1 /* 2 ******************************************************************************** 3 * Copyright (C) 1997-2015, International Business Machines 4 * Corporation and others. All Rights Reserved. 5 ******************************************************************************** 6 * 7 * File DECIMFMT.H 8 * 9 * Modification History: 10 * 11 * Date Name Description 12 * 02/19/97 aliu Converted from java. 13 * 03/20/97 clhuang Updated per C++ implementation. 14 * 04/03/97 aliu Rewrote parsing and formatting completely, and 15 * cleaned up and debugged. Actually works now. 16 * 04/17/97 aliu Changed DigitCount to int per code review. 17 * 07/10/97 helena Made ParsePosition a class and get rid of the function 18 * hiding problems. 19 * 09/09/97 aliu Ported over support for exponential formats. 20 * 07/20/98 stephen Changed documentation 21 * 01/30/13 emmons Added Scaling methods 22 ******************************************************************************** 23 */ 24 25 #ifndef DECIMFMT_H 26 #define DECIMFMT_H 27 28 #include "unicode/utypes.h" 29 /** 30 * \file 31 * \brief C++ API: Formats decimal numbers. 32 */ 33 34 #if !UCONFIG_NO_FORMATTING 35 36 #include "unicode/dcfmtsym.h" 37 #include "unicode/numfmt.h" 38 #include "unicode/locid.h" 39 #include "unicode/fpositer.h" 40 #include "unicode/stringpiece.h" 41 #include "unicode/curramt.h" 42 #include "unicode/enumset.h" 43 44 /** 45 * \def UNUM_DECIMALFORMAT_INTERNAL_SIZE 46 * @internal 47 */ 48 #if UCONFIG_FORMAT_FASTPATHS_49 49 #define UNUM_DECIMALFORMAT_INTERNAL_SIZE 16 50 #endif 51 52 U_NAMESPACE_BEGIN 53 54 class DigitList; 55 class ChoiceFormat; 56 class CurrencyPluralInfo; 57 class Hashtable; 58 class UnicodeSet; 59 class FieldPositionHandler; 60 class DecimalFormatStaticSets; 61 class FixedDecimal; 62 63 // explicit template instantiation. see digitlst.h 64 #if defined (_MSC_VER) 65 template class U_I18N_API EnumSet<UNumberFormatAttribute, 66 UNUM_MAX_NONBOOLEAN_ATTRIBUTE+1, 67 UNUM_LIMIT_BOOLEAN_ATTRIBUTE>; 68 #endif 69 70 /** 71 * DecimalFormat is a concrete subclass of NumberFormat that formats decimal 72 * numbers. It has a variety of features designed to make it possible to parse 73 * and format numbers in any locale, including support for Western, Arabic, or 74 * Indic digits. It also supports different flavors of numbers, including 75 * integers ("123"), fixed-point numbers ("123.4"), scientific notation 76 * ("1.23E4"), percentages ("12%"), and currency amounts ("$123", "USD123", 77 * "123 US dollars"). All of these flavors can be easily localized. 78 * 79 * <p>To obtain a NumberFormat for a specific locale (including the default 80 * locale) call one of NumberFormat's factory methods such as 81 * createInstance(). Do not call the DecimalFormat constructors directly, unless 82 * you know what you are doing, since the NumberFormat factory methods may 83 * return subclasses other than DecimalFormat. 84 * 85 * <p><strong>Example Usage</strong> 86 * 87 * \code 88 * // Normally we would have a GUI with a menu for this 89 * int32_t locCount; 90 * const Locale* locales = NumberFormat::getAvailableLocales(locCount); 91 * 92 * double myNumber = -1234.56; 93 * UErrorCode success = U_ZERO_ERROR; 94 * NumberFormat* form; 95 * 96 * // Print out a number with the localized number, currency and percent 97 * // format for each locale. 98 * UnicodeString countryName; 99 * UnicodeString displayName; 100 * UnicodeString str; 101 * UnicodeString pattern; 102 * Formattable fmtable; 103 * for (int32_t j = 0; j < 3; ++j) { 104 * cout << endl << "FORMAT " << j << endl; 105 * for (int32_t i = 0; i < locCount; ++i) { 106 * if (locales[i].getCountry(countryName).size() == 0) { 107 * // skip language-only 108 * continue; 109 * } 110 * switch (j) { 111 * case 0: 112 * form = NumberFormat::createInstance(locales[i], success ); break; 113 * case 1: 114 * form = NumberFormat::createCurrencyInstance(locales[i], success ); break; 115 * default: 116 * form = NumberFormat::createPercentInstance(locales[i], success ); break; 117 * } 118 * if (form) { 119 * str.remove(); 120 * pattern = ((DecimalFormat*)form)->toPattern(pattern); 121 * cout << locales[i].getDisplayName(displayName) << ": " << pattern; 122 * cout << " -> " << form->format(myNumber,str) << endl; 123 * form->parse(form->format(myNumber,str), fmtable, success); 124 * delete form; 125 * } 126 * } 127 * } 128 * \endcode 129 * <P> 130 * Another example use createInstance(style) 131 * <P> 132 * <pre> 133 * <strong>// Print out a number using the localized number, currency, 134 * // percent, scientific, integer, iso currency, and plural currency 135 * // format for each locale</strong> 136 * Locale* locale = new Locale("en", "US"); 137 * double myNumber = 1234.56; 138 * UErrorCode success = U_ZERO_ERROR; 139 * UnicodeString str; 140 * Formattable fmtable; 141 * for (int j=NumberFormat::kNumberStyle; 142 * j<=NumberFormat::kPluralCurrencyStyle; 143 * ++j) { 144 * NumberFormat* format = NumberFormat::createInstance(locale, j, success); 145 * str.remove(); 146 * cout << "format result " << form->format(myNumber, str) << endl; 147 * format->parse(form->format(myNumber, str), fmtable, success); 148 * }</pre> 149 * 150 * 151 * <p><strong>Patterns</strong> 152 * 153 * <p>A DecimalFormat consists of a <em>pattern</em> and a set of 154 * <em>symbols</em>. The pattern may be set directly using 155 * applyPattern(), or indirectly using other API methods which 156 * manipulate aspects of the pattern, such as the minimum number of integer 157 * digits. The symbols are stored in a DecimalFormatSymbols 158 * object. When using the NumberFormat factory methods, the 159 * pattern and symbols are read from ICU's locale data. 160 * 161 * <p><strong>Special Pattern Characters</strong> 162 * 163 * <p>Many characters in a pattern are taken literally; they are matched during 164 * parsing and output unchanged during formatting. Special characters, on the 165 * other hand, stand for other characters, strings, or classes of characters. 166 * For example, the '#' character is replaced by a localized digit. Often the 167 * replacement character is the same as the pattern character; in the U.S. locale, 168 * the ',' grouping character is replaced by ','. However, the replacement is 169 * still happening, and if the symbols are modified, the grouping character 170 * changes. Some special characters affect the behavior of the formatter by 171 * their presence; for example, if the percent character is seen, then the 172 * value is multiplied by 100 before being displayed. 173 * 174 * <p>To insert a special character in a pattern as a literal, that is, without 175 * any special meaning, the character must be quoted. There are some exceptions to 176 * this which are noted below. 177 * 178 * <p>The characters listed here are used in non-localized patterns. Localized 179 * patterns use the corresponding characters taken from this formatter's 180 * DecimalFormatSymbols object instead, and these characters lose 181 * their special status. Two exceptions are the currency sign and quote, which 182 * are not localized. 183 * 184 * <table border=0 cellspacing=3 cellpadding=0> 185 * <tr bgcolor="#ccccff"> 186 * <td align=left><strong>Symbol</strong> 187 * <td align=left><strong>Location</strong> 188 * <td align=left><strong>Localized?</strong> 189 * <td align=left><strong>Meaning</strong> 190 * <tr valign=top> 191 * <td><code>0</code> 192 * <td>Number 193 * <td>Yes 194 * <td>Digit 195 * <tr valign=top bgcolor="#eeeeff"> 196 * <td><code>1-9</code> 197 * <td>Number 198 * <td>Yes 199 * <td>'1' through '9' indicate rounding. 200 * <tr valign=top> 201 * <td><code>\htmlonly@\endhtmlonly</code> <!--doxygen doesn't like @--> 202 * <td>Number 203 * <td>No 204 * <td>Significant digit 205 * <tr valign=top bgcolor="#eeeeff"> 206 * <td><code>#</code> 207 * <td>Number 208 * <td>Yes 209 * <td>Digit, zero shows as absent 210 * <tr valign=top> 211 * <td><code>.</code> 212 * <td>Number 213 * <td>Yes 214 * <td>Decimal separator or monetary decimal separator 215 * <tr valign=top bgcolor="#eeeeff"> 216 * <td><code>-</code> 217 * <td>Number 218 * <td>Yes 219 * <td>Minus sign 220 * <tr valign=top> 221 * <td><code>,</code> 222 * <td>Number 223 * <td>Yes 224 * <td>Grouping separator 225 * <tr valign=top bgcolor="#eeeeff"> 226 * <td><code>E</code> 227 * <td>Number 228 * <td>Yes 229 * <td>Separates mantissa and exponent in scientific notation. 230 * <em>Need not be quoted in prefix or suffix.</em> 231 * <tr valign=top> 232 * <td><code>+</code> 233 * <td>Exponent 234 * <td>Yes 235 * <td>Prefix positive exponents with localized plus sign. 236 * <em>Need not be quoted in prefix or suffix.</em> 237 * <tr valign=top bgcolor="#eeeeff"> 238 * <td><code>;</code> 239 * <td>Subpattern boundary 240 * <td>Yes 241 * <td>Separates positive and negative subpatterns 242 * <tr valign=top> 243 * <td><code>\%</code> 244 * <td>Prefix or suffix 245 * <td>Yes 246 * <td>Multiply by 100 and show as percentage 247 * <tr valign=top bgcolor="#eeeeff"> 248 * <td><code>\\u2030</code> 249 * <td>Prefix or suffix 250 * <td>Yes 251 * <td>Multiply by 1000 and show as per mille 252 * <tr valign=top> 253 * <td><code>\htmlonly¤\endhtmlonly</code> (<code>\\u00A4</code>) 254 * <td>Prefix or suffix 255 * <td>No 256 * <td>Currency sign, replaced by currency symbol. If 257 * doubled, replaced by international currency symbol. 258 * If tripled, replaced by currency plural names, for example, 259 * "US dollar" or "US dollars" for America. 260 * If present in a pattern, the monetary decimal separator 261 * is used instead of the decimal separator. 262 * <tr valign=top bgcolor="#eeeeff"> 263 * <td><code>'</code> 264 * <td>Prefix or suffix 265 * <td>No 266 * <td>Used to quote special characters in a prefix or suffix, 267 * for example, <code>"'#'#"</code> formats 123 to 268 * <code>"#123"</code>. To create a single quote 269 * itself, use two in a row: <code>"# o''clock"</code>. 270 * <tr valign=top> 271 * <td><code>*</code> 272 * <td>Prefix or suffix boundary 273 * <td>Yes 274 * <td>Pad escape, precedes pad character 275 * </table> 276 * 277 * <p>A DecimalFormat pattern contains a postive and negative 278 * subpattern, for example, "#,##0.00;(#,##0.00)". Each subpattern has a 279 * prefix, a numeric part, and a suffix. If there is no explicit negative 280 * subpattern, the negative subpattern is the localized minus sign prefixed to the 281 * positive subpattern. That is, "0.00" alone is equivalent to "0.00;-0.00". If there 282 * is an explicit negative subpattern, it serves only to specify the negative 283 * prefix and suffix; the number of digits, minimal digits, and other 284 * characteristics are ignored in the negative subpattern. That means that 285 * "#,##0.0#;(#)" has precisely the same result as "#,##0.0#;(#,##0.0#)". 286 * 287 * <p>The prefixes, suffixes, and various symbols used for infinity, digits, 288 * thousands separators, decimal separators, etc. may be set to arbitrary 289 * values, and they will appear properly during formatting. However, care must 290 * be taken that the symbols and strings do not conflict, or parsing will be 291 * unreliable. For example, either the positive and negative prefixes or the 292 * suffixes must be distinct for parse() to be able 293 * to distinguish positive from negative values. Another example is that the 294 * decimal separator and thousands separator should be distinct characters, or 295 * parsing will be impossible. 296 * 297 * <p>The <em>grouping separator</em> is a character that separates clusters of 298 * integer digits to make large numbers more legible. It commonly used for 299 * thousands, but in some locales it separates ten-thousands. The <em>grouping 300 * size</em> is the number of digits between the grouping separators, such as 3 301 * for "100,000,000" or 4 for "1 0000 0000". There are actually two different 302 * grouping sizes: One used for the least significant integer digits, the 303 * <em>primary grouping size</em>, and one used for all others, the 304 * <em>secondary grouping size</em>. In most locales these are the same, but 305 * sometimes they are different. For example, if the primary grouping interval 306 * is 3, and the secondary is 2, then this corresponds to the pattern 307 * "#,##,##0", and the number 123456789 is formatted as "12,34,56,789". If a 308 * pattern contains multiple grouping separators, the interval between the last 309 * one and the end of the integer defines the primary grouping size, and the 310 * interval between the last two defines the secondary grouping size. All others 311 * are ignored, so "#,##,###,####" == "###,###,####" == "##,#,###,####". 312 * 313 * <p>Illegal patterns, such as "#.#.#" or "#.###,###", will cause 314 * DecimalFormat to set a failing UErrorCode. 315 * 316 * <p><strong>Pattern BNF</strong> 317 * 318 * <pre> 319 * pattern := subpattern (';' subpattern)? 320 * subpattern := prefix? number exponent? suffix? 321 * number := (integer ('.' fraction)?) | sigDigits 322 * prefix := '\\u0000'..'\\uFFFD' - specialCharacters 323 * suffix := '\\u0000'..'\\uFFFD' - specialCharacters 324 * integer := '#'* '0'* '0' 325 * fraction := '0'* '#'* 326 * sigDigits := '#'* '@' '@'* '#'* 327 * exponent := 'E' '+'? '0'* '0' 328 * padSpec := '*' padChar 329 * padChar := '\\u0000'..'\\uFFFD' - quote 330 * 331 * Notation: 332 * X* 0 or more instances of X 333 * X? 0 or 1 instances of X 334 * X|Y either X or Y 335 * C..D any character from C up to D, inclusive 336 * S-T characters in S, except those in T 337 * </pre> 338 * The first subpattern is for positive numbers. The second (optional) 339 * subpattern is for negative numbers. 340 * 341 * <p>Not indicated in the BNF syntax above: 342 * 343 * <ul><li>The grouping separator ',' can occur inside the integer and 344 * sigDigits elements, between any two pattern characters of that 345 * element, as long as the integer or sigDigits element is not 346 * followed by the exponent element. 347 * 348 * <li>Two grouping intervals are recognized: That between the 349 * decimal point and the first grouping symbol, and that 350 * between the first and second grouping symbols. These 351 * intervals are identical in most locales, but in some 352 * locales they differ. For example, the pattern 353 * "#,##,###" formats the number 123456789 as 354 * "12,34,56,789".</li> 355 * 356 * <li>The pad specifier <code>padSpec</code> may appear before the prefix, 357 * after the prefix, before the suffix, after the suffix, or not at all. 358 * 359 * <li>In place of '0', the digits '1' through '9' may be used to 360 * indicate a rounding increment. 361 * </ul> 362 * 363 * <p><strong>Parsing</strong> 364 * 365 * <p>DecimalFormat parses all Unicode characters that represent 366 * decimal digits, as defined by u_charDigitValue(). In addition, 367 * DecimalFormat also recognizes as digits the ten consecutive 368 * characters starting with the localized zero digit defined in the 369 * DecimalFormatSymbols object. During formatting, the 370 * DecimalFormatSymbols-based digits are output. 371 * 372 * <p>During parsing, grouping separators are ignored if in lenient mode; 373 * otherwise, if present, they must be in appropriate positions. 374 * 375 * <p>For currency parsing, the formatter is able to parse every currency 376 * style formats no matter which style the formatter is constructed with. 377 * For example, a formatter instance gotten from 378 * NumberFormat.getInstance(ULocale, NumberFormat.CURRENCYSTYLE) can parse 379 * formats such as "USD1.00" and "3.00 US dollars". 380 * 381 * <p>If parse(UnicodeString&,Formattable&,ParsePosition&) 382 * fails to parse a string, it leaves the parse position unchanged. 383 * The convenience method parse(UnicodeString&,Formattable&,UErrorCode&) 384 * indicates parse failure by setting a failing 385 * UErrorCode. 386 * 387 * <p><strong>Formatting</strong> 388 * 389 * <p>Formatting is guided by several parameters, all of which can be 390 * specified either using a pattern or using the API. The following 391 * description applies to formats that do not use <a href="#sci">scientific 392 * notation</a> or <a href="#sigdig">significant digits</a>. 393 * 394 * <ul><li>If the number of actual integer digits exceeds the 395 * <em>maximum integer digits</em>, then only the least significant 396 * digits are shown. For example, 1997 is formatted as "97" if the 397 * maximum integer digits is set to 2. 398 * 399 * <li>If the number of actual integer digits is less than the 400 * <em>minimum integer digits</em>, then leading zeros are added. For 401 * example, 1997 is formatted as "01997" if the minimum integer digits 402 * is set to 5. 403 * 404 * <li>If the number of actual fraction digits exceeds the <em>maximum 405 * fraction digits</em>, then rounding is performed to the 406 * maximum fraction digits. For example, 0.125 is formatted as "0.12" 407 * if the maximum fraction digits is 2. This behavior can be changed 408 * by specifying a rounding increment and/or a rounding mode. 409 * 410 * <li>If the number of actual fraction digits is less than the 411 * <em>minimum fraction digits</em>, then trailing zeros are added. 412 * For example, 0.125 is formatted as "0.1250" if the mimimum fraction 413 * digits is set to 4. 414 * 415 * <li>Trailing fractional zeros are not displayed if they occur 416 * <em>j</em> positions after the decimal, where <em>j</em> is less 417 * than the maximum fraction digits. For example, 0.10004 is 418 * formatted as "0.1" if the maximum fraction digits is four or less. 419 * </ul> 420 * 421 * <p><strong>Special Values</strong> 422 * 423 * <p><code>NaN</code> is represented as a single character, typically 424 * <code>\\uFFFD</code>. This character is determined by the 425 * DecimalFormatSymbols object. This is the only value for which 426 * the prefixes and suffixes are not used. 427 * 428 * <p>Infinity is represented as a single character, typically 429 * <code>\\u221E</code>, with the positive or negative prefixes and suffixes 430 * applied. The infinity character is determined by the 431 * DecimalFormatSymbols object. 432 * 433 * <a name="sci"><strong>Scientific Notation</strong></a> 434 * 435 * <p>Numbers in scientific notation are expressed as the product of a mantissa 436 * and a power of ten, for example, 1234 can be expressed as 1.234 x 10<sup>3</sup>. The 437 * mantissa is typically in the half-open interval [1.0, 10.0) or sometimes [0.0, 1.0), 438 * but it need not be. DecimalFormat supports arbitrary mantissas. 439 * DecimalFormat can be instructed to use scientific 440 * notation through the API or through the pattern. In a pattern, the exponent 441 * character immediately followed by one or more digit characters indicates 442 * scientific notation. Example: "0.###E0" formats the number 1234 as 443 * "1.234E3". 444 * 445 * <ul> 446 * <li>The number of digit characters after the exponent character gives the 447 * minimum exponent digit count. There is no maximum. Negative exponents are 448 * formatted using the localized minus sign, <em>not</em> the prefix and suffix 449 * from the pattern. This allows patterns such as "0.###E0 m/s". To prefix 450 * positive exponents with a localized plus sign, specify '+' between the 451 * exponent and the digits: "0.###E+0" will produce formats "1E+1", "1E+0", 452 * "1E-1", etc. (In localized patterns, use the localized plus sign rather than 453 * '+'.) 454 * 455 * <li>The minimum number of integer digits is achieved by adjusting the 456 * exponent. Example: 0.00123 formatted with "00.###E0" yields "12.3E-4". This 457 * only happens if there is no maximum number of integer digits. If there is a 458 * maximum, then the minimum number of integer digits is fixed at one. 459 * 460 * <li>The maximum number of integer digits, if present, specifies the exponent 461 * grouping. The most common use of this is to generate <em>engineering 462 * notation</em>, in which the exponent is a multiple of three, e.g., 463 * "##0.###E0". The number 12345 is formatted using "##0.####E0" as "12.345E3". 464 * 465 * <li>When using scientific notation, the formatter controls the 466 * digit counts using significant digits logic. The maximum number of 467 * significant digits limits the total number of integer and fraction 468 * digits that will be shown in the mantissa; it does not affect 469 * parsing. For example, 12345 formatted with "##0.##E0" is "12.3E3". 470 * See the section on significant digits for more details. 471 * 472 * <li>The number of significant digits shown is determined as 473 * follows: If areSignificantDigitsUsed() returns false, then the 474 * minimum number of significant digits shown is one, and the maximum 475 * number of significant digits shown is the sum of the <em>minimum 476 * integer</em> and <em>maximum fraction</em> digits, and is 477 * unaffected by the maximum integer digits. If this sum is zero, 478 * then all significant digits are shown. If 479 * areSignificantDigitsUsed() returns true, then the significant digit 480 * counts are specified by getMinimumSignificantDigits() and 481 * getMaximumSignificantDigits(). In this case, the number of 482 * integer digits is fixed at one, and there is no exponent grouping. 483 * 484 * <li>Exponential patterns may not contain grouping separators. 485 * </ul> 486 * 487 * <a name="sigdig"><strong>Significant Digits</strong></a> 488 * 489 * <code>DecimalFormat</code> has two ways of controlling how many 490 * digits are shows: (a) significant digits counts, or (b) integer and 491 * fraction digit counts. Integer and fraction digit counts are 492 * described above. When a formatter is using significant digits 493 * counts, the number of integer and fraction digits is not specified 494 * directly, and the formatter settings for these counts are ignored. 495 * Instead, the formatter uses however many integer and fraction 496 * digits are required to display the specified number of significant 497 * digits. Examples: 498 * 499 * <table border=0 cellspacing=3 cellpadding=0> 500 * <tr bgcolor="#ccccff"> 501 * <td align=left>Pattern 502 * <td align=left>Minimum significant digits 503 * <td align=left>Maximum significant digits 504 * <td align=left>Number 505 * <td align=left>Output of format() 506 * <tr valign=top> 507 * <td><code>\@\@\@</code> 508 * <td>3 509 * <td>3 510 * <td>12345 511 * <td><code>12300</code> 512 * <tr valign=top bgcolor="#eeeeff"> 513 * <td><code>\@\@\@</code> 514 * <td>3 515 * <td>3 516 * <td>0.12345 517 * <td><code>0.123</code> 518 * <tr valign=top> 519 * <td><code>\@\@##</code> 520 * <td>2 521 * <td>4 522 * <td>3.14159 523 * <td><code>3.142</code> 524 * <tr valign=top bgcolor="#eeeeff"> 525 * <td><code>\@\@##</code> 526 * <td>2 527 * <td>4 528 * <td>1.23004 529 * <td><code>1.23</code> 530 * </table> 531 * 532 * <ul> 533 * <li>Significant digit counts may be expressed using patterns that 534 * specify a minimum and maximum number of significant digits. These 535 * are indicated by the <code>'@'</code> and <code>'#'</code> 536 * characters. The minimum number of significant digits is the number 537 * of <code>'@'</code> characters. The maximum number of significant 538 * digits is the number of <code>'@'</code> characters plus the number 539 * of <code>'#'</code> characters following on the right. For 540 * example, the pattern <code>"@@@"</code> indicates exactly 3 541 * significant digits. The pattern <code>"@##"</code> indicates from 542 * 1 to 3 significant digits. Trailing zero digits to the right of 543 * the decimal separator are suppressed after the minimum number of 544 * significant digits have been shown. For example, the pattern 545 * <code>"@##"</code> formats the number 0.1203 as 546 * <code>"0.12"</code>. 547 * 548 * <li>If a pattern uses significant digits, it may not contain a 549 * decimal separator, nor the <code>'0'</code> pattern character. 550 * Patterns such as <code>"@00"</code> or <code>"@.###"</code> are 551 * disallowed. 552 * 553 * <li>Any number of <code>'#'</code> characters may be prepended to 554 * the left of the leftmost <code>'@'</code> character. These have no 555 * effect on the minimum and maximum significant digits counts, but 556 * may be used to position grouping separators. For example, 557 * <code>"#,#@#"</code> indicates a minimum of one significant digits, 558 * a maximum of two significant digits, and a grouping size of three. 559 * 560 * <li>In order to enable significant digits formatting, use a pattern 561 * containing the <code>'@'</code> pattern character. Alternatively, 562 * call setSignificantDigitsUsed(TRUE). 563 * 564 * <li>In order to disable significant digits formatting, use a 565 * pattern that does not contain the <code>'@'</code> pattern 566 * character. Alternatively, call setSignificantDigitsUsed(FALSE). 567 * 568 * <li>The number of significant digits has no effect on parsing. 569 * 570 * <li>Significant digits may be used together with exponential notation. Such 571 * patterns are equivalent to a normal exponential pattern with a minimum and 572 * maximum integer digit count of one, a minimum fraction digit count of 573 * <code>getMinimumSignificantDigits() - 1</code>, and a maximum fraction digit 574 * count of <code>getMaximumSignificantDigits() - 1</code>. For example, the 575 * pattern <code>"@@###E0"</code> is equivalent to <code>"0.0###E0"</code>. 576 * 577 * <li>If signficant digits are in use, then the integer and fraction 578 * digit counts, as set via the API, are ignored. If significant 579 * digits are not in use, then the signficant digit counts, as set via 580 * the API, are ignored. 581 * 582 * </ul> 583 * 584 * <p><strong>Padding</strong> 585 * 586 * <p>DecimalFormat supports padding the result of 587 * format() to a specific width. Padding may be specified either 588 * through the API or through the pattern syntax. In a pattern the pad escape 589 * character, followed by a single pad character, causes padding to be parsed 590 * and formatted. The pad escape character is '*' in unlocalized patterns, and 591 * can be localized using DecimalFormatSymbols::setSymbol() with a 592 * DecimalFormatSymbols::kPadEscapeSymbol 593 * selector. For example, <code>"$*x#,##0.00"</code> formats 123 to 594 * <code>"$xx123.00"</code>, and 1234 to <code>"$1,234.00"</code>. 595 * 596 * <ul> 597 * <li>When padding is in effect, the width of the positive subpattern, 598 * including prefix and suffix, determines the format width. For example, in 599 * the pattern <code>"* #0 o''clock"</code>, the format width is 10. 600 * 601 * <li>The width is counted in 16-bit code units (UChars). 602 * 603 * <li>Some parameters which usually do not matter have meaning when padding is 604 * used, because the pattern width is significant with padding. In the pattern 605 * "* ##,##,#,##0.##", the format width is 14. The initial characters "##,##," 606 * do not affect the grouping size or maximum integer digits, but they do affect 607 * the format width. 608 * 609 * <li>Padding may be inserted at one of four locations: before the prefix, 610 * after the prefix, before the suffix, or after the suffix. If padding is 611 * specified in any other location, applyPattern() 612 * sets a failing UErrorCode. If there is no prefix, 613 * before the prefix and after the prefix are equivalent, likewise for the 614 * suffix. 615 * 616 * <li>When specified in a pattern, the 32-bit code point immediately 617 * following the pad escape is the pad character. This may be any character, 618 * including a special pattern character. That is, the pad escape 619 * <em>escapes</em> the following character. If there is no character after 620 * the pad escape, then the pattern is illegal. 621 * 622 * </ul> 623 * 624 * <p><strong>Rounding</strong> 625 * 626 * <p>DecimalFormat supports rounding to a specific increment. For 627 * example, 1230 rounded to the nearest 50 is 1250. 1.234 rounded to the 628 * nearest 0.65 is 1.3. The rounding increment may be specified through the API 629 * or in a pattern. To specify a rounding increment in a pattern, include the 630 * increment in the pattern itself. "#,#50" specifies a rounding increment of 631 * 50. "#,##0.05" specifies a rounding increment of 0.05. 632 * 633 * <p>In the absense of an explicit rounding increment numbers are 634 * rounded to their formatted width. 635 * 636 * <ul> 637 * <li>Rounding only affects the string produced by formatting. It does 638 * not affect parsing or change any numerical values. 639 * 640 * <li>A <em>rounding mode</em> determines how values are rounded; see 641 * DecimalFormat::ERoundingMode. The default rounding mode is 642 * DecimalFormat::kRoundHalfEven. The rounding mode can only be set 643 * through the API; it can not be set with a pattern. 644 * 645 * <li>Some locales use rounding in their currency formats to reflect the 646 * smallest currency denomination. 647 * 648 * <li>In a pattern, digits '1' through '9' specify rounding, but otherwise 649 * behave identically to digit '0'. 650 * </ul> 651 * 652 * <p><strong>Synchronization</strong> 653 * 654 * <p>DecimalFormat objects are not synchronized. Multiple 655 * threads should not access one formatter concurrently. 656 * 657 * <p><strong>Subclassing</strong> 658 * 659 * <p><em>User subclasses are not supported.</em> While clients may write 660 * subclasses, such code will not necessarily work and will not be 661 * guaranteed to work stably from release to release. 662 */ 663 class U_I18N_API DecimalFormat: public NumberFormat { 664 public: 665 /** 666 * Rounding mode. 667 * @stable ICU 2.4 668 */ 669 enum ERoundingMode { 670 kRoundCeiling, /**< Round towards positive infinity */ 671 kRoundFloor, /**< Round towards negative infinity */ 672 kRoundDown, /**< Round towards zero */ 673 kRoundUp, /**< Round away from zero */ 674 kRoundHalfEven, /**< Round towards the nearest integer, or 675 towards the nearest even integer if equidistant */ 676 kRoundHalfDown, /**< Round towards the nearest integer, or 677 towards zero if equidistant */ 678 kRoundHalfUp, /**< Round towards the nearest integer, or 679 away from zero if equidistant */ 680 /** 681 * Return U_FORMAT_INEXACT_ERROR if number does not format exactly. 682 * @stable ICU 4.8 683 */ 684 kRoundUnnecessary 685 }; 686 687 /** 688 * Pad position. 689 * @stable ICU 2.4 690 */ 691 enum EPadPosition { 692 kPadBeforePrefix, 693 kPadAfterPrefix, 694 kPadBeforeSuffix, 695 kPadAfterSuffix 696 }; 697 698 /** 699 * Create a DecimalFormat using the default pattern and symbols 700 * for the default locale. This is a convenient way to obtain a 701 * DecimalFormat when internationalization is not the main concern. 702 * <P> 703 * To obtain standard formats for a given locale, use the factory methods 704 * on NumberFormat such as createInstance. These factories will 705 * return the most appropriate sub-class of NumberFormat for a given 706 * locale. 707 * @param status Output param set to success/failure code. If the 708 * pattern is invalid this will be set to a failure code. 709 * @stable ICU 2.0 710 */ 711 DecimalFormat(UErrorCode& status); 712 713 /** 714 * Create a DecimalFormat from the given pattern and the symbols 715 * for the default locale. This is a convenient way to obtain a 716 * DecimalFormat when internationalization is not the main concern. 717 * <P> 718 * To obtain standard formats for a given locale, use the factory methods 719 * on NumberFormat such as createInstance. These factories will 720 * return the most appropriate sub-class of NumberFormat for a given 721 * locale. 722 * @param pattern A non-localized pattern string. 723 * @param status Output param set to success/failure code. If the 724 * pattern is invalid this will be set to a failure code. 725 * @stable ICU 2.0 726 */ 727 DecimalFormat(const UnicodeString& pattern, 728 UErrorCode& status); 729 730 /** 731 * Create a DecimalFormat from the given pattern and symbols. 732 * Use this constructor when you need to completely customize the 733 * behavior of the format. 734 * <P> 735 * To obtain standard formats for a given 736 * locale, use the factory methods on NumberFormat such as 737 * createInstance or createCurrencyInstance. If you need only minor adjustments 738 * to a standard format, you can modify the format returned by 739 * a NumberFormat factory method. 740 * 741 * @param pattern a non-localized pattern string 742 * @param symbolsToAdopt the set of symbols to be used. The caller should not 743 * delete this object after making this call. 744 * @param status Output param set to success/failure code. If the 745 * pattern is invalid this will be set to a failure code. 746 * @stable ICU 2.0 747 */ 748 DecimalFormat( const UnicodeString& pattern, 749 DecimalFormatSymbols* symbolsToAdopt, 750 UErrorCode& status); 751 752 #ifndef U_HIDE_INTERNAL_API 753 /** 754 * This API is for ICU use only. 755 * Create a DecimalFormat from the given pattern, symbols, and style. 756 * 757 * @param pattern a non-localized pattern string 758 * @param symbolsToAdopt the set of symbols to be used. The caller should not 759 * delete this object after making this call. 760 * @param style style of decimal format 761 * @param status Output param set to success/failure code. If the 762 * pattern is invalid this will be set to a failure code. 763 * @internal 764 */ 765 DecimalFormat( const UnicodeString& pattern, 766 DecimalFormatSymbols* symbolsToAdopt, 767 UNumberFormatStyle style, 768 UErrorCode& status); 769 770 #if UCONFIG_HAVE_PARSEALLINPUT 771 /** 772 * @internal 773 */ 774 void setParseAllInput(UNumberFormatAttributeValue value); 775 #endif 776 777 #endif /* U_HIDE_INTERNAL_API */ 778 779 780 /** 781 * Set an integer attribute on this DecimalFormat. 782 * May return U_UNSUPPORTED_ERROR if this instance does not support 783 * the specified attribute. 784 * @param attr the attribute to set 785 * @param newvalue new value 786 * @param status the error type 787 * @return *this - for chaining (example: format.setAttribute(...).setAttribute(...) ) 788 * @stable ICU 51 789 */ 790 virtual DecimalFormat& setAttribute( UNumberFormatAttribute attr, 791 int32_t newvalue, 792 UErrorCode &status); 793 794 /** 795 * Get an integer 796 * May return U_UNSUPPORTED_ERROR if this instance does not support 797 * the specified attribute. 798 * @param attr the attribute to set 799 * @param status the error type 800 * @return the attribute value. Undefined if there is an error. 801 * @stable ICU 51 802 */ 803 virtual int32_t getAttribute( UNumberFormatAttribute attr, 804 UErrorCode &status) const; 805 806 807 /** 808 * Set whether or not grouping will be used in this format. 809 * @param newValue True, grouping will be used in this format. 810 * @see getGroupingUsed 811 * @stable ICU 53 812 */ 813 virtual void setGroupingUsed(UBool newValue); 814 815 /** 816 * Sets whether or not numbers should be parsed as integers only. 817 * @param value set True, this format will parse numbers as integers 818 * only. 819 * @see isParseIntegerOnly 820 * @stable ICU 53 821 */ 822 virtual void setParseIntegerOnly(UBool value); 823 824 /** 825 * Set a particular UDisplayContext value in the formatter, such as 826 * UDISPCTX_CAPITALIZATION_FOR_STANDALONE. 827 * @param value The UDisplayContext value to set. 828 * @param status Input/output status. If at entry this indicates a failure 829 * status, the function will do nothing; otherwise this will be 830 * updated with any new status from the function. 831 * @stable ICU 53 832 */ 833 virtual void setContext(UDisplayContext value, UErrorCode& status); 834 835 /** 836 * Create a DecimalFormat from the given pattern and symbols. 837 * Use this constructor when you need to completely customize the 838 * behavior of the format. 839 * <P> 840 * To obtain standard formats for a given 841 * locale, use the factory methods on NumberFormat such as 842 * createInstance or createCurrencyInstance. If you need only minor adjustments 843 * to a standard format, you can modify the format returned by 844 * a NumberFormat factory method. 845 * 846 * @param pattern a non-localized pattern string 847 * @param symbolsToAdopt the set of symbols to be used. The caller should not 848 * delete this object after making this call. 849 * @param parseError Output param to receive errors occured during parsing 850 * @param status Output param set to success/failure code. If the 851 * pattern is invalid this will be set to a failure code. 852 * @stable ICU 2.0 853 */ 854 DecimalFormat( const UnicodeString& pattern, 855 DecimalFormatSymbols* symbolsToAdopt, 856 UParseError& parseError, 857 UErrorCode& status); 858 /** 859 * Create a DecimalFormat from the given pattern and symbols. 860 * Use this constructor when you need to completely customize the 861 * behavior of the format. 862 * <P> 863 * To obtain standard formats for a given 864 * locale, use the factory methods on NumberFormat such as 865 * createInstance or createCurrencyInstance. If you need only minor adjustments 866 * to a standard format, you can modify the format returned by 867 * a NumberFormat factory method. 868 * 869 * @param pattern a non-localized pattern string 870 * @param symbols the set of symbols to be used 871 * @param status Output param set to success/failure code. If the 872 * pattern is invalid this will be set to a failure code. 873 * @stable ICU 2.0 874 */ 875 DecimalFormat( const UnicodeString& pattern, 876 const DecimalFormatSymbols& symbols, 877 UErrorCode& status); 878 879 /** 880 * Copy constructor. 881 * 882 * @param source the DecimalFormat object to be copied from. 883 * @stable ICU 2.0 884 */ 885 DecimalFormat(const DecimalFormat& source); 886 887 /** 888 * Assignment operator. 889 * 890 * @param rhs the DecimalFormat object to be copied. 891 * @stable ICU 2.0 892 */ 893 DecimalFormat& operator=(const DecimalFormat& rhs); 894 895 /** 896 * Destructor. 897 * @stable ICU 2.0 898 */ 899 virtual ~DecimalFormat(); 900 901 /** 902 * Clone this Format object polymorphically. The caller owns the 903 * result and should delete it when done. 904 * 905 * @return a polymorphic copy of this DecimalFormat. 906 * @stable ICU 2.0 907 */ 908 virtual Format* clone(void) const; 909 910 /** 911 * Return true if the given Format objects are semantically equal. 912 * Objects of different subclasses are considered unequal. 913 * 914 * @param other the object to be compared with. 915 * @return true if the given Format objects are semantically equal. 916 * @stable ICU 2.0 917 */ 918 virtual UBool operator==(const Format& other) const; 919 920 921 using NumberFormat::format; 922 923 /** 924 * Format a double or long number using base-10 representation. 925 * 926 * @param number The value to be formatted. 927 * @param appendTo Output parameter to receive result. 928 * Result is appended to existing contents. 929 * @param pos On input: an alignment field, if desired. 930 * On output: the offsets of the alignment field. 931 * @return Reference to 'appendTo' parameter. 932 * @stable ICU 2.0 933 */ 934 virtual UnicodeString& format(double number, 935 UnicodeString& appendTo, 936 FieldPosition& pos) const; 937 938 939 /** 940 * Format a double or long number using base-10 representation. 941 * 942 * @param number The value to be formatted. 943 * @param appendTo Output parameter to receive result. 944 * Result is appended to existing contents. 945 * @param pos On input: an alignment field, if desired. 946 * On output: the offsets of the alignment field. 947 * @param status 948 * @return Reference to 'appendTo' parameter. 949 * @internal 950 */ 951 virtual UnicodeString& format(double number, 952 UnicodeString& appendTo, 953 FieldPosition& pos, 954 UErrorCode &status) const; 955 956 /** 957 * Format a double or long number using base-10 representation. 958 * 959 * @param number The value to be formatted. 960 * @param appendTo Output parameter to receive result. 961 * Result is appended to existing contents. 962 * @param posIter On return, can be used to iterate over positions 963 * of fields generated by this format call. 964 * Can be NULL. 965 * @param status Output param filled with success/failure status. 966 * @return Reference to 'appendTo' parameter. 967 * @stable 4.4 968 */ 969 virtual UnicodeString& format(double number, 970 UnicodeString& appendTo, 971 FieldPositionIterator* posIter, 972 UErrorCode& status) const; 973 974 /** 975 * Format a long number using base-10 representation. 976 * 977 * @param number The value to be formatted. 978 * @param appendTo Output parameter to receive result. 979 * Result is appended to existing contents. 980 * @param pos On input: an alignment field, if desired. 981 * On output: the offsets of the alignment field. 982 * @return Reference to 'appendTo' parameter. 983 * @stable ICU 2.0 984 */ 985 virtual UnicodeString& format(int32_t number, 986 UnicodeString& appendTo, 987 FieldPosition& pos) const; 988 989 /** 990 * Format a long number using base-10 representation. 991 * 992 * @param number The value to be formatted. 993 * @param appendTo Output parameter to receive result. 994 * Result is appended to existing contents. 995 * @param pos On input: an alignment field, if desired. 996 * On output: the offsets of the alignment field. 997 * @return Reference to 'appendTo' parameter. 998 * @internal 999 */ 1000 virtual UnicodeString& format(int32_t number, 1001 UnicodeString& appendTo, 1002 FieldPosition& pos, 1003 UErrorCode &status) const; 1004 1005 /** 1006 * Format a long number using base-10 representation. 1007 * 1008 * @param number The value to be formatted. 1009 * @param appendTo Output parameter to receive result. 1010 * Result is appended to existing contents. 1011 * @param posIter On return, can be used to iterate over positions 1012 * of fields generated by this format call. 1013 * Can be NULL. 1014 * @param status Output param filled with success/failure status. 1015 * @return Reference to 'appendTo' parameter. 1016 * @stable 4.4 1017 */ 1018 virtual UnicodeString& format(int32_t number, 1019 UnicodeString& appendTo, 1020 FieldPositionIterator* posIter, 1021 UErrorCode& status) const; 1022 1023 /** 1024 * Format an int64 number using base-10 representation. 1025 * 1026 * @param number The value to be formatted. 1027 * @param appendTo Output parameter to receive result. 1028 * Result is appended to existing contents. 1029 * @param pos On input: an alignment field, if desired. 1030 * On output: the offsets of the alignment field. 1031 * @return Reference to 'appendTo' parameter. 1032 * @stable ICU 2.8 1033 */ 1034 virtual UnicodeString& format(int64_t number, 1035 UnicodeString& appendTo, 1036 FieldPosition& pos) const; 1037 1038 /** 1039 * Format an int64 number using base-10 representation. 1040 * 1041 * @param number The value to be formatted. 1042 * @param appendTo Output parameter to receive result. 1043 * Result is appended to existing contents. 1044 * @param pos On input: an alignment field, if desired. 1045 * On output: the offsets of the alignment field. 1046 * @return Reference to 'appendTo' parameter. 1047 * @internal 1048 */ 1049 virtual UnicodeString& format(int64_t number, 1050 UnicodeString& appendTo, 1051 FieldPosition& pos, 1052 UErrorCode &status) const; 1053 1054 /** 1055 * Format an int64 number using base-10 representation. 1056 * 1057 * @param number The value to be formatted. 1058 * @param appendTo Output parameter to receive result. 1059 * Result is appended to existing contents. 1060 * @param posIter On return, can be used to iterate over positions 1061 * of fields generated by this format call. 1062 * Can be NULL. 1063 * @param status Output param filled with success/failure status. 1064 * @return Reference to 'appendTo' parameter. 1065 * @stable 4.4 1066 */ 1067 virtual UnicodeString& format(int64_t number, 1068 UnicodeString& appendTo, 1069 FieldPositionIterator* posIter, 1070 UErrorCode& status) const; 1071 1072 /** 1073 * Format a decimal number. 1074 * The syntax of the unformatted number is a "numeric string" 1075 * as defined in the Decimal Arithmetic Specification, available at 1076 * http://speleotrove.com/decimal 1077 * 1078 * @param number The unformatted number, as a string. 1079 * @param appendTo Output parameter to receive result. 1080 * Result is appended to existing contents. 1081 * @param posIter On return, can be used to iterate over positions 1082 * of fields generated by this format call. 1083 * Can be NULL. 1084 * @param status Output param filled with success/failure status. 1085 * @return Reference to 'appendTo' parameter. 1086 * @stable 4.4 1087 */ 1088 virtual UnicodeString& format(const StringPiece &number, 1089 UnicodeString& appendTo, 1090 FieldPositionIterator* posIter, 1091 UErrorCode& status) const; 1092 1093 1094 /** 1095 * Format a decimal number. 1096 * The number is a DigitList wrapper onto a floating point decimal number. 1097 * The default implementation in NumberFormat converts the decimal number 1098 * to a double and formats that. 1099 * 1100 * @param number The number, a DigitList format Decimal Floating Point. 1101 * @param appendTo Output parameter to receive result. 1102 * Result is appended to existing contents. 1103 * @param posIter On return, can be used to iterate over positions 1104 * of fields generated by this format call. 1105 * @param status Output param filled with success/failure status. 1106 * @return Reference to 'appendTo' parameter. 1107 * @internal 1108 */ 1109 virtual UnicodeString& format(const DigitList &number, 1110 UnicodeString& appendTo, 1111 FieldPositionIterator* posIter, 1112 UErrorCode& status) const; 1113 1114 /** 1115 * Format a decimal number. 1116 * The number is a DigitList wrapper onto a floating point decimal number. 1117 * The default implementation in NumberFormat converts the decimal number 1118 * to a double and formats that. 1119 * 1120 * @param number The number, a DigitList format Decimal Floating Point. 1121 * @param appendTo Output parameter to receive result. 1122 * Result is appended to existing contents. 1123 * @param pos On input: an alignment field, if desired. 1124 * On output: the offsets of the alignment field. 1125 * @param status Output param filled with success/failure status. 1126 * @return Reference to 'appendTo' parameter. 1127 * @internal 1128 */ 1129 virtual UnicodeString& format(const DigitList &number, 1130 UnicodeString& appendTo, 1131 FieldPosition& pos, 1132 UErrorCode& status) const; 1133 1134 using NumberFormat::parse; 1135 1136 /** 1137 * Parse the given string using this object's choices. The method 1138 * does string comparisons to try to find an optimal match. 1139 * If no object can be parsed, index is unchanged, and NULL is 1140 * returned. The result is returned as the most parsimonious 1141 * type of Formattable that will accomodate all of the 1142 * necessary precision. For example, if the result is exactly 12, 1143 * it will be returned as a long. However, if it is 1.5, it will 1144 * be returned as a double. 1145 * 1146 * @param text The text to be parsed. 1147 * @param result Formattable to be set to the parse result. 1148 * If parse fails, return contents are undefined. 1149 * @param parsePosition The position to start parsing at on input. 1150 * On output, moved to after the last successfully 1151 * parse character. On parse failure, does not change. 1152 * @see Formattable 1153 * @stable ICU 2.0 1154 */ 1155 virtual void parse(const UnicodeString& text, 1156 Formattable& result, 1157 ParsePosition& parsePosition) const; 1158 1159 /** 1160 * Parses text from the given string as a currency amount. Unlike 1161 * the parse() method, this method will attempt to parse a generic 1162 * currency name, searching for a match of this object's locale's 1163 * currency display names, or for a 3-letter ISO currency code. 1164 * This method will fail if this format is not a currency format, 1165 * that is, if it does not contain the currency pattern symbol 1166 * (U+00A4) in its prefix or suffix. 1167 * 1168 * @param text the string to parse 1169 * @param pos input-output position; on input, the position within text 1170 * to match; must have 0 <= pos.getIndex() < text.length(); 1171 * on output, the position after the last matched character. 1172 * If the parse fails, the position in unchanged upon output. 1173 * @return if parse succeeds, a pointer to a newly-created CurrencyAmount 1174 * object (owned by the caller) containing information about 1175 * the parsed currency; if parse fails, this is NULL. 1176 * @stable ICU 49 1177 */ 1178 virtual CurrencyAmount* parseCurrency(const UnicodeString& text, 1179 ParsePosition& pos) const; 1180 1181 /** 1182 * Returns the decimal format symbols, which is generally not changed 1183 * by the programmer or user. 1184 * @return desired DecimalFormatSymbols 1185 * @see DecimalFormatSymbols 1186 * @stable ICU 2.0 1187 */ 1188 virtual const DecimalFormatSymbols* getDecimalFormatSymbols(void) const; 1189 1190 /** 1191 * Sets the decimal format symbols, which is generally not changed 1192 * by the programmer or user. 1193 * @param symbolsToAdopt DecimalFormatSymbols to be adopted. 1194 * @stable ICU 2.0 1195 */ 1196 virtual void adoptDecimalFormatSymbols(DecimalFormatSymbols* symbolsToAdopt); 1197 1198 /** 1199 * Sets the decimal format symbols, which is generally not changed 1200 * by the programmer or user. 1201 * @param symbols DecimalFormatSymbols. 1202 * @stable ICU 2.0 1203 */ 1204 virtual void setDecimalFormatSymbols(const DecimalFormatSymbols& symbols); 1205 1206 1207 /** 1208 * Returns the currency plural format information, 1209 * which is generally not changed by the programmer or user. 1210 * @return desired CurrencyPluralInfo 1211 * @stable ICU 4.2 1212 */ 1213 virtual const CurrencyPluralInfo* getCurrencyPluralInfo(void) const; 1214 1215 /** 1216 * Sets the currency plural format information, 1217 * which is generally not changed by the programmer or user. 1218 * @param toAdopt CurrencyPluralInfo to be adopted. 1219 * @stable ICU 4.2 1220 */ 1221 virtual void adoptCurrencyPluralInfo(CurrencyPluralInfo* toAdopt); 1222 1223 /** 1224 * Sets the currency plural format information, 1225 * which is generally not changed by the programmer or user. 1226 * @param info Currency Plural Info. 1227 * @stable ICU 4.2 1228 */ 1229 virtual void setCurrencyPluralInfo(const CurrencyPluralInfo& info); 1230 1231 1232 /** 1233 * Get the positive prefix. 1234 * 1235 * @param result Output param which will receive the positive prefix. 1236 * @return A reference to 'result'. 1237 * Examples: +123, $123, sFr123 1238 * @stable ICU 2.0 1239 */ 1240 UnicodeString& getPositivePrefix(UnicodeString& result) const; 1241 1242 /** 1243 * Set the positive prefix. 1244 * 1245 * @param newValue the new value of the the positive prefix to be set. 1246 * Examples: +123, $123, sFr123 1247 * @stable ICU 2.0 1248 */ 1249 virtual void setPositivePrefix(const UnicodeString& newValue); 1250 1251 /** 1252 * Get the negative prefix. 1253 * 1254 * @param result Output param which will receive the negative prefix. 1255 * @return A reference to 'result'. 1256 * Examples: -123, ($123) (with negative suffix), sFr-123 1257 * @stable ICU 2.0 1258 */ 1259 UnicodeString& getNegativePrefix(UnicodeString& result) const; 1260 1261 /** 1262 * Set the negative prefix. 1263 * 1264 * @param newValue the new value of the the negative prefix to be set. 1265 * Examples: -123, ($123) (with negative suffix), sFr-123 1266 * @stable ICU 2.0 1267 */ 1268 virtual void setNegativePrefix(const UnicodeString& newValue); 1269 1270 /** 1271 * Get the positive suffix. 1272 * 1273 * @param result Output param which will receive the positive suffix. 1274 * @return A reference to 'result'. 1275 * Example: 123% 1276 * @stable ICU 2.0 1277 */ 1278 UnicodeString& getPositiveSuffix(UnicodeString& result) const; 1279 1280 /** 1281 * Set the positive suffix. 1282 * 1283 * @param newValue the new value of the positive suffix to be set. 1284 * Example: 123% 1285 * @stable ICU 2.0 1286 */ 1287 virtual void setPositiveSuffix(const UnicodeString& newValue); 1288 1289 /** 1290 * Get the negative suffix. 1291 * 1292 * @param result Output param which will receive the negative suffix. 1293 * @return A reference to 'result'. 1294 * Examples: -123%, ($123) (with positive suffixes) 1295 * @stable ICU 2.0 1296 */ 1297 UnicodeString& getNegativeSuffix(UnicodeString& result) const; 1298 1299 /** 1300 * Set the negative suffix. 1301 * 1302 * @param newValue the new value of the negative suffix to be set. 1303 * Examples: 123% 1304 * @stable ICU 2.0 1305 */ 1306 virtual void setNegativeSuffix(const UnicodeString& newValue); 1307 1308 /** 1309 * Get the multiplier for use in percent, permill, etc. 1310 * For a percentage, set the suffixes to have "%" and the multiplier to be 100. 1311 * (For Arabic, use arabic percent symbol). 1312 * For a permill, set the suffixes to have "\\u2031" and the multiplier to be 1000. 1313 * 1314 * @return the multiplier for use in percent, permill, etc. 1315 * Examples: with 100, 1.23 -> "123", and "123" -> 1.23 1316 * @stable ICU 2.0 1317 */ 1318 int32_t getMultiplier(void) const; 1319 1320 /** 1321 * Set the multiplier for use in percent, permill, etc. 1322 * For a percentage, set the suffixes to have "%" and the multiplier to be 100. 1323 * (For Arabic, use arabic percent symbol). 1324 * For a permill, set the suffixes to have "\\u2031" and the multiplier to be 1000. 1325 * 1326 * @param newValue the new value of the multiplier for use in percent, permill, etc. 1327 * Examples: with 100, 1.23 -> "123", and "123" -> 1.23 1328 * @stable ICU 2.0 1329 */ 1330 virtual void setMultiplier(int32_t newValue); 1331 1332 /** 1333 * Get the rounding increment. 1334 * @return A positive rounding increment, or 0.0 if a custom rounding 1335 * increment is not in effect. 1336 * @see #setRoundingIncrement 1337 * @see #getRoundingMode 1338 * @see #setRoundingMode 1339 * @stable ICU 2.0 1340 */ 1341 virtual double getRoundingIncrement(void) const; 1342 1343 /** 1344 * Set the rounding increment. In the absence of a rounding increment, 1345 * numbers will be rounded to the number of digits displayed. 1346 * @param newValue A positive rounding increment, or 0.0 to 1347 * use the default rounding increment. 1348 * Negative increments are equivalent to 0.0. 1349 * @see #getRoundingIncrement 1350 * @see #getRoundingMode 1351 * @see #setRoundingMode 1352 * @stable ICU 2.0 1353 */ 1354 virtual void setRoundingIncrement(double newValue); 1355 1356 /** 1357 * Get the rounding mode. 1358 * @return A rounding mode 1359 * @see #setRoundingIncrement 1360 * @see #getRoundingIncrement 1361 * @see #setRoundingMode 1362 * @stable ICU 2.0 1363 */ 1364 virtual ERoundingMode getRoundingMode(void) const; 1365 1366 /** 1367 * Set the rounding mode. 1368 * @param roundingMode A rounding mode 1369 * @see #setRoundingIncrement 1370 * @see #getRoundingIncrement 1371 * @see #getRoundingMode 1372 * @stable ICU 2.0 1373 */ 1374 virtual void setRoundingMode(ERoundingMode roundingMode); 1375 1376 /** 1377 * Get the width to which the output of format() is padded. 1378 * The width is counted in 16-bit code units. 1379 * @return the format width, or zero if no padding is in effect 1380 * @see #setFormatWidth 1381 * @see #getPadCharacterString 1382 * @see #setPadCharacter 1383 * @see #getPadPosition 1384 * @see #setPadPosition 1385 * @stable ICU 2.0 1386 */ 1387 virtual int32_t getFormatWidth(void) const; 1388 1389 /** 1390 * Set the width to which the output of format() is padded. 1391 * The width is counted in 16-bit code units. 1392 * This method also controls whether padding is enabled. 1393 * @param width the width to which to pad the result of 1394 * format(), or zero to disable padding. A negative 1395 * width is equivalent to 0. 1396 * @see #getFormatWidth 1397 * @see #getPadCharacterString 1398 * @see #setPadCharacter 1399 * @see #getPadPosition 1400 * @see #setPadPosition 1401 * @stable ICU 2.0 1402 */ 1403 virtual void setFormatWidth(int32_t width); 1404 1405 /** 1406 * Get the pad character used to pad to the format width. The 1407 * default is ' '. 1408 * @return a string containing the pad character. This will always 1409 * have a length of one 32-bit code point. 1410 * @see #setFormatWidth 1411 * @see #getFormatWidth 1412 * @see #setPadCharacter 1413 * @see #getPadPosition 1414 * @see #setPadPosition 1415 * @stable ICU 2.0 1416 */ 1417 virtual UnicodeString getPadCharacterString() const; 1418 1419 /** 1420 * Set the character used to pad to the format width. If padding 1421 * is not enabled, then this will take effect if padding is later 1422 * enabled. 1423 * @param padChar a string containing the pad charcter. If the string 1424 * has length 0, then the pad characer is set to ' '. Otherwise 1425 * padChar.char32At(0) will be used as the pad character. 1426 * @see #setFormatWidth 1427 * @see #getFormatWidth 1428 * @see #getPadCharacterString 1429 * @see #getPadPosition 1430 * @see #setPadPosition 1431 * @stable ICU 2.0 1432 */ 1433 virtual void setPadCharacter(const UnicodeString &padChar); 1434 1435 /** 1436 * Get the position at which padding will take place. This is the location 1437 * at which padding will be inserted if the result of format() 1438 * is shorter than the format width. 1439 * @return the pad position, one of kPadBeforePrefix, 1440 * kPadAfterPrefix, kPadBeforeSuffix, or 1441 * kPadAfterSuffix. 1442 * @see #setFormatWidth 1443 * @see #getFormatWidth 1444 * @see #setPadCharacter 1445 * @see #getPadCharacterString 1446 * @see #setPadPosition 1447 * @see #EPadPosition 1448 * @stable ICU 2.0 1449 */ 1450 virtual EPadPosition getPadPosition(void) const; 1451 1452 /** 1453 * Set the position at which padding will take place. This is the location 1454 * at which padding will be inserted if the result of format() 1455 * is shorter than the format width. This has no effect unless padding is 1456 * enabled. 1457 * @param padPos the pad position, one of kPadBeforePrefix, 1458 * kPadAfterPrefix, kPadBeforeSuffix, or 1459 * kPadAfterSuffix. 1460 * @see #setFormatWidth 1461 * @see #getFormatWidth 1462 * @see #setPadCharacter 1463 * @see #getPadCharacterString 1464 * @see #getPadPosition 1465 * @see #EPadPosition 1466 * @stable ICU 2.0 1467 */ 1468 virtual void setPadPosition(EPadPosition padPos); 1469 1470 /** 1471 * Return whether or not scientific notation is used. 1472 * @return TRUE if this object formats and parses scientific notation 1473 * @see #setScientificNotation 1474 * @see #getMinimumExponentDigits 1475 * @see #setMinimumExponentDigits 1476 * @see #isExponentSignAlwaysShown 1477 * @see #setExponentSignAlwaysShown 1478 * @stable ICU 2.0 1479 */ 1480 virtual UBool isScientificNotation(void) const; 1481 1482 /** 1483 * Set whether or not scientific notation is used. When scientific notation 1484 * is used, the effective maximum number of integer digits is <= 8. If the 1485 * maximum number of integer digits is set to more than 8, the effective 1486 * maximum will be 1. This allows this call to generate a 'default' scientific 1487 * number format without additional changes. 1488 * @param useScientific TRUE if this object formats and parses scientific 1489 * notation 1490 * @see #isScientificNotation 1491 * @see #getMinimumExponentDigits 1492 * @see #setMinimumExponentDigits 1493 * @see #isExponentSignAlwaysShown 1494 * @see #setExponentSignAlwaysShown 1495 * @stable ICU 2.0 1496 */ 1497 virtual void setScientificNotation(UBool useScientific); 1498 1499 /** 1500 * Return the minimum exponent digits that will be shown. 1501 * @return the minimum exponent digits that will be shown 1502 * @see #setScientificNotation 1503 * @see #isScientificNotation 1504 * @see #setMinimumExponentDigits 1505 * @see #isExponentSignAlwaysShown 1506 * @see #setExponentSignAlwaysShown 1507 * @stable ICU 2.0 1508 */ 1509 virtual int8_t getMinimumExponentDigits(void) const; 1510 1511 /** 1512 * Set the minimum exponent digits that will be shown. This has no 1513 * effect unless scientific notation is in use. 1514 * @param minExpDig a value >= 1 indicating the fewest exponent digits 1515 * that will be shown. Values less than 1 will be treated as 1. 1516 * @see #setScientificNotation 1517 * @see #isScientificNotation 1518 * @see #getMinimumExponentDigits 1519 * @see #isExponentSignAlwaysShown 1520 * @see #setExponentSignAlwaysShown 1521 * @stable ICU 2.0 1522 */ 1523 virtual void setMinimumExponentDigits(int8_t minExpDig); 1524 1525 /** 1526 * Return whether the exponent sign is always shown. 1527 * @return TRUE if the exponent is always prefixed with either the 1528 * localized minus sign or the localized plus sign, false if only negative 1529 * exponents are prefixed with the localized minus sign. 1530 * @see #setScientificNotation 1531 * @see #isScientificNotation 1532 * @see #setMinimumExponentDigits 1533 * @see #getMinimumExponentDigits 1534 * @see #setExponentSignAlwaysShown 1535 * @stable ICU 2.0 1536 */ 1537 virtual UBool isExponentSignAlwaysShown(void) const; 1538 1539 /** 1540 * Set whether the exponent sign is always shown. This has no effect 1541 * unless scientific notation is in use. 1542 * @param expSignAlways TRUE if the exponent is always prefixed with either 1543 * the localized minus sign or the localized plus sign, false if only 1544 * negative exponents are prefixed with the localized minus sign. 1545 * @see #setScientificNotation 1546 * @see #isScientificNotation 1547 * @see #setMinimumExponentDigits 1548 * @see #getMinimumExponentDigits 1549 * @see #isExponentSignAlwaysShown 1550 * @stable ICU 2.0 1551 */ 1552 virtual void setExponentSignAlwaysShown(UBool expSignAlways); 1553 1554 /** 1555 * Return the grouping size. Grouping size is the number of digits between 1556 * grouping separators in the integer portion of a number. For example, 1557 * in the number "123,456.78", the grouping size is 3. 1558 * 1559 * @return the grouping size. 1560 * @see setGroupingSize 1561 * @see NumberFormat::isGroupingUsed 1562 * @see DecimalFormatSymbols::getGroupingSeparator 1563 * @stable ICU 2.0 1564 */ 1565 int32_t getGroupingSize(void) const; 1566 1567 /** 1568 * Set the grouping size. Grouping size is the number of digits between 1569 * grouping separators in the integer portion of a number. For example, 1570 * in the number "123,456.78", the grouping size is 3. 1571 * 1572 * @param newValue the new value of the grouping size. 1573 * @see getGroupingSize 1574 * @see NumberFormat::setGroupingUsed 1575 * @see DecimalFormatSymbols::setGroupingSeparator 1576 * @stable ICU 2.0 1577 */ 1578 virtual void setGroupingSize(int32_t newValue); 1579 1580 /** 1581 * Return the secondary grouping size. In some locales one 1582 * grouping interval is used for the least significant integer 1583 * digits (the primary grouping size), and another is used for all 1584 * others (the secondary grouping size). A formatter supporting a 1585 * secondary grouping size will return a positive integer unequal 1586 * to the primary grouping size returned by 1587 * getGroupingSize(). For example, if the primary 1588 * grouping size is 4, and the secondary grouping size is 2, then 1589 * the number 123456789 formats as "1,23,45,6789", and the pattern 1590 * appears as "#,##,###0". 1591 * @return the secondary grouping size, or a value less than 1592 * one if there is none 1593 * @see setSecondaryGroupingSize 1594 * @see NumberFormat::isGroupingUsed 1595 * @see DecimalFormatSymbols::getGroupingSeparator 1596 * @stable ICU 2.4 1597 */ 1598 int32_t getSecondaryGroupingSize(void) const; 1599 1600 /** 1601 * Set the secondary grouping size. If set to a value less than 1, 1602 * then secondary grouping is turned off, and the primary grouping 1603 * size is used for all intervals, not just the least significant. 1604 * 1605 * @param newValue the new value of the secondary grouping size. 1606 * @see getSecondaryGroupingSize 1607 * @see NumberFormat#setGroupingUsed 1608 * @see DecimalFormatSymbols::setGroupingSeparator 1609 * @stable ICU 2.4 1610 */ 1611 virtual void setSecondaryGroupingSize(int32_t newValue); 1612 1613 /** 1614 * Allows you to get the behavior of the decimal separator with integers. 1615 * (The decimal separator will always appear with decimals.) 1616 * 1617 * @return TRUE if the decimal separator always appear with decimals. 1618 * Example: Decimal ON: 12345 -> 12345.; OFF: 12345 -> 12345 1619 * @stable ICU 2.0 1620 */ 1621 UBool isDecimalSeparatorAlwaysShown(void) const; 1622 1623 /** 1624 * Allows you to set the behavior of the decimal separator with integers. 1625 * (The decimal separator will always appear with decimals.) 1626 * 1627 * @param newValue set TRUE if the decimal separator will always appear with decimals. 1628 * Example: Decimal ON: 12345 -> 12345.; OFF: 12345 -> 12345 1629 * @stable ICU 2.0 1630 */ 1631 virtual void setDecimalSeparatorAlwaysShown(UBool newValue); 1632 1633 #ifndef U_HIDE_DRAFT_API 1634 /** 1635 * Allows you to get the parse behavior of the pattern decimal mark. 1636 * 1637 * @return TRUE if input must contain a match to decimal mark in pattern 1638 * @draft ICU 54 1639 */ 1640 UBool isDecimalPatternMatchRequired(void) const; 1641 #endif /* U_HIDE_DRAFT_API */ 1642 1643 /** 1644 * Allows you to set the behavior of the pattern decimal mark. 1645 * 1646 * if TRUE, the input must have a decimal mark if one was specified in the pattern. When 1647 * FALSE the decimal mark may be omitted from the input. 1648 * 1649 * @param newValue set TRUE if input must contain a match to decimal mark in pattern 1650 * @draft ICU 54 1651 */ 1652 virtual void setDecimalPatternMatchRequired(UBool newValue); 1653 1654 1655 /** 1656 * Synthesizes a pattern string that represents the current state 1657 * of this Format object. 1658 * 1659 * @param result Output param which will receive the pattern. 1660 * Previous contents are deleted. 1661 * @return A reference to 'result'. 1662 * @see applyPattern 1663 * @stable ICU 2.0 1664 */ 1665 virtual UnicodeString& toPattern(UnicodeString& result) const; 1666 1667 /** 1668 * Synthesizes a localized pattern string that represents the current 1669 * state of this Format object. 1670 * 1671 * @param result Output param which will receive the localized pattern. 1672 * Previous contents are deleted. 1673 * @return A reference to 'result'. 1674 * @see applyPattern 1675 * @stable ICU 2.0 1676 */ 1677 virtual UnicodeString& toLocalizedPattern(UnicodeString& result) const; 1678 1679 /** 1680 * Apply the given pattern to this Format object. A pattern is a 1681 * short-hand specification for the various formatting properties. 1682 * These properties can also be changed individually through the 1683 * various setter methods. 1684 * <P> 1685 * There is no limit to integer digits are set 1686 * by this routine, since that is the typical end-user desire; 1687 * use setMaximumInteger if you want to set a real value. 1688 * For negative numbers, use a second pattern, separated by a semicolon 1689 * <pre> 1690 * . Example "#,#00.0#" -> 1,234.56 1691 * </pre> 1692 * This means a minimum of 2 integer digits, 1 fraction digit, and 1693 * a maximum of 2 fraction digits. 1694 * <pre> 1695 * . Example: "#,#00.0#;(#,#00.0#)" for negatives in parantheses. 1696 * </pre> 1697 * In negative patterns, the minimum and maximum counts are ignored; 1698 * these are presumed to be set in the positive pattern. 1699 * 1700 * @param pattern The pattern to be applied. 1701 * @param parseError Struct to recieve information on position 1702 * of error if an error is encountered 1703 * @param status Output param set to success/failure code on 1704 * exit. If the pattern is invalid, this will be 1705 * set to a failure result. 1706 * @stable ICU 2.0 1707 */ 1708 virtual void applyPattern(const UnicodeString& pattern, 1709 UParseError& parseError, 1710 UErrorCode& status); 1711 /** 1712 * Sets the pattern. 1713 * @param pattern The pattern to be applied. 1714 * @param status Output param set to success/failure code on 1715 * exit. If the pattern is invalid, this will be 1716 * set to a failure result. 1717 * @stable ICU 2.0 1718 */ 1719 virtual void applyPattern(const UnicodeString& pattern, 1720 UErrorCode& status); 1721 1722 /** 1723 * Apply the given pattern to this Format object. The pattern 1724 * is assumed to be in a localized notation. A pattern is a 1725 * short-hand specification for the various formatting properties. 1726 * These properties can also be changed individually through the 1727 * various setter methods. 1728 * <P> 1729 * There is no limit to integer digits are set 1730 * by this routine, since that is the typical end-user desire; 1731 * use setMaximumInteger if you want to set a real value. 1732 * For negative numbers, use a second pattern, separated by a semicolon 1733 * <pre> 1734 * . Example "#,#00.0#" -> 1,234.56 1735 * </pre> 1736 * This means a minimum of 2 integer digits, 1 fraction digit, and 1737 * a maximum of 2 fraction digits. 1738 * 1739 * Example: "#,#00.0#;(#,#00.0#)" for negatives in parantheses. 1740 * 1741 * In negative patterns, the minimum and maximum counts are ignored; 1742 * these are presumed to be set in the positive pattern. 1743 * 1744 * @param pattern The localized pattern to be applied. 1745 * @param parseError Struct to recieve information on position 1746 * of error if an error is encountered 1747 * @param status Output param set to success/failure code on 1748 * exit. If the pattern is invalid, this will be 1749 * set to a failure result. 1750 * @stable ICU 2.0 1751 */ 1752 virtual void applyLocalizedPattern(const UnicodeString& pattern, 1753 UParseError& parseError, 1754 UErrorCode& status); 1755 1756 /** 1757 * Apply the given pattern to this Format object. 1758 * 1759 * @param pattern The localized pattern to be applied. 1760 * @param status Output param set to success/failure code on 1761 * exit. If the pattern is invalid, this will be 1762 * set to a failure result. 1763 * @stable ICU 2.0 1764 */ 1765 virtual void applyLocalizedPattern(const UnicodeString& pattern, 1766 UErrorCode& status); 1767 1768 1769 /** 1770 * Sets the maximum number of digits allowed in the integer portion of a 1771 * number. This override limits the integer digit count to 309. 1772 * 1773 * @param newValue the new value of the maximum number of digits 1774 * allowed in the integer portion of a number. 1775 * @see NumberFormat#setMaximumIntegerDigits 1776 * @stable ICU 2.0 1777 */ 1778 virtual void setMaximumIntegerDigits(int32_t newValue); 1779 1780 /** 1781 * Sets the minimum number of digits allowed in the integer portion of a 1782 * number. This override limits the integer digit count to 309. 1783 * 1784 * @param newValue the new value of the minimum number of digits 1785 * allowed in the integer portion of a number. 1786 * @see NumberFormat#setMinimumIntegerDigits 1787 * @stable ICU 2.0 1788 */ 1789 virtual void setMinimumIntegerDigits(int32_t newValue); 1790 1791 /** 1792 * Sets the maximum number of digits allowed in the fraction portion of a 1793 * number. This override limits the fraction digit count to 340. 1794 * 1795 * @param newValue the new value of the maximum number of digits 1796 * allowed in the fraction portion of a number. 1797 * @see NumberFormat#setMaximumFractionDigits 1798 * @stable ICU 2.0 1799 */ 1800 virtual void setMaximumFractionDigits(int32_t newValue); 1801 1802 /** 1803 * Sets the minimum number of digits allowed in the fraction portion of a 1804 * number. This override limits the fraction digit count to 340. 1805 * 1806 * @param newValue the new value of the minimum number of digits 1807 * allowed in the fraction portion of a number. 1808 * @see NumberFormat#setMinimumFractionDigits 1809 * @stable ICU 2.0 1810 */ 1811 virtual void setMinimumFractionDigits(int32_t newValue); 1812 1813 /** 1814 * Returns the minimum number of significant digits that will be 1815 * displayed. This value has no effect unless areSignificantDigitsUsed() 1816 * returns true. 1817 * @return the fewest significant digits that will be shown 1818 * @stable ICU 3.0 1819 */ 1820 int32_t getMinimumSignificantDigits() const; 1821 1822 /** 1823 * Returns the maximum number of significant digits that will be 1824 * displayed. This value has no effect unless areSignificantDigitsUsed() 1825 * returns true. 1826 * @return the most significant digits that will be shown 1827 * @stable ICU 3.0 1828 */ 1829 int32_t getMaximumSignificantDigits() const; 1830 1831 /** 1832 * Sets the minimum number of significant digits that will be 1833 * displayed. If <code>min</code> is less than one then it is set 1834 * to one. If the maximum significant digits count is less than 1835 * <code>min</code>, then it is set to <code>min</code>. 1836 * This function also enables the use of significant digits 1837 * by this formatter - areSignificantDigitsUsed() will return TRUE. 1838 * @see #areSignificantDigitsUsed 1839 * @param min the fewest significant digits to be shown 1840 * @stable ICU 3.0 1841 */ 1842 void setMinimumSignificantDigits(int32_t min); 1843 1844 /** 1845 * Sets the maximum number of significant digits that will be 1846 * displayed. If <code>max</code> is less than one then it is set 1847 * to one. If the minimum significant digits count is greater 1848 * than <code>max</code>, then it is set to <code>max</code>. 1849 * This function also enables the use of significant digits 1850 * by this formatter - areSignificantDigitsUsed() will return TRUE. 1851 * @see #areSignificantDigitsUsed 1852 * @param max the most significant digits to be shown 1853 * @stable ICU 3.0 1854 */ 1855 void setMaximumSignificantDigits(int32_t max); 1856 1857 /** 1858 * Returns true if significant digits are in use, or false if 1859 * integer and fraction digit counts are in use. 1860 * @return true if significant digits are in use 1861 * @stable ICU 3.0 1862 */ 1863 UBool areSignificantDigitsUsed() const; 1864 1865 /** 1866 * Sets whether significant digits are in use, or integer and 1867 * fraction digit counts are in use. 1868 * @param useSignificantDigits true to use significant digits, or 1869 * false to use integer and fraction digit counts 1870 * @stable ICU 3.0 1871 */ 1872 void setSignificantDigitsUsed(UBool useSignificantDigits); 1873 1874 public: 1875 /** 1876 * Sets the currency used to display currency 1877 * amounts. This takes effect immediately, if this format is a 1878 * currency format. If this format is not a currency format, then 1879 * the currency is used if and when this object becomes a 1880 * currency format through the application of a new pattern. 1881 * @param theCurrency a 3-letter ISO code indicating new currency 1882 * to use. It need not be null-terminated. May be the empty 1883 * string or NULL to indicate no currency. 1884 * @param ec input-output error code 1885 * @stable ICU 3.0 1886 */ 1887 virtual void setCurrency(const UChar* theCurrency, UErrorCode& ec); 1888 1889 /** 1890 * Sets the currency used to display currency amounts. See 1891 * setCurrency(const UChar*, UErrorCode&). 1892 * @deprecated ICU 3.0. Use setCurrency(const UChar*, UErrorCode&). 1893 */ 1894 virtual void setCurrency(const UChar* theCurrency); 1895 1896 #ifndef U_HIDE_DRAFT_API 1897 /** 1898 * Sets the <tt>Currency Context</tt> object used to display currency. 1899 * This takes effect immediately, if this format is a 1900 * currency format. 1901 * @param currencyContext new currency context object to use. 1902 * @draft ICU 54 1903 */ 1904 void setCurrencyUsage(UCurrencyUsage newUsage, UErrorCode* ec); 1905 1906 /** 1907 * Returns the <tt>Currency Context</tt> object used to display currency 1908 * @draft ICU 54 1909 */ 1910 UCurrencyUsage getCurrencyUsage() const; 1911 #endif /* U_HIDE_DRAFT_API */ 1912 1913 1914 #ifndef U_HIDE_DEPRECATED_API 1915 /** 1916 * The resource tags we use to retrieve decimal format data from 1917 * locale resource bundles. 1918 * @deprecated ICU 3.4. This string has no public purpose. Please don't use it. 1919 */ 1920 static const char fgNumberPatterns[]; 1921 #endif /* U_HIDE_DEPRECATED_API */ 1922 1923 #ifndef U_HIDE_INTERNAL_API 1924 /** 1925 * Get a FixedDecimal corresponding to a double as it would be 1926 * formatted by this DecimalFormat. 1927 * Internal, not intended for public use. 1928 * @internal 1929 */ 1930 FixedDecimal getFixedDecimal(double number, UErrorCode &status) const; 1931 1932 /** 1933 * Get a FixedDecimal corresponding to a formattable as it would be 1934 * formatted by this DecimalFormat. 1935 * Internal, not intended for public use. 1936 * @internal 1937 */ 1938 FixedDecimal getFixedDecimal(const Formattable &number, UErrorCode &status) const; 1939 1940 /** 1941 * Get a FixedDecimal corresponding to a DigitList as it would be 1942 * formatted by this DecimalFormat. Note: the DigitList may be modified. 1943 * Internal, not intended for public use. 1944 * @internal 1945 */ 1946 FixedDecimal getFixedDecimal(DigitList &number, UErrorCode &status) const; 1947 #endif /* U_HIDE_INTERNAL_API */ 1948 1949 public: 1950 1951 /** 1952 * Return the class ID for this class. This is useful only for 1953 * comparing to a return value from getDynamicClassID(). For example: 1954 * <pre> 1955 * . Base* polymorphic_pointer = createPolymorphicObject(); 1956 * . if (polymorphic_pointer->getDynamicClassID() == 1957 * . Derived::getStaticClassID()) ... 1958 * </pre> 1959 * @return The class ID for all objects of this class. 1960 * @stable ICU 2.0 1961 */ 1962 static UClassID U_EXPORT2 getStaticClassID(void); 1963 1964 /** 1965 * Returns a unique class ID POLYMORPHICALLY. Pure virtual override. 1966 * This method is to implement a simple version of RTTI, since not all 1967 * C++ compilers support genuine RTTI. Polymorphic operator==() and 1968 * clone() methods call this method. 1969 * 1970 * @return The class ID for this object. All objects of a 1971 * given class have the same class ID. Objects of 1972 * other classes have different class IDs. 1973 * @stable ICU 2.0 1974 */ 1975 virtual UClassID getDynamicClassID(void) const; 1976 1977 private: 1978 1979 DecimalFormat(); // default constructor not implemented 1980 1981 int32_t precision() const; 1982 1983 /** 1984 * Initialize all fields of a new DecimalFormatter to a safe default value. 1985 * Common code for use by constructors. 1986 */ 1987 void init(); 1988 1989 /** 1990 * Do real work of constructing a new DecimalFormat. 1991 */ 1992 void construct(UErrorCode& status, 1993 UParseError& parseErr, 1994 const UnicodeString* pattern = 0, 1995 DecimalFormatSymbols* symbolsToAdopt = 0 1996 ); 1997 1998 /** 1999 * Does the real work of generating a pattern. 2000 * 2001 * @param result Output param which will receive the pattern. 2002 * Previous contents are deleted. 2003 * @param localized TRUE return localized pattern. 2004 * @return A reference to 'result'. 2005 */ 2006 UnicodeString& toPattern(UnicodeString& result, UBool localized) const; 2007 2008 /** 2009 * Does the real work of applying a pattern. 2010 * @param pattern The pattern to be applied. 2011 * @param localized If true, the pattern is localized; else false. 2012 * @param parseError Struct to recieve information on position 2013 * of error if an error is encountered 2014 * @param status Output param set to success/failure code on 2015 * exit. If the pattern is invalid, this will be 2016 * set to a failure result. 2017 */ 2018 void applyPattern(const UnicodeString& pattern, 2019 UBool localized, 2020 UParseError& parseError, 2021 UErrorCode& status); 2022 2023 /* 2024 * similar to applyPattern, but without re-gen affix for currency 2025 */ 2026 void applyPatternInternally(const UnicodeString& pluralCount, 2027 const UnicodeString& pattern, 2028 UBool localized, 2029 UParseError& parseError, 2030 UErrorCode& status); 2031 2032 /* 2033 * only apply pattern without expand affixes 2034 */ 2035 void applyPatternWithoutExpandAffix(const UnicodeString& pattern, 2036 UBool localized, 2037 UParseError& parseError, 2038 UErrorCode& status); 2039 2040 2041 /* 2042 * expand affixes (after apply patter) and re-compute fFormatWidth 2043 */ 2044 void expandAffixAdjustWidth(const UnicodeString* pluralCount); 2045 2046 2047 /** 2048 * Do the work of formatting a number, either a double or a long. 2049 * 2050 * @param appendTo Output parameter to receive result. 2051 * Result is appended to existing contents. 2052 * @param handler Records information about field positions. 2053 * @param digits the digits to be formatted. 2054 * @param isInteger if TRUE format the digits as Integer. 2055 * @return Reference to 'appendTo' parameter. 2056 */ 2057 UnicodeString& subformat(UnicodeString& appendTo, 2058 FieldPositionHandler& handler, 2059 DigitList& digits, 2060 UBool isInteger, 2061 UErrorCode &status) const; 2062 2063 2064 void parse(const UnicodeString& text, 2065 Formattable& result, 2066 ParsePosition& pos, 2067 UChar* currency) const; 2068 2069 enum { 2070 fgStatusInfinite, 2071 fgStatusLength // Leave last in list. 2072 } StatusFlags; 2073 2074 UBool subparse(const UnicodeString& text, 2075 const UnicodeString* negPrefix, 2076 const UnicodeString* negSuffix, 2077 const UnicodeString* posPrefix, 2078 const UnicodeString* posSuffix, 2079 UBool complexCurrencyParsing, 2080 int8_t type, 2081 ParsePosition& parsePosition, 2082 DigitList& digits, UBool* status, 2083 UChar* currency) const; 2084 2085 // Mixed style parsing for currency. 2086 // It parses against the current currency pattern 2087 // using complex affix comparison 2088 // parses against the currency plural patterns using complex affix comparison, 2089 // and parses against the current pattern using simple affix comparison. 2090 UBool parseForCurrency(const UnicodeString& text, 2091 ParsePosition& parsePosition, 2092 DigitList& digits, 2093 UBool* status, 2094 UChar* currency) const; 2095 2096 int32_t skipPadding(const UnicodeString& text, int32_t position) const; 2097 2098 int32_t compareAffix(const UnicodeString& input, 2099 int32_t pos, 2100 UBool isNegative, 2101 UBool isPrefix, 2102 const UnicodeString* affixPat, 2103 UBool complexCurrencyParsing, 2104 int8_t type, 2105 UChar* currency) const; 2106 2107 static UnicodeString& trimMarksFromAffix(const UnicodeString& affix, UnicodeString& trimmedAffix); 2108 2109 UBool equalWithSignCompatibility(UChar32 lhs, UChar32 rhs) const; 2110 2111 int32_t compareSimpleAffix(const UnicodeString& affix, 2112 const UnicodeString& input, 2113 int32_t pos, 2114 UBool lenient) const; 2115 2116 static int32_t skipPatternWhiteSpace(const UnicodeString& text, int32_t pos); 2117 2118 static int32_t skipUWhiteSpace(const UnicodeString& text, int32_t pos); 2119 2120 static int32_t skipUWhiteSpaceAndMarks(const UnicodeString& text, int32_t pos); 2121 2122 static int32_t skipBidiMarks(const UnicodeString& text, int32_t pos); 2123 2124 int32_t compareComplexAffix(const UnicodeString& affixPat, 2125 const UnicodeString& input, 2126 int32_t pos, 2127 int8_t type, 2128 UChar* currency) const; 2129 2130 static int32_t match(const UnicodeString& text, int32_t pos, UChar32 ch); 2131 2132 static int32_t match(const UnicodeString& text, int32_t pos, const UnicodeString& str); 2133 2134 static UBool matchSymbol(const UnicodeString &text, int32_t position, int32_t length, const UnicodeString &symbol, 2135 UnicodeSet *sset, UChar32 schar); 2136 2137 static UBool matchDecimal(UChar32 symbolChar, 2138 UBool sawDecimal, UChar32 sawDecimalChar, 2139 const UnicodeSet *sset, UChar32 schar); 2140 2141 static UBool matchGrouping(UChar32 groupingChar, 2142 UBool sawGrouping, UChar32 sawGroupingChar, 2143 const UnicodeSet *sset, 2144 UChar32 decimalChar, const UnicodeSet *decimalSet, 2145 UChar32 schar); 2146 2147 /** 2148 * Get a decimal format symbol. 2149 * Returns a const reference to the symbol string. 2150 * @internal 2151 */ 2152 inline const UnicodeString &getConstSymbol(DecimalFormatSymbols::ENumberFormatSymbol symbol) const; 2153 2154 int32_t appendAffix(UnicodeString& buf, 2155 double number, 2156 FieldPositionHandler& handler, 2157 UBool isNegative, 2158 UBool isPrefix) const; 2159 2160 /** 2161 * Append an affix to the given UnicodeString, using quotes if 2162 * there are special characters. Single quotes themselves must be 2163 * escaped in either case. 2164 */ 2165 void appendAffixPattern(UnicodeString& appendTo, const UnicodeString& affix, 2166 UBool localized) const; 2167 2168 void appendAffixPattern(UnicodeString& appendTo, 2169 const UnicodeString* affixPattern, 2170 const UnicodeString& expAffix, UBool localized) const; 2171 2172 void expandAffix(const UnicodeString& pattern, 2173 UnicodeString& affix, 2174 double number, 2175 FieldPositionHandler& handler, 2176 UBool doFormat, 2177 const UnicodeString* pluralCount) const; 2178 2179 void expandAffixes(const UnicodeString* pluralCount); 2180 2181 void addPadding(UnicodeString& appendTo, 2182 FieldPositionHandler& handler, 2183 int32_t prefixLen, int32_t suffixLen) const; 2184 2185 UBool isGroupingPosition(int32_t pos) const; 2186 2187 void setCurrencyForSymbols(); 2188 2189 // similar to setCurrency without re-compute the affixes for currency. 2190 // If currency changes, the affix pattern for currency is not changed, 2191 // but the affix will be changed. So, affixes need to be 2192 // re-computed in setCurrency(), but not in setCurrencyInternally(). 2193 virtual void setCurrencyInternally(const UChar* theCurrency, UErrorCode& ec); 2194 2195 // set up currency affix patterns for mix parsing. 2196 // The patterns saved here are the affix patterns of default currency 2197 // pattern and the unique affix patterns of the plural currency patterns. 2198 // Those patterns are used by parseForCurrency(). 2199 void setupCurrencyAffixPatterns(UErrorCode& status); 2200 2201 // set up the currency affixes used in currency plural formatting. 2202 // It sets up both fAffixesForCurrency for currency pattern if the current 2203 // pattern contains 3 currency signs, 2204 // and it sets up fPluralAffixesForCurrency for currency plural patterns. 2205 void setupCurrencyAffixes(const UnicodeString& pattern, 2206 UBool setupForCurrentPattern, 2207 UBool setupForPluralPattern, 2208 UErrorCode& status); 2209 2210 // get the currency rounding with respect to currency usage 2211 double getCurrencyRounding(const UChar* currency, 2212 UErrorCode* ec) const; 2213 2214 // get the currency fraction with respect to currency usage 2215 int getCurrencyFractionDigits(const UChar* currency, 2216 UErrorCode* ec) const; 2217 2218 // hashtable operations 2219 Hashtable* initHashForAffixPattern(UErrorCode& status); 2220 Hashtable* initHashForAffix(UErrorCode& status); 2221 2222 void deleteHashForAffixPattern(); 2223 void deleteHashForAffix(Hashtable*& table); 2224 2225 void copyHashForAffixPattern(const Hashtable* source, 2226 Hashtable* target, UErrorCode& status); 2227 void copyHashForAffix(const Hashtable* source, 2228 Hashtable* target, UErrorCode& status); 2229 2230 UnicodeString& _format(int64_t number, 2231 UnicodeString& appendTo, 2232 FieldPositionHandler& handler, 2233 UErrorCode &status) const; 2234 UnicodeString& _format(double number, 2235 UnicodeString& appendTo, 2236 FieldPositionHandler& handler, 2237 UErrorCode &status) const; 2238 UnicodeString& _format(const DigitList &number, 2239 UnicodeString& appendTo, 2240 FieldPositionHandler& handler, 2241 UErrorCode &status) const; 2242 2243 /** 2244 * Constants. 2245 */ 2246 2247 UnicodeString fPositivePrefix; 2248 UnicodeString fPositiveSuffix; 2249 UnicodeString fNegativePrefix; 2250 UnicodeString fNegativeSuffix; 2251 UnicodeString* fPosPrefixPattern; 2252 UnicodeString* fPosSuffixPattern; 2253 UnicodeString* fNegPrefixPattern; 2254 UnicodeString* fNegSuffixPattern; 2255 2256 /** 2257 * Formatter for ChoiceFormat-based currency names. If this field 2258 * is not null, then delegate to it to format currency symbols. 2259 * @since ICU 2.6 2260 */ 2261 ChoiceFormat* fCurrencyChoice; 2262 2263 DigitList * fMultiplier; // NULL for multiplier of one 2264 int32_t fScale; 2265 int32_t fGroupingSize; 2266 int32_t fGroupingSize2; 2267 UBool fDecimalSeparatorAlwaysShown; 2268 DecimalFormatSymbols* fSymbols; 2269 2270 UBool fUseSignificantDigits; 2271 int32_t fMinSignificantDigits; 2272 int32_t fMaxSignificantDigits; 2273 2274 UBool fUseExponentialNotation; 2275 int8_t fMinExponentDigits; 2276 UBool fExponentSignAlwaysShown; 2277 2278 EnumSet<UNumberFormatAttribute, 2279 UNUM_MAX_NONBOOLEAN_ATTRIBUTE+1, 2280 UNUM_LIMIT_BOOLEAN_ATTRIBUTE> 2281 fBoolFlags; 2282 2283 DigitList* fRoundingIncrement; // NULL if no rounding increment specified. 2284 ERoundingMode fRoundingMode; 2285 2286 UChar32 fPad; 2287 int32_t fFormatWidth; 2288 EPadPosition fPadPosition; 2289 2290 /* 2291 * Following are used for currency format 2292 */ 2293 // pattern used in this formatter 2294 UnicodeString fFormatPattern; 2295 // style is only valid when decimal formatter is constructed by 2296 // DecimalFormat(pattern, decimalFormatSymbol, style) 2297 int fStyle; 2298 /* 2299 * Represents whether this is a currency format, and which 2300 * currency format style. 2301 * 0: not currency format type; 2302 * 1: currency style -- symbol name, such as "$" for US dollar. 2303 * 2: currency style -- ISO name, such as USD for US dollar. 2304 * 3: currency style -- plural long name, such as "US Dollar" for 2305 * "1.00 US Dollar", or "US Dollars" for 2306 * "3.00 US Dollars". 2307 */ 2308 int fCurrencySignCount; 2309 2310 2311 /* For currency parsing purose, 2312 * Need to remember all prefix patterns and suffix patterns of 2313 * every currency format pattern, 2314 * including the pattern of default currecny style 2315 * and plural currency style. And the patterns are set through applyPattern. 2316 */ 2317 // TODO: innerclass? 2318 /* This is not needed in the class declaration, so it is moved into decimfmp.cpp 2319 struct AffixPatternsForCurrency : public UMemory { 2320 // negative prefix pattern 2321 UnicodeString negPrefixPatternForCurrency; 2322 // negative suffix pattern 2323 UnicodeString negSuffixPatternForCurrency; 2324 // positive prefix pattern 2325 UnicodeString posPrefixPatternForCurrency; 2326 // positive suffix pattern 2327 UnicodeString posSuffixPatternForCurrency; 2328 int8_t patternType; 2329 2330 AffixPatternsForCurrency(const UnicodeString& negPrefix, 2331 const UnicodeString& negSuffix, 2332 const UnicodeString& posPrefix, 2333 const UnicodeString& posSuffix, 2334 int8_t type) { 2335 negPrefixPatternForCurrency = negPrefix; 2336 negSuffixPatternForCurrency = negSuffix; 2337 posPrefixPatternForCurrency = posPrefix; 2338 posSuffixPatternForCurrency = posSuffix; 2339 patternType = type; 2340 } 2341 }; 2342 */ 2343 2344 /* affix for currency formatting when the currency sign in the pattern 2345 * equals to 3, such as the pattern contains 3 currency sign or 2346 * the formatter style is currency plural format style. 2347 */ 2348 /* This is not needed in the class declaration, so it is moved into decimfmp.cpp 2349 struct AffixesForCurrency : public UMemory { 2350 // negative prefix 2351 UnicodeString negPrefixForCurrency; 2352 // negative suffix 2353 UnicodeString negSuffixForCurrency; 2354 // positive prefix 2355 UnicodeString posPrefixForCurrency; 2356 // positive suffix 2357 UnicodeString posSuffixForCurrency; 2358 2359 int32_t formatWidth; 2360 2361 AffixesForCurrency(const UnicodeString& negPrefix, 2362 const UnicodeString& negSuffix, 2363 const UnicodeString& posPrefix, 2364 const UnicodeString& posSuffix) { 2365 negPrefixForCurrency = negPrefix; 2366 negSuffixForCurrency = negSuffix; 2367 posPrefixForCurrency = posPrefix; 2368 posSuffixForCurrency = posSuffix; 2369 } 2370 }; 2371 */ 2372 2373 // Affix pattern set for currency. 2374 // It is a set of AffixPatternsForCurrency, 2375 // each element of the set saves the negative prefix pattern, 2376 // negative suffix pattern, positive prefix pattern, 2377 // and positive suffix pattern of a pattern. 2378 // It is used for currency mixed style parsing. 2379 // It is actually is a set. 2380 // The set contains the default currency pattern from the locale, 2381 // and the currency plural patterns. 2382 // Since it is a set, it does not contain duplicated items. 2383 // For example, if 2 currency plural patterns are the same, only one pattern 2384 // is included in the set. When parsing, we do not check whether the plural 2385 // count match or not. 2386 Hashtable* fAffixPatternsForCurrency; 2387 2388 // Following 2 are affixes for currency. 2389 // It is a hash map from plural count to AffixesForCurrency. 2390 // AffixesForCurrency saves the negative prefix, 2391 // negative suffix, positive prefix, and positive suffix of a pattern. 2392 // It is used during currency formatting only when the currency sign count 2393 // is 3. In which case, the affixes are getting from here, not 2394 // from the fNegativePrefix etc. 2395 Hashtable* fAffixesForCurrency; // for current pattern 2396 Hashtable* fPluralAffixesForCurrency; // for plural pattern 2397 2398 // Information needed for DecimalFormat to format/parse currency plural. 2399 CurrencyPluralInfo* fCurrencyPluralInfo; 2400 2401 #if UCONFIG_HAVE_PARSEALLINPUT 2402 UNumberFormatAttributeValue fParseAllInput; 2403 #endif 2404 2405 // Decimal Format Static Sets singleton. 2406 const DecimalFormatStaticSets *fStaticSets; 2407 2408 // Currency Usage(STANDARD vs CASH) 2409 UCurrencyUsage fCurrencyUsage; 2410 2411 protected: 2412 2413 #ifndef U_HIDE_INTERNAL_API 2414 /** 2415 * Rounds a value according to the rules of this object. 2416 * @internal 2417 */ 2418 DigitList& _round(const DigitList& number, DigitList& adjustedNum, UBool& isNegative, UErrorCode& status) const; 2419 #endif /* U_HIDE_INTERNAL_API */ 2420 2421 /** 2422 * Returns the currency in effect for this formatter. Subclasses 2423 * should override this method as needed. Unlike getCurrency(), 2424 * this method should never return "". 2425 * @result output parameter for null-terminated result, which must 2426 * have a capacity of at least 4 2427 * @internal 2428 */ 2429 virtual void getEffectiveCurrency(UChar* result, UErrorCode& ec) const; 2430 2431 /** number of integer digits 2432 * @stable ICU 2.4 2433 */ 2434 static const int32_t kDoubleIntegerDigits; 2435 /** number of fraction digits 2436 * @stable ICU 2.4 2437 */ 2438 static const int32_t kDoubleFractionDigits; 2439 2440 /** 2441 * When someone turns on scientific mode, we assume that more than this 2442 * number of digits is due to flipping from some other mode that didn't 2443 * restrict the maximum, and so we force 1 integer digit. We don't bother 2444 * to track and see if someone is using exponential notation with more than 2445 * this number, it wouldn't make sense anyway, and this is just to make sure 2446 * that someone turning on scientific mode with default settings doesn't 2447 * end up with lots of zeroes. 2448 * @stable ICU 2.8 2449 */ 2450 static const int32_t kMaxScientificIntegerDigits; 2451 2452 #if UCONFIG_FORMAT_FASTPATHS_49 2453 private: 2454 /** 2455 * Internal state. 2456 * @internal 2457 */ 2458 uint8_t fReserved[UNUM_DECIMALFORMAT_INTERNAL_SIZE]; 2459 2460 2461 /** 2462 * Called whenever any state changes. Recomputes whether fastpath is OK to use. 2463 */ 2464 void handleChanged(); 2465 #endif 2466 }; 2467 2468 inline const UnicodeString & 2469 DecimalFormat::getConstSymbol(DecimalFormatSymbols::ENumberFormatSymbol symbol) const { 2470 return fSymbols->getConstSymbol(symbol); 2471 } 2472 2473 U_NAMESPACE_END 2474 2475 #endif /* #if !UCONFIG_NO_FORMATTING */ 2476 2477 #endif // _DECIMFMT 2478 //eof 2479