and '}' (quoted left and * right curly braces): representing string "{'}", * not "{}". * *

A SubformatPattern is interpreted by its corresponding * subformat, and subformat-dependent pattern rules apply. For example, * pattern string "{1,number,$'#',##}" * (SubformatPattern with underline) will produce a number format * with the pound-sign quoted, with a result such as: {@code * "$#31,45"}. Refer to each {@code Format} subclass documentation for * details. * *

Any unmatched quote is treated as closed at the end of the given * pattern. For example, pattern string {@code "'{0}"} is treated as * pattern {@code "'{0}'"}. * *

Any curly braces within an unquoted pattern must be balanced. For * example, "ab {0} de" and "ab '}' de" are * valid patterns, but "ab {0'}' de", "ab } de" * and "''{''" are not. * *

Warning:
The rules for using quotes within message * format patterns unfortunately have shown to be somewhat confusing. * In particular, it isn't always obvious to localizers whether single * quotes need to be doubled or not. Make sure to inform localizers about * the rules, and tell them (for example, by using comments in resource * bundle source files) which strings will be processed by {@code MessageFormat}. * Note that localizers may need to use single quotes in translated * strings where the original version doesn't have them. *
* *

Usage Information

* * * The following example demonstrates a general usage of {@code MessageFormat}. * In internationalized programs, the message format pattern and other * static strings will likely be obtained from resource bundles. * * {@snippet lang=java : * int planet = 7; * String event = "a disturbance in the Force"; * String result = MessageFormat.format( * "At {1,time} on {1,date}, there was {2} on planet {0,number,integer}.", * planet, new GregorianCalendar(2053, Calendar.JULY, 3, 12, 30).getTime(), event); * } * * {@code result} returns the following: * 
 * At 12:30:00 PM on Jul 3, 2053, there was a disturbance in the Force on planet 7.
 *
* *

* For more sophisticated patterns, {@link ChoiceFormat} can be used with * {@code MessageFormat} to produce accurate forms for singular and plural: * {@snippet lang=java : * MessageFormat msgFmt = new MessageFormat("The disk \"{0}\" contains {1,choice,0#no files|1#one file|1< {1,number,integer} files}."); * Object[] args = {"MyDisk", fileCount}; * String result = msgFmt.format(args); * } * * {@code result} with different values for {@code fileCount}, returns the following: * 

 * The disk "MyDisk" contains no files.
 * The disk "MyDisk" contains one file.
 * The disk "MyDisk" contains 1,273 files.
 *
* *

* Notes: As seen in the previous snippet, * the string produced by a {@code ChoiceFormat} in {@code MessageFormat} is * treated as special; occurrences of '{' are used to indicate subformats, and * cause recursion. If a {@code FormatElement} is defined in the {@code ChoiceFormat} * pattern, it will only be formatted according to the {@code FormatType} and * {@code FormatStyle} pattern provided. The associated subformats of the * top level {@code MessageFormat} will not be applied to the {@code FormatElement} * defined in the {@code ChoiceFormat} pattern. * If you create both a {@code MessageFormat} and {@code ChoiceFormat} * programmatically (instead of using the string patterns), then be careful not to * produce a format that recurses on itself, which will cause an infinite loop. * *

Formatting Date and Time

* * MessageFormat provides patterns that support the date/time formatters in the * {@link java.time.format} and {@link java.text} packages. Consider the following three examples, * with a date of 11/16/2023: * *

1) a date {@code FormatType} with a full {@code FormatStyle}, * {@snippet lang=java : * Object[] arg = {new GregorianCalendar(2023, Calendar.NOVEMBER, 16).getTime()}; * var fmt = new MessageFormat("The date was {0,date,full}"); * fmt.format(arg); // returns "The date was Thursday, November 16, 2023" * } * *

2) a dtf_date {@code FormatType} with a full {@code FormatStyle}, * {@snippet lang=java : * Object[] arg = {LocalDate.of(2023, 11, 16)}; * var fmt = new MessageFormat("The date was {0,dtf_date,full}"); * fmt.format(arg); // returns "The date was Thursday, November 16, 2023" * } * *

3) an ISO_LOCAL_DATE {@code FormatType}, * {@snippet lang=java : * Object[] arg = {LocalDate.of(2023, 11, 16)}; * var fmt = new MessageFormat("The date was {0,ISO_LOCAL_DATE}"); * fmt.format(arg); // returns "The date was 2023-11-16" * } * *

Parsing

*

* When a single argument is parsed more than once in the string, the last match * will be the final result of the parsing. For example, * {@snippet lang=java : * MessageFormat mf = new MessageFormat("{0,number,#.##}, {0,number,#.#}"); * Object[] objs = {Double.valueOf(3.1415)}; * String result = mf.format( objs ); * // result now equals "3.14, 3.1" * objs = mf.parse(result, new ParsePosition(0)); * // objs now equals {Double.valueOf(3.1)} * } * *

* Likewise, parsing with a {@code MessageFormat} object using patterns containing * multiple occurrences of the same argument would return the last match. For * example, * {@snippet lang=java : * MessageFormat mf = new MessageFormat("{0}, {0}, {0}"); * String forParsing = "x, y, z"; * Object[] objs = mf.parse(forParsing, new ParsePosition(0)); * // objs now equals {new String("z")} * } * *

Synchronization

* *

* Message formats are 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 java.util.Locale * @see Format * @see NumberFormat * @see DecimalFormat * @see DecimalFormatSymbols * @see ChoiceFormat * @see DateFormat * @see SimpleDateFormat * @see DateTimeFormatter * * @author Mark Davis * @since 1.1 */ public class MessageFormat extends Format { @java.io.Serial private static final long serialVersionUID = 6479157306784022952L; /** * Constructs a MessageFormat for the default * {@link java.util.Locale.Category#FORMAT FORMAT} locale and the * specified pattern. * The constructor first sets the locale, then parses the pattern and * creates a list of subformats for the format elements contained in it. * Patterns and their interpretation are specified in the * {@linkplain ##patterns class description}. * * @param pattern the pattern for this message format * @throws IllegalArgumentException if the pattern is invalid * @throws NullPointerException if {@code pattern} is * {@code null} */ public MessageFormat(String pattern) { this.locale = Locale.getDefault(Locale.Category.FORMAT); applyPatternImpl(pattern); } /** * Constructs a MessageFormat for the specified locale and * pattern. * The constructor first sets the locale, then parses the pattern and * creates a list of subformats for the format elements contained in it. * Patterns and their interpretation are specified in the * {@linkplain ##patterns class description}. * * @implSpec The default implementation throws a * {@code NullPointerException} if {@code locale} is {@code null} * either during the creation of the {@code MessageFormat} object or later * when {@code format()} is called by a {@code MessageFormat} * instance with a null locale and the implementation utilizes a * locale-dependent subformat. * * @param pattern the pattern for this message format * @param locale the locale for this message format * @throws IllegalArgumentException if the pattern is invalid * @throws NullPointerException if {@code pattern} is * {@code null} or {@code locale} is {@code null} and the * implementation uses a locale-dependent subformat. * @since 1.4 */ public MessageFormat(String pattern, Locale locale) { this.locale = locale; applyPatternImpl(pattern); } /** * Sets the locale to be used when creating or comparing subformats. * This affects subsequent calls *

* Subformats that have already been created are not affected. * * @param locale the locale to be used when creating or comparing subformats */ public void setLocale(Locale locale) { this.locale = locale; } /** * Gets the locale that's used when creating or comparing subformats. * * @return the locale used when creating or comparing subformats */ public Locale getLocale() { return locale; } /** * Sets the pattern used by this message format. * The method parses the pattern and creates a list of subformats * for the format elements contained in it. * Patterns and their interpretation are specified in the * {@linkplain ##patterns class description}. * * @param pattern the pattern for this message format * @throws IllegalArgumentException if the pattern is invalid * @throws NullPointerException if {@code pattern} is * {@code null} */ public void applyPattern(String pattern) { applyPatternImpl(pattern); } /** * Implementation of applying a pattern to this MessageFormat. * This method processes a String pattern in accordance with the MessageFormat * pattern syntax and sets the internal {@code pattern} variable as well as * populating the {@code formats} array with the subformats defined in the * pattern. See the {@linkplain ##patterns} section for further understanding * of certain special characters: "{", "}", ",". See {@linkplain * ##makeFormat(int, int, StringBuilder[])} for the implementation of setting * a subformat. */ @SuppressWarnings("fallthrough") // fallthrough in switch is expected, suppress it private void applyPatternImpl(String pattern) { StringBuilder[] segments = new StringBuilder[4]; // Allocate only segments[SEG_RAW] here. The rest are // allocated on demand. segments[SEG_RAW] = new StringBuilder(); int part = SEG_RAW; int formatNumber = 0; boolean inQuote = false; int braceStack = 0; maxOffset = -1; for (int i = 0; i < pattern.length(); ++i) { char ch = pattern.charAt(i); if (part == SEG_RAW) { if (ch == '\'') { if (i + 1 < pattern.length() && pattern.charAt(i+1) == '\'') { segments[part].append(ch); // handle doubles ++i; } else { inQuote = !inQuote; } } else if (ch == '{' && !inQuote) { part = SEG_INDEX; if (segments[SEG_INDEX] == null) { segments[SEG_INDEX] = new StringBuilder(); } } else { segments[part].append(ch); } } else { if (inQuote) { // just copy quotes in parts segments[part].append(ch); if (ch == '\'') { inQuote = false; } } else { switch (ch) { case ',': if (part < SEG_MODIFIER) { if (segments[++part] == null) { segments[part] = new StringBuilder(); } } else { segments[part].append(ch); } break; case '{': ++braceStack; segments[part].append(ch); break; case '}': if (braceStack == 0) { part = SEG_RAW; // Set the subformat setFormatFromPattern(i, formatNumber, segments); formatNumber++; // throw away other segments segments[SEG_INDEX] = null; segments[SEG_TYPE] = null; segments[SEG_MODIFIER] = null; } else { --braceStack; segments[part].append(ch); } break; case ' ': // Skip any leading space chars for SEG_TYPE. if (part != SEG_TYPE || segments[SEG_TYPE].length() > 0) { segments[part].append(ch); } break; case '\'': inQuote = true; // fall through, so we keep quotes in other parts default: segments[part].append(ch); break; } } } } if (braceStack == 0 && part != 0) { maxOffset = -1; throw new IllegalArgumentException("Unmatched braces in the pattern."); } this.pattern = segments[0].toString(); } /** * {@return a String pattern adhering to the {@link ##patterns patterns section} that * represents the current state of this {@code MessageFormat}} * * The string is constructed from internal information and therefore * does not necessarily equal the previously applied pattern. The order of * {@code FormatStyle} matching is not guaranteed. That is, a {@code * FormatStyle} produced may not be equivalent to the corresponding style passed, * in the instance that multiple styles are equivalent. * * @implSpec The implementation in {@link MessageFormat} returns a * string that, when passed to a {@code MessageFormat()} constructor * or {@link #applyPattern applyPattern()}, produces an instance that * is semantically equivalent to this instance. If a subformat cannot be * converted to a String pattern, the {@code FormatType} and {@code FormatStyle} * will be omitted from the {@code FormatElement}. */ public String toPattern() { // later, make this more extensible int lastOffset = 0; StringBuilder result = new StringBuilder(); for (int i = 0; i <= maxOffset; ++i) { copyAndFixQuotes(pattern, lastOffset, offsets[i], result); lastOffset = offsets[i]; result.append('{') .append(argumentNumbers[i]) .append(patternFromFormat(formats[i])) .append('}'); } copyAndFixQuotes(pattern, lastOffset, pattern.length(), result); return result.toString(); } /** * This method converts a Format into a {@code FormatType} and {@code * FormatStyle}, if applicable. For each Format, this method will * first check against the pre-defined styles established in the * {@link ##patterns patterns section}. Any "default"/"medium" styles * are omitted according to the specification. * If a Format does not match to a pre-defined style, it will provide the * {@code SubformatPattern}, if the Format class can provide one. The * following subformats do not provide a {@code SubformatPattern}: * CompactNumberFormat, ListFormat, and DateTimeFormatter (ClassicFormat). * *

In addition, since DateTimeFormatter and ClassicFormat do not implement {@code equals()}, * there is not a means to compare {@code fmt} to a ClassicFormat for equality, * and thus we don't have enough info to represent it as a pattern since there is no way to check * if {@code fmt} is equal to some, (for example, "long" style) pre-defined ClassicFormat. * Even if ClassicFormat implemented equals(), it is a wrapper class for * DateTimeFormatter, which would require DTF to implement equals() as well to effectively * compare the two ClassicFormats. */ private String patternFromFormat(Format fmt) { if (fmt instanceof NumberFormat nFmt) { // Check nFmt factory instances String nStyle = NumberFormat.matchToStyle(nFmt, locale); if (nStyle != null) { return ",number" + (nStyle.isEmpty() ? nStyle : "," + nStyle); } // Check SubformatPattern if (fmt instanceof DecimalFormat dFmt) { // Quote eligible mFmt pattern characters: '{' and '}' // Here, and in other subformatPattern instances return ",number," + copyAndQuoteBraces(dFmt.toPattern()); } else if (fmt instanceof ChoiceFormat cFmt) { return ",choice," + copyAndQuoteBraces(cFmt.toPattern()); } } else if (fmt instanceof DateFormat) { // Check dFmt factory instances for (DateFormat.Style style : DateFormat.Style.values()) { if (fmt.equals(DateFormat.getDateInstance(style.getValue(), locale))) { return ",date" + ((style.getValue() != DateFormat.DEFAULT) ? "," + style.name().toLowerCase(Locale.ROOT) : ""); } if (fmt.equals(DateFormat.getTimeInstance(style.getValue(), locale))) { return ",time" + ((style.getValue() != DateFormat.DEFAULT) ? "," + style.name().toLowerCase(Locale.ROOT) : ""); } } // Check SubformatPattern if (fmt instanceof SimpleDateFormat sdFmt) { return ",date," + copyAndQuoteBraces(sdFmt.toPattern()); } } else if (fmt instanceof ListFormat) { // Check lFmt factory instances for (ListFormat.Type type : ListFormat.Type.values()) { if (fmt.equals(ListFormat.getInstance(locale, type, ListFormat.Style.FULL))) { return ",list" + ((type != ListFormat.Type.STANDARD) ? "," + type.name().toLowerCase(Locale.ROOT) : ""); } } } // By here, this is an instanceof Format that is unknown to MessageFormat. // Since it is unknown, nothing can be done. return ""; } /** * Sets the formats to use for the values passed into * {@code format} methods or returned from {@code parse} * methods. The indices of elements in {@code newFormats} * correspond to the argument indices used in the previously set * pattern string. * The order of formats in {@code newFormats} thus corresponds to * the order of elements in the {@code arguments} array passed * to the {@code format} methods or the result array returned * by the {@code parse} methods. *

* If an argument index is used for more than one format element * in the pattern string, then the corresponding new format is used * for all such format elements. If an argument index is not used * for any format element in the pattern string, then the * corresponding new format is ignored. If fewer formats are provided * than needed, then only the formats for argument indices less * than {@code newFormats.length} are replaced. * * @param newFormats the new formats to use * @throws NullPointerException if {@code newFormats} is null * @since 1.4 */ public void setFormatsByArgumentIndex(Format[] newFormats) { for (int i = 0; i <= maxOffset; i++) { int j = argumentNumbers[i]; if (j < newFormats.length) { formats[i] = newFormats[j]; } } } /** * Sets the formats to use for the format elements in the * previously set pattern string. * The order of formats in {@code newFormats} corresponds to * the order of format elements in the pattern string. *

* If more formats are provided than needed by the pattern string, * the remaining ones are ignored. If fewer formats are provided * than needed, then only the first {@code newFormats.length} * formats are replaced. *

* Since the order of format elements in a pattern string often * changes during localization, it is generally better to use the * {@link #setFormatsByArgumentIndex setFormatsByArgumentIndex} * method, which assumes an order of formats corresponding to the * order of elements in the {@code arguments} array passed to * the {@code format} methods or the result array returned by * the {@code parse} methods. * * @param newFormats the new formats to use * @throws NullPointerException if {@code newFormats} is null */ public void setFormats(Format[] newFormats) { int runsToCopy = newFormats.length; if (runsToCopy > maxOffset + 1) { runsToCopy = maxOffset + 1; } if (runsToCopy >= 0) System.arraycopy(newFormats, 0, formats, 0, runsToCopy); } /** * Sets the format to use for the format elements within the * previously set pattern string that use the given argument * index. * The argument index is part of the format element definition and * represents an index into the {@code arguments} array passed * to the {@code format} methods or the result array returned * by the {@code parse} methods. *

* If the argument index is used for more than one format element * in the pattern string, then the new format is used for all such * format elements. If the argument index is not used for any format * element in the pattern string, then the new format is ignored. * * @param argumentIndex the argument index for which to use the new format * @param newFormat the new format to use * @since 1.4 */ public void setFormatByArgumentIndex(int argumentIndex, Format newFormat) { for (int j = 0; j <= maxOffset; j++) { if (argumentNumbers[j] == argumentIndex) { formats[j] = newFormat; } } } /** * Sets the format to use for the format element with the given * format element index within the previously set pattern string. * The format element index is the zero-based number of the format * element counting from the start of the pattern string. *

* Since the order of format elements in a pattern string often * changes during localization, it is generally better to use the * {@link #setFormatByArgumentIndex setFormatByArgumentIndex} * method, which accesses format elements based on the argument * index they specify. * * @param formatElementIndex the index of a format element within the pattern * @param newFormat the format to use for the specified format element * @throws ArrayIndexOutOfBoundsException if {@code formatElementIndex} is equal to or * larger than the number of format elements in the pattern string */ public void setFormat(int formatElementIndex, Format newFormat) { if (formatElementIndex > maxOffset) { throw new ArrayIndexOutOfBoundsException(formatElementIndex); } formats[formatElementIndex] = newFormat; } /** * Gets the formats used for the values passed into * {@code format} methods or returned from {@code parse} * methods. The indices of elements in the returned array * correspond to the argument indices used in the previously set * pattern string. * The order of formats in the returned array thus corresponds to * the order of elements in the {@code arguments} array passed * to the {@code format} methods or the result array returned * by the {@code parse} methods. *

* If an argument index is used for more than one format element * in the pattern string, then the format used for the last such * format element is returned in the array. If an argument index * is not used for any format element in the pattern string, then * null is returned in the array. * * @return the formats used for the arguments within the pattern * @since 1.4 */ public Format[] getFormatsByArgumentIndex() { int maximumArgumentNumber = -1; for (int i = 0; i <= maxOffset; i++) { if (argumentNumbers[i] > maximumArgumentNumber) { maximumArgumentNumber = argumentNumbers[i]; } } Format[] resultArray = new Format[maximumArgumentNumber + 1]; for (int i = 0; i <= maxOffset; i++) { resultArray[argumentNumbers[i]] = formats[i]; } return resultArray; } /** * Gets the formats used for the format elements in the * previously set pattern string. * The order of formats in the returned array corresponds to * the order of format elements in the pattern string. *

* Since the order of format elements in a pattern string often * changes during localization, it's generally better to use the * {@link #getFormatsByArgumentIndex getFormatsByArgumentIndex} * method, which assumes an order of formats corresponding to the * order of elements in the {@code arguments} array passed to * the {@code format} methods or the result array returned by * the {@code parse} methods. * * @return the formats used for the format elements in the pattern */ public Format[] getFormats() { Format[] resultArray = new Format[maxOffset + 1]; System.arraycopy(formats, 0, resultArray, 0, maxOffset + 1); return resultArray; } /** * Formats an array of objects and appends the {@code MessageFormat}'s * pattern, with format elements replaced by the formatted objects, to the * provided {@code StringBuffer}. *

* The text substituted for the individual format elements is derived from * the current subformat of the format element and the * {@code arguments} element at the format element's argument index * as indicated by the first matching line of the following table. An * argument is unavailable if {@code arguments} is * {@code null} or has fewer than argumentIndex+1 elements. * * * * * * * * * * * * * * * * *
Examples of subformat, argument, and formatted text
Subformat * Argument * Formatted Text *
any * unavailable * "{" + argumentIndex + "}" *
{@code null} * {@code "null"} *
{@code instanceof ChoiceFormat} * any * subformat.format(argument).indexOf('{') >= 0 ?
* (new MessageFormat(subformat.format(argument), getLocale())).format(argument) : * subformat.format(argument) *
{@code != null} * any * {@code subformat.format(argument)} *
{@code null} * {@code instanceof Number} * {@code NumberFormat.getInstance(getLocale()).format(argument)} *
{@code instanceof Date} * {@code DateFormat.getDateTimeInstance(DateFormat.SHORT, DateFormat.SHORT, getLocale()).format(argument)} *
{@code instanceof String} * {@code argument} *
any * {@code argument.toString()} *
*

* If {@code pos} is non-null, and refers to * {@code Field.ARGUMENT}, the location of the first formatted * string will be returned. * * @param arguments an array of objects to be formatted and substituted. * @param result where text is appended. * @param pos keeps track on the position of the first replaced argument * in the output string. * @return the string buffer passed in as {@code result}, with formatted * text appended * @throws IllegalArgumentException if an argument in the * {@code arguments} array is not of the type * expected by the format element(s) that use it. * @throws NullPointerException if {@code result} is {@code null} or * if the {@code MessageFormat} instance that calls this method * has locale set to null, and the implementation * uses a locale-dependent subformat. */ public final StringBuffer format(Object[] arguments, StringBuffer result, FieldPosition pos) { return subformat(arguments, StringBufFactory.of(result), pos, null).asStringBuffer(); } /** * Creates a MessageFormat with the given pattern and uses it * to format the given arguments. * This method returns a string that would be equal to the string returned by *

* (new {@link #MessageFormat(String) MessageFormat}(pattern)).{@link #format(java.lang.Object[], java.lang.StringBuffer, java.text.FieldPosition) format}(arguments, new StringBuffer(), null).toString() *
* * @param pattern the pattern string * @param arguments object(s) to format * @return the formatted string * @throws IllegalArgumentException if the pattern is invalid, * or if an argument in the {@code arguments} array * is not of the type expected by the format element(s) * that use it. * @throws NullPointerException if {@code pattern} is {@code null} */ public static String format(String pattern, Object ... arguments) { MessageFormat temp = new MessageFormat(pattern); return temp.format(arguments); } // Overrides /** * Formats an array of objects and appends the {@code MessageFormat}'s * pattern, with format elements replaced by the formatted objects, to the * provided {@code StringBuffer}. * This is equivalent to *
* {@link #format(java.lang.Object[], java.lang.StringBuffer, java.text.FieldPosition) format}((Object[]) arguments, result, pos) *
* * @param arguments an array of objects to be formatted and substituted. * @param result where text is appended. * @param pos keeps track on the position of the first replaced argument * in the output string. * @throws IllegalArgumentException if an argument in the * {@code arguments} array is not of the type * expected by the format element(s) that use it. * @throws NullPointerException if {@code result} is {@code null} or * if the {@code MessageFormat} instance that calls this method * has locale set to null, and the implementation * uses a locale-dependent subformat. */ public final StringBuffer format(Object arguments, StringBuffer result, FieldPosition pos) { return subformat((Object[]) arguments, StringBufFactory.of(result), pos, null).asStringBuffer(); } @Override final StringBuf format(Object arguments, StringBuf result, FieldPosition pos) { return subformat((Object[]) arguments, result, pos, null); } /** * Formats an array of objects and inserts them into the * {@code MessageFormat}'s pattern, producing an * {@code AttributedCharacterIterator}. * You can use the returned {@code AttributedCharacterIterator} * to build the resulting String, as well as to determine information * about the resulting String. *

* The text of the returned {@code AttributedCharacterIterator} is * the same that would be returned by *

* {@link #format(java.lang.Object[], java.lang.StringBuffer, java.text.FieldPosition) format}(arguments, new StringBuffer(), null).toString() *
*

* In addition, the {@code AttributedCharacterIterator} contains at * least attributes indicating where text was generated from an * argument in the {@code arguments} array. The keys of these attributes are of * type {@code MessageFormat.Field}, their values are * {@code Integer} objects indicating the index in the {@code arguments} * array of the argument from which the text was generated. *

* The attributes/value from the underlying {@code Format} * instances that {@code MessageFormat} uses will also be * placed in the resulting {@code AttributedCharacterIterator}. * This allows you to not only find where an argument is placed in the * resulting String, but also which fields it contains in turn. * * @param arguments an array of objects to be formatted and substituted. * @return AttributedCharacterIterator describing the formatted value. * @throws NullPointerException if {@code arguments} is null. * @throws IllegalArgumentException if an argument in the * {@code arguments} array is not of the type * expected by the format element(s) that use it. * @since 1.4 */ public AttributedCharacterIterator formatToCharacterIterator(Object arguments) { Objects.requireNonNull(arguments, "arguments must not be null"); StringBuf result = StringBufFactory.of(); ArrayList iterators = new ArrayList<>(); subformat((Object[]) arguments, result, null, iterators); if (iterators.size() == 0) { return createAttributedCharacterIterator(""); } return createAttributedCharacterIterator( iterators.toArray(new AttributedCharacterIterator[0])); } /** * Parses the string. * *

Caveats: The parse may fail in a number of circumstances. * For example: *

* When the parse fails, use ParsePosition.getErrorIndex() to find out * where in the string the parsing failed. The returned error * index is the starting offset of the sub-patterns that the string * is comparing with. For example, if the parsing string "AAA {0} BBB" * is comparing against the pattern "AAD {0} BBB", the error index is * 0. When an error occurs, the call to this method will return null. * If the source is null, return an empty array. * * @param source the string to parse * @param pos the parse position * @return an array of parsed objects * @throws NullPointerException if {@code pos} is {@code null} * for a non-null {@code source} string. */ public Object[] parse(String source, ParsePosition pos) { if (source == null) { Object[] empty = {}; return empty; } int maximumArgumentNumber = -1; for (int i = 0; i <= maxOffset; i++) { if (argumentNumbers[i] > maximumArgumentNumber) { maximumArgumentNumber = argumentNumbers[i]; } } // Constructors/applyPattern ensure that resultArray.length < MAX_ARGUMENT_INDEX Object[] resultArray = new Object[maximumArgumentNumber + 1]; int patternOffset = 0; int sourceOffset = pos.index; ParsePosition tempStatus = new ParsePosition(0); for (int i = 0; i <= maxOffset; ++i) { // match up to format int len = offsets[i] - patternOffset; if (len == 0 || pattern.regionMatches(patternOffset, source, sourceOffset, len)) { sourceOffset += len; patternOffset += len; } else { pos.errorIndex = sourceOffset; return null; // leave index as is to signal error } // now use format if (formats[i] == null) { // string format // if at end, use longest possible match // otherwise uses first match to intervening string // does NOT recursively try all possibilities int tempLength = (i != maxOffset) ? offsets[i+1] : pattern.length(); int next; if (patternOffset >= tempLength) { next = source.length(); }else{ next = source.indexOf(pattern.substring(patternOffset, tempLength), sourceOffset); } if (next < 0) { pos.errorIndex = sourceOffset; return null; // leave index as is to signal error } else { String strValue= source.substring(sourceOffset,next); if (!strValue.equals("{" + argumentNumbers[i] + "}")) resultArray[argumentNumbers[i]] = source.substring(sourceOffset,next); sourceOffset = next; } } else { tempStatus.index = sourceOffset; resultArray[argumentNumbers[i]] = formats[i].parseObject(source,tempStatus); if (tempStatus.index == sourceOffset) { pos.errorIndex = sourceOffset; return null; // leave index as is to signal error } sourceOffset = tempStatus.index; // update } } int len = pattern.length() - patternOffset; if (len == 0 || pattern.regionMatches(patternOffset, source, sourceOffset, len)) { pos.index = sourceOffset + len; } else { pos.errorIndex = sourceOffset; return null; // leave index as is to signal error } return resultArray; } /** * Parses text from the beginning of the given string to produce an object * array. * The method may not use the entire text of the given string. *

* See the {@link #parse(String, ParsePosition)} method for more information * on message parsing. * * @param source A {@code String} whose beginning should be parsed. * @return An {@code Object} array parsed from the string. * @throws ParseException if the beginning of the specified string * cannot be parsed. */ public Object[] parse(String source) throws ParseException { ParsePosition pos = new ParsePosition(0); Object[] result = parse(source, pos); if (pos.index == 0) // unchanged, returned object is null throw new ParseException("MessageFormat parse error!", pos.errorIndex); return result; } /** * Parses text from a string to produce an object array. *

* The method attempts to parse text starting at the index given by * {@code pos}. * If parsing succeeds, then the index of {@code 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 * object array is returned. The updated {@code pos} 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} is not * changed, the error index of {@code pos} is set to the index of * the character where the error occurred, and null is returned. *

* See the {@link #parse(String, ParsePosition)} method for more information * on message parsing. * * @param source A {@code String}, part of which should be parsed. * @param pos A {@code ParsePosition} object with index and error * index information as described above. * @return An {@code Object} array parsed from the string. In case of * error, returns null. * @throws NullPointerException if {@code pos} is null. */ public Object parseObject(String source, ParsePosition pos) { return parse(source, pos); } /** * Creates and returns a copy of this object. * * @return a clone of this instance. */ public Object clone() { MessageFormat other = (MessageFormat) super.clone(); // clone arrays. Can't do with utility because of bug in Cloneable other.formats = formats.clone(); // shallow clone for (int i = 0; i < formats.length; ++i) { if (formats[i] != null) other.formats[i] = (Format)formats[i].clone(); } // for primitives or immutables, shallow clone is enough other.offsets = offsets.clone(); other.argumentNumbers = argumentNumbers.clone(); return other; } /** * Compares the specified object with this {@code MessageFormat} for equality. * Returns true if the object is also a {@code MessageFormat} and the * two formats would format any value the same. * * @implSpec This method performs an equality check with a notion of class * identity based on {@code getClass()}, rather than {@code instanceof}. * Therefore, in the equals methods in subclasses, no instance of this class * should compare as equal to an instance of a subclass. * @param obj object to be compared for equality * @return {@code true} if the specified object is equal to this {@code MessageFormat} * @see Object#equals(Object) */ @Override public boolean equals(Object obj) { if (this == obj) // quick check return true; if (obj == null || getClass() != obj.getClass()) return false; MessageFormat other = (MessageFormat) obj; return (maxOffset == other.maxOffset && pattern.equals(other.pattern) && Objects.equals(locale,other.locale) && Arrays.equals(offsets,other.offsets) && Arrays.equals(argumentNumbers,other.argumentNumbers) && Arrays.equals(formats,other.formats)); } /** * {@return the hash code value for this {@code MessageFormat}} * * @implSpec This method calculates the hash code value using the value returned by * {@link #toPattern()}. * @see Object#hashCode() */ @Override public int hashCode() { return pattern.hashCode(); // enough for reasonable distribution } /** * {@return a string identifying this {@code MessageFormat}, for debugging} */ @Override public String toString() { return """ MessageFormat [locale: %s, pattern: "%s"] """.formatted(locale == null ? null : '"' + locale.getDisplayName() + '"', toPattern()); } /** * Defines constants that are used as attribute keys in the * {@code AttributedCharacterIterator} returned * from {@code MessageFormat.formatToCharacterIterator}. * * @since 1.4 */ public static class Field extends Format.Field { // Proclaim serial compatibility with 1.4 FCS @java.io.Serial private static final long serialVersionUID = 7899943957617360810L; /** * Creates a Field with the specified name. * * @param name Name of the attribute */ protected Field(String name) { super(name); } /** * Resolves instances being deserialized to the predefined constants. * * @throws InvalidObjectException if the constant could not be * resolved. * @return resolved MessageFormat.Field constant */ @java.io.Serial protected Object readResolve() throws InvalidObjectException { if (this.getClass() != MessageFormat.Field.class) { throw new InvalidObjectException("subclass didn't correctly implement readResolve"); } return ARGUMENT; } // // The constants // /** * Constant identifying a portion of a message that was generated * from an argument passed into {@code formatToCharacterIterator}. * The value associated with the key will be an {@code Integer} * indicating the index in the {@code arguments} array of the * argument from which the text was generated. */ public static final Field ARGUMENT = new Field("message argument field"); } // ===========================privates============================ /** * The locale to use for formatting numbers and dates. * @serial */ private Locale locale; /** * The string that the formatted values are to be plugged into. In other words, this * is the pattern supplied on construction with all of the {} expressions taken out. * @serial */ private String pattern = ""; /** The initially expected number of subformats in the format */ private static final int INITIAL_FORMATS = 10; /** * An array of formatters, which are used to format the arguments. * @serial */ private Format[] formats = new Format[INITIAL_FORMATS]; /** * The positions where the results of formatting each argument are to be inserted * into the pattern. * @serial */ private int[] offsets = new int[INITIAL_FORMATS]; /** * The argument numbers corresponding to each formatter. (The formatters are stored * in the order they occur in the pattern, not in the order in which the arguments * are specified.) * @serial */ private int[] argumentNumbers = new int[INITIAL_FORMATS]; // Implementation limit for ArgumentIndex pattern element. Valid indices must // be less than this value private static final int MAX_ARGUMENT_INDEX = 10000; /** * One less than the number of entries in {@code offsets}. Can also be thought of * as the index of the highest-numbered element in {@code offsets} that is being used. * All of these arrays should have the same number of elements being used as {@code offsets} * does, and so this variable suffices to tell us how many entries are in all of them. * @serial */ private int maxOffset = -1; /** * Internal routine used by format. If {@code characterIterators} is * {@code non-null}, AttributedCharacterIterator will be created from the * subformats as necessary. If {@code characterIterators} is {@code null} * and {@code fp} is {@code non-null} and identifies * {@code Field.ARGUMENT} as the field attribute, the location of * the first replaced argument will be set in it. * * @throws IllegalArgumentException if an argument in the * {@code arguments} array is not of the type * expected by the format element(s) that use it. */ private StringBuf subformat(Object[] arguments, StringBuf result, FieldPosition fp, List characterIterators) { // note: this implementation assumes a fast substring & index. // if this is not true, would be better to append chars one by one. int lastOffset = 0; int last = result.length(); for (int i = 0; i <= maxOffset; ++i) { result.append(pattern, lastOffset, offsets[i]); lastOffset = offsets[i]; int argumentNumber = argumentNumbers[i]; if (arguments == null || argumentNumber >= arguments.length) { result.append('{').append(argumentNumber).append('}'); continue; } // int argRecursion = ((recursionProtection >> (argumentNumber*2)) & 0x3); if (false) { // if (argRecursion == 3){ // prevent loop!!! result.append('\uFFFD'); } else { Object obj = arguments[argumentNumber]; String arg = null; Format subFormatter = null; if (obj == null) { arg = "null"; } else if (formats[i] != null) { subFormatter = formats[i]; if (subFormatter instanceof ChoiceFormat) { arg = formats[i].format(obj); if (arg.indexOf('{') >= 0) { subFormatter = new MessageFormat(arg, locale); obj = arguments; arg = null; } } } else if (obj instanceof Number) { // format number if can subFormatter = NumberFormat.getInstance(locale); } else if (obj instanceof Date) { // format a Date if can subFormatter = DateFormat.getDateTimeInstance( DateFormat.SHORT, DateFormat.SHORT, locale);//fix } else if (obj instanceof String) { arg = (String) obj; } else { arg = obj.toString(); if (arg == null) arg = "null"; } // At this point we are in two states, either subFormatter // is non-null indicating we should format obj using it, // or arg is non-null and we should use it as the value. if (characterIterators != null) { // If characterIterators is non-null, it indicates we need // to get the CharacterIterator from the child formatter. if (last != result.length()) { characterIterators.add( createAttributedCharacterIterator(result.substring (last))); last = result.length(); } if (subFormatter != null) { AttributedCharacterIterator subIterator = subFormatter.formatToCharacterIterator(obj); append(result, subIterator); if (last != result.length()) { characterIterators.add( createAttributedCharacterIterator( subIterator, Field.ARGUMENT, Integer.valueOf(argumentNumber))); last = result.length(); } arg = null; } if (arg != null && !arg.isEmpty()) { result.append(arg); characterIterators.add( createAttributedCharacterIterator( arg, Field.ARGUMENT, Integer.valueOf(argumentNumber))); last = result.length(); } } else { if (subFormatter != null) { arg = subFormatter.format(obj); } last = result.length(); result.append(arg); if (i == 0 && fp != null && Field.ARGUMENT.equals( fp.getFieldAttribute())) { fp.setBeginIndex(last); fp.setEndIndex(result.length()); } last = result.length(); } } } result.append(pattern, lastOffset, pattern.length()); if (characterIterators != null && last != result.length()) { characterIterators.add(createAttributedCharacterIterator( result.substring(last))); } return result; } /** * Convenience method to append all the characters in * {@code iterator} to the StringBuf {@code result}. */ private void append(StringBuf result, CharacterIterator iterator) { if (iterator.first() != CharacterIterator.DONE) { char aChar; result.append(iterator.first()); while ((aChar = iterator.next()) != CharacterIterator.DONE) { result.append(aChar); } } } // Indices for segments private static final int SEG_RAW = 0; // String in MessageFormatPattern private static final int SEG_INDEX = 1; // ArgumentIndex private static final int SEG_TYPE = 2; // FormatType private static final int SEG_MODIFIER = 3; // FormatStyle /** * This method sets a Format in the {@code formats} array for the * corresponding {@code argumentNumber} based on the pattern supplied. * If the pattern supplied does not contain a {@code FormatType}, null * is stored in the {@code formats} array. */ private void setFormatFromPattern(int position, int offsetNumber, StringBuilder[] textSegments) { // Convert any null values in textSegments to empty string String[] segments = new String[textSegments.length]; for (int i = 0; i < textSegments.length; i++) { StringBuilder oneseg = textSegments[i]; segments[i] = (oneseg != null) ? oneseg.toString() : ""; } // get the argument number int argumentNumber; try { argumentNumber = Integer.parseInt(segments[SEG_INDEX]); // always unlocalized! } catch (NumberFormatException e) { throw new IllegalArgumentException("can't parse argument number: " + segments[SEG_INDEX], e); } if (argumentNumber < 0) { throw new IllegalArgumentException("negative argument number: " + argumentNumber); } if (argumentNumber >= MAX_ARGUMENT_INDEX) { throw new IllegalArgumentException( argumentNumber + " exceeds the ArgumentIndex implementation limit"); } // resize format information arrays if necessary if (offsetNumber >= formats.length) { int newLength = formats.length * 2; Format[] newFormats = new Format[newLength]; int[] newOffsets = new int[newLength]; int[] newArgumentNumbers = new int[newLength]; System.arraycopy(formats, 0, newFormats, 0, maxOffset + 1); System.arraycopy(offsets, 0, newOffsets, 0, maxOffset + 1); System.arraycopy(argumentNumbers, 0, newArgumentNumbers, 0, maxOffset + 1); formats = newFormats; offsets = newOffsets; argumentNumbers = newArgumentNumbers; } int oldMaxOffset = maxOffset; maxOffset = offsetNumber; offsets[offsetNumber] = segments[SEG_RAW].length(); argumentNumbers[offsetNumber] = argumentNumber; // Only search for corresponding type/style if type is not empty if (!segments[SEG_TYPE].isEmpty()) { try { formats[offsetNumber] = formatFromPattern(segments[SEG_TYPE], segments[SEG_MODIFIER]); } catch (Exception e) { // Catch to reset maxOffset maxOffset = oldMaxOffset; throw e; } } else { // Type "" is allowed. e.g., "{0,}", "{0,,}", and "{0,,#}" // are treated as "{0}". formats[offsetNumber] = null; } } /** * This method converts a {@code FormatType} and {@code FormatStyle} to a * {@code Format} value. The String parameters are converted * to their corresponding enum values FormatType and FormatStyle which are used * to return a {@code Format}. See the patterns section in the class * description for further detail on a MessageFormat pattern. * * @param type the {@code FormatType} in {@code FormatElement} * @param style the {@code FormatStyle} in {@code FormatElement} * @return a Format that corresponds to the corresponding {@code formatType} * and {@code formatStyle} * @throws IllegalArgumentException if a Format cannot be produced from the * type and style provided */ private Format formatFromPattern(String type, String style) { // Get the type, if it's valid FormatType fType; try { fType = FormatType.valueOf(type.trim().toUpperCase(Locale.ROOT)); } catch (IllegalArgumentException iae) { // Invalid type throws exception throw new IllegalArgumentException("unknown format type: " + type); } // Get the style if recognized, otherwise treat style as a SubformatPattern FormatStyle fStyle; try { fStyle = FormatStyle.fromString(style); } catch (IllegalArgumentException iae) { fStyle = FormatStyle.SUBFORMATPATTERN; } return switch (fType) { case NUMBER -> switch (fStyle) { case DEFAULT -> NumberFormat.getInstance(locale); case CURRENCY -> NumberFormat.getCurrencyInstance(locale); case PERCENT -> NumberFormat.getPercentInstance(locale); case INTEGER -> NumberFormat.getIntegerInstance(locale); case COMPACT_SHORT -> NumberFormat.getCompactNumberInstance(locale, NumberFormat.Style.SHORT); case COMPACT_LONG -> NumberFormat.getCompactNumberInstance(locale, NumberFormat.Style.LONG); default -> formatFromSubformatPattern(fType, style); }; case DATE -> switch (fStyle) { case DEFAULT -> DateFormat.getDateInstance(DateFormat.DEFAULT, locale); case SHORT -> DateFormat.getDateInstance(DateFormat.SHORT, locale); case MEDIUM -> DateFormat.getDateInstance(DateFormat.MEDIUM, locale); case LONG -> DateFormat.getDateInstance(DateFormat.LONG, locale); case FULL -> DateFormat.getDateInstance(DateFormat.FULL, locale); default -> formatFromSubformatPattern(fType, style); }; case TIME -> switch (fStyle) { case DEFAULT -> DateFormat.getTimeInstance(DateFormat.DEFAULT, locale); case SHORT -> DateFormat.getTimeInstance(DateFormat.SHORT, locale); case MEDIUM -> DateFormat.getTimeInstance(DateFormat.MEDIUM, locale); case LONG -> DateFormat.getTimeInstance(DateFormat.LONG, locale); case FULL -> DateFormat.getTimeInstance(DateFormat.FULL, locale); default -> formatFromSubformatPattern(fType, style); }; case DTF_DATE -> switch (fStyle) { case DEFAULT, MEDIUM -> DateTimeFormatter.ofLocalizedDate(java.time.format.FormatStyle.MEDIUM).withLocale(locale).toFormat(); case SHORT -> DateTimeFormatter.ofLocalizedDate(java.time.format.FormatStyle.SHORT).withLocale(locale).toFormat(); case LONG -> DateTimeFormatter.ofLocalizedDate(java.time.format.FormatStyle.LONG).withLocale(locale).toFormat(); case FULL -> DateTimeFormatter.ofLocalizedDate(java.time.format.FormatStyle.FULL).withLocale(locale).toFormat(); default -> formatFromSubformatPattern(fType, style); }; case DTF_TIME -> switch (fStyle) { case DEFAULT, MEDIUM -> DateTimeFormatter.ofLocalizedTime(java.time.format.FormatStyle.MEDIUM).withLocale(locale).toFormat(); case SHORT -> DateTimeFormatter.ofLocalizedTime(java.time.format.FormatStyle.SHORT).withLocale(locale).toFormat(); case LONG -> DateTimeFormatter.ofLocalizedTime(java.time.format.FormatStyle.LONG).withLocale(locale).toFormat(); case FULL -> DateTimeFormatter.ofLocalizedTime(java.time.format.FormatStyle.FULL).withLocale(locale).toFormat(); default -> formatFromSubformatPattern(fType, style); }; case DTF_DATETIME -> switch (fStyle) { case DEFAULT, MEDIUM -> DateTimeFormatter.ofLocalizedDateTime(java.time.format.FormatStyle.MEDIUM).withLocale(locale).toFormat(); case SHORT -> DateTimeFormatter.ofLocalizedDateTime(java.time.format.FormatStyle.SHORT).withLocale(locale).toFormat(); case LONG -> DateTimeFormatter.ofLocalizedDateTime(java.time.format.FormatStyle.LONG).withLocale(locale).toFormat(); case FULL -> DateTimeFormatter.ofLocalizedDateTime(java.time.format.FormatStyle.FULL).withLocale(locale).toFormat(); default -> formatFromSubformatPattern(fType, style); }; case CHOICE -> formatFromSubformatPattern(fType, style); case LIST -> switch (fStyle) { case DEFAULT -> ListFormat.getInstance(locale, ListFormat.Type.STANDARD, ListFormat.Style.FULL); case OR -> ListFormat.getInstance(locale, ListFormat.Type.OR, ListFormat.Style.FULL); case UNIT -> ListFormat.getInstance(locale, ListFormat.Type.UNIT, ListFormat.Style.FULL); // ListFormat does not provide a String pattern method/constructor default -> formatFromSubformatPattern(fType, style); }; // The DateTimeFormatter constants are only given as a type // Regardless of style, return the corresponding DTF constant case BASIC_ISO_DATE -> DateTimeFormatter.BASIC_ISO_DATE.toFormat(); case ISO_LOCAL_DATE -> DateTimeFormatter.ISO_LOCAL_DATE.toFormat(); case ISO_OFFSET_DATE -> DateTimeFormatter.ISO_OFFSET_DATE.toFormat(); case ISO_DATE -> DateTimeFormatter.ISO_DATE.toFormat(); case ISO_LOCAL_TIME -> DateTimeFormatter.ISO_LOCAL_TIME.toFormat(); case ISO_OFFSET_TIME -> DateTimeFormatter.ISO_OFFSET_TIME.toFormat(); case ISO_TIME -> DateTimeFormatter.ISO_TIME.toFormat(); case ISO_LOCAL_DATE_TIME -> DateTimeFormatter.ISO_LOCAL_DATE_TIME.toFormat(); case ISO_OFFSET_DATE_TIME -> DateTimeFormatter.ISO_OFFSET_DATE_TIME.toFormat(); case ISO_ZONED_DATE_TIME -> DateTimeFormatter.ISO_ZONED_DATE_TIME.toFormat(); case ISO_DATE_TIME -> DateTimeFormatter.ISO_DATE_TIME.toFormat(); case ISO_ORDINAL_DATE -> DateTimeFormatter.ISO_ORDINAL_DATE.toFormat(); case ISO_WEEK_DATE -> DateTimeFormatter.ISO_WEEK_DATE.toFormat(); case ISO_INSTANT -> DateTimeFormatter.ISO_INSTANT.toFormat(); case RFC_1123_DATE_TIME -> DateTimeFormatter.RFC_1123_DATE_TIME.toFormat(); }; } /** * This method will attempt to return a subformat produced with the provided * SubformatPattern applied. If the subformat does not support SubformatPatterns * or the SubformatPattern is illegal to the subformat, an IllegalArgumentException * is thrown. To adhere to the specification, this method ensures if an underlying * exception is thrown, it is rethrown as an IllegalArgumentException unless * the underlying exception is itself an IAE, or an NPE. * * @param fType the enum type of the subformat * @param pattern the SubformatPattern to be applied * @return a Format that corresponds to the corresponding {@code fType} * and {@code pattern} * @throws IllegalArgumentException if a Format cannot be produced from the * type and SubformatPattern provided */ private Format formatFromSubformatPattern(FormatType fType, String pattern) { // Modified for neater exception value if needed String type = fType.name().charAt(0) + fType.name().substring(1).toLowerCase(Locale.ROOT); try { return switch (fType) { case NUMBER -> new DecimalFormat(pattern, DecimalFormatSymbols.getInstance(locale)); case DATE, TIME -> new SimpleDateFormat(pattern, locale); case DTF_DATE, DTF_TIME, DTF_DATETIME -> DateTimeFormatter.ofPattern(pattern).toFormat(); case CHOICE -> new ChoiceFormat(pattern); // These classe(s) do not support String patterns default -> throw new IllegalArgumentException(String.format( "Unexpected modifier for %s: %s", type, pattern)); }; } catch (Exception e) { // getClass check over separate catch block to not catch the IAE subclasses // For example, ChoiceFormat can throw a NumberFormatException if (e.getClass() == IllegalArgumentException.class || e.getClass() == NullPointerException.class) { // If IAE no need to wrap with another IAE // If NPE, it should be thrown as is (as specified) throw e; } else { throw new IllegalArgumentException(String.format( "%s pattern incorrect: %s", type, pattern), e); } } } private static void copyAndFixQuotes(String source, int start, int end, StringBuilder target) { boolean quoted = false; for (int i = start; i < end; ++i) { char ch = source.charAt(i); if (ch == '{') { if (!quoted) { target.append('\''); quoted = true; } target.append(ch); } else if (ch == '\'') { target.append("''"); } else { if (quoted) { target.append('\''); quoted = false; } target.append(ch); } } if (quoted) { target.append('\''); } } // The subformat pattern comes already quoted, but only for those characters that are // special to the subformat. Therefore, we may need to quote additional characters. // The ones we care about at the MessageFormat level are '{' and '}'. private static String copyAndQuoteBraces(String source) { // Analyze existing string for already quoted and newly quotable characters record Qchar(char ch, boolean quoted) { }; ArrayList qchars = new ArrayList<>(); boolean quoted = false; boolean anyChangeNeeded = false; StringBuilder quotedSource = new StringBuilder(); for (int i = 0; i < source.length(); i++) { char ch = source.charAt(i); if (ch == '\'') { if (i + 1 < source.length() && source.charAt(i + 1) == '\'') { qchars.add(new Qchar('\'', quoted)); i++; } else { quoted = !quoted; } } else { boolean quotable = ch == '{' || ch == '}'; anyChangeNeeded |= quotable && !quoted; qchars.add(new Qchar(ch, quoted || quotable)); } } // Was any change needed? if (!anyChangeNeeded) { return source; } // Build new string, automatically consolidating adjacent runs of quoted chars quoted = false; for (Qchar qchar : qchars) { char ch = qchar.ch; if (ch == '\'') { quotedSource.append(ch); // doubling works whether quoted or not } else if (qchar.quoted() != quoted) { quotedSource.append('\''); quoted = qchar.quoted(); } quotedSource.append(ch); } if (quoted) { quotedSource.append('\''); } return quotedSource.toString(); } // Corresponding to the FormatType pattern private enum FormatType { NUMBER, DATE, TIME, DTF_DATE, DTF_TIME, DTF_DATETIME, CHOICE, LIST, // Pre-defined DateTimeFormatter types BASIC_ISO_DATE, ISO_LOCAL_DATE, ISO_OFFSET_DATE , ISO_DATE, ISO_LOCAL_TIME, ISO_OFFSET_TIME, ISO_TIME, ISO_LOCAL_DATE_TIME, ISO_OFFSET_DATE_TIME, ISO_ZONED_DATE_TIME, ISO_DATE_TIME, ISO_ORDINAL_DATE, ISO_WEEK_DATE, ISO_INSTANT, RFC_1123_DATE_TIME; } // Corresponding to the FormatStyle pattern private enum FormatStyle { DEFAULT(""), SHORT("short"), MEDIUM("medium"), LONG("long"), FULL("full"), INTEGER("integer"), CURRENCY("currency"), PERCENT("percent"), COMPACT_SHORT("compact_short"), COMPACT_LONG("compact_long"), OR("or"), UNIT("unit"), SUBFORMATPATTERN(null); private final String text; // Differs from FormatType in that the text String is // not guaranteed to match the Enum name, thus a text field is used FormatStyle(String text) { this.text = text; } // This method returns a FormatStyle (excluding SUBFORMATPATTERN) // that matches the passed String. If no FormatStyle is found, // an IllegalArgumentException is thrown private static FormatStyle fromString(String text) { for (FormatStyle style : values()) { // Also check trimmed case-insensitive for historical reasons if (style != FormatStyle.SUBFORMATPATTERN && text.trim().compareToIgnoreCase(style.text) == 0) { return style; } } throw new IllegalArgumentException(); } } /** * After reading an object from the input stream, do a simple verification * to maintain class invariants. * @throws InvalidObjectException if the objects read from the stream is invalid. */ @java.io.Serial private void readObject(ObjectInputStream in) throws IOException, ClassNotFoundException { ObjectInputStream.GetField fields = in.readFields(); if (fields.defaulted("argumentNumbers") || fields.defaulted("offsets") || fields.defaulted("formats") || fields.defaulted("locale") || fields.defaulted("pattern") || fields.defaulted("maxOffset")){ throw new InvalidObjectException("Stream has missing data"); } locale = (Locale) fields.get("locale", null); String patt = (String) fields.get("pattern", null); int maxOff = fields.get("maxOffset", -2); int[] argNums = ((int[]) fields.get("argumentNumbers", null)).clone(); int[] offs = ((int[]) fields.get("offsets", null)).clone(); Format[] fmts = ((Format[]) fields.get("formats", null)).clone(); // Check arrays/maxOffset have correct value/length boolean isValid = maxOff >= -1 && argNums.length > maxOff && offs.length > maxOff && fmts.length > maxOff; // Check the correctness of arguments and offsets if (isValid) { int lastOffset = patt.length() + 1; for (int i = maxOff; i >= 0; --i) { if (argNums[i] < 0 || argNums[i] >= MAX_ARGUMENT_INDEX || offs[i] < 0 || offs[i] > lastOffset) { isValid = false; break; } else { lastOffset = offs[i]; } } } if (!isValid) { throw new InvalidObjectException("Stream has invalid data"); } maxOffset = maxOff; pattern = patt; offsets = offs; formats = fmts; argumentNumbers = argNums; } /** * Serialization without data not supported for this class. */ @java.io.Serial private void readObjectNoData() throws ObjectStreamException { throw new InvalidObjectException("Deserialized MessageFormat objects need data"); } }