// © 2018 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html #include "unicode/utypes.h" #if !UCONFIG_NO_FORMATTING // Allow implicit conversion from char16_t* to UnicodeString for this file: // Helpful in toString methods and elsewhere. #define UNISTR_FROM_STRING_EXPLICIT #include <stdlib.h> #include <cmath> #include "number_decnum.h" #include "number_types.h" #include "number_utils.h" #include "charstr.h" #include "decContext.h" #include "decNumber.h" #include "double-conversion.h" #include "fphdlimp.h" #include "uresimp.h" #include "ureslocs.h" using namespace icu; using namespace icu::number; using namespace icu::number::impl; using icu::double_conversion::DoubleToStringConverter; namespace { const char16_t* doGetPattern(UResourceBundle* res, const char* nsName, const char* patternKey, UErrorCode& publicStatus, UErrorCode& localStatus) { // Construct the path into the resource bundle CharString key; key.append("NumberElements/", publicStatus); key.append(nsName, publicStatus); key.append("/patterns/", publicStatus); key.append(patternKey, publicStatus); if (U_FAILURE(publicStatus)) { return u""; } return ures_getStringByKeyWithFallback(res, key.data(), nullptr, &localStatus); } } const char16_t* utils::getPatternForStyle(const Locale& locale, const char* nsName, CldrPatternStyle style, UErrorCode& status) { const char* patternKey; switch (style) { case CLDR_PATTERN_STYLE_DECIMAL: patternKey = "decimalFormat"; break; case CLDR_PATTERN_STYLE_CURRENCY: patternKey = "currencyFormat"; break; case CLDR_PATTERN_STYLE_ACCOUNTING: patternKey = "accountingFormat"; break; case CLDR_PATTERN_STYLE_PERCENT: patternKey = "percentFormat"; break; case CLDR_PATTERN_STYLE_SCIENTIFIC: patternKey = "scientificFormat"; break; default: patternKey = "decimalFormat"; // silence compiler error U_ASSERT(false); } LocalUResourceBundlePointer res(ures_open(nullptr, locale.getName(), &status)); if (U_FAILURE(status)) { return u""; } // Attempt to get the pattern with the native numbering system. UErrorCode localStatus = U_ZERO_ERROR; const char16_t* pattern; pattern = doGetPattern(res.getAlias(), nsName, patternKey, status, localStatus); if (U_FAILURE(status)) { return u""; } // Fall back to latn if native numbering system does not have the right pattern if (U_FAILURE(localStatus) && uprv_strcmp("latn", nsName) != 0) { localStatus = U_ZERO_ERROR; pattern = doGetPattern(res.getAlias(), "latn", patternKey, status, localStatus); if (U_FAILURE(status)) { return u""; } } return pattern; } DecNum::DecNum() { uprv_decContextDefault(&fContext, DEC_INIT_BASE); uprv_decContextSetRounding(&fContext, DEC_ROUND_HALF_EVEN); fContext.traps = 0; // no traps, thank you (what does this even mean?) } DecNum::DecNum(const DecNum& other, UErrorCode& status) : fContext(other.fContext) { // Allocate memory for the new DecNum. U_ASSERT(fContext.digits == other.fData.getCapacity()); if (fContext.digits > kDefaultDigits) { void* p = fData.resize(fContext.digits, 0); if (p == nullptr) { status = U_MEMORY_ALLOCATION_ERROR; return; } } // Copy the data from the old DecNum to the new one. uprv_memcpy(fData.getAlias(), other.fData.getAlias(), sizeof(decNumber)); uprv_memcpy(fData.getArrayStart(), other.fData.getArrayStart(), other.fData.getArrayLimit() - other.fData.getArrayStart()); } void DecNum::setTo(StringPiece str, UErrorCode& status) { // We need NUL-terminated for decNumber; CharString guarantees this, but not StringPiece. CharString cstr(str, status); if (U_FAILURE(status)) { return; } _setTo(cstr.data(), str.length(), status); } void DecNum::setTo(const char* str, UErrorCode& status) { _setTo(str, static_cast<int32_t>(uprv_strlen(str)), status); } void DecNum::setTo(double d, UErrorCode& status) { // Need to check for NaN and Infinity before going into DoubleToStringConverter if (std::isnan(d) != 0 || std::isfinite(d) == 0) { status = U_UNSUPPORTED_ERROR; return; } // First convert from double to string, then string to DecNum. // Allocate enough room for: all digits, "E-324", and NUL-terminator. char buffer[DoubleToStringConverter::kBase10MaximalLength + 6]; bool sign; // unused; always positive int32_t length; int32_t point; DoubleToStringConverter::DoubleToAscii( d, DoubleToStringConverter::DtoaMode::SHORTEST, 0, buffer, sizeof(buffer), &sign, &length, &point ); // Read initial result as a string. _setTo(buffer, length, status); // Set exponent and bitmask. Note that DoubleToStringConverter does not do negatives. fData.getAlias()->exponent += point - length; fData.getAlias()->bits |= static_cast<uint8_t>(std::signbit(d) ? DECNEG : 0); } void DecNum::_setTo(const char* str, int32_t maxDigits, UErrorCode& status) { if (maxDigits > kDefaultDigits) { fData.resize(maxDigits, 0); fContext.digits = maxDigits; } else { fContext.digits = kDefaultDigits; } static_assert(DECDPUN == 1, "Assumes that DECDPUN is set to 1"); uprv_decNumberFromString(fData.getAlias(), str, &fContext); // Check for invalid syntax and set the corresponding error code. if ((fContext.status & DEC_Conversion_syntax) != 0) { status = U_DECIMAL_NUMBER_SYNTAX_ERROR; return; } else if (fContext.status != 0) { // Not a syntax error, but some other error, like an exponent that is too large. status = U_UNSUPPORTED_ERROR; return; } // For consistency with Java BigDecimal, no support for DecNum that is NaN or Infinity! if (decNumberIsSpecial(fData.getAlias())) { status = U_UNSUPPORTED_ERROR; return; } } void DecNum::setTo(const uint8_t* bcd, int32_t length, int32_t scale, bool isNegative, UErrorCode& status) { if (length > kDefaultDigits) { fData.resize(length, 0); fContext.digits = length; } else { fContext.digits = kDefaultDigits; } // "digits is of type int32_t, and must have a value in the range 1 through 999,999,999." if (length < 1 || length > 999999999) { // Too large for decNumber status = U_UNSUPPORTED_ERROR; return; } // "The exponent field holds the exponent of the number. Its range is limited by the requirement that // "the range of the adjusted exponent of the number be balanced and fit within a whole number of // "decimal digits (in this implementation, be –999,999,999 through +999,999,999). The adjusted // "exponent is the exponent that would result if the number were expressed with a single digit before // "the decimal point, and is therefore given by exponent+digits-1." if (scale > 999999999 - length + 1 || scale < -999999999 - length + 1) { // Too large for decNumber status = U_UNSUPPORTED_ERROR; return; } fData.getAlias()->digits = length; fData.getAlias()->exponent = scale; fData.getAlias()->bits = static_cast<uint8_t>(isNegative ? DECNEG : 0); uprv_decNumberSetBCD(fData, bcd, static_cast<uint32_t>(length)); if (fContext.status != 0) { // Some error occurred while constructing the decNumber. status = U_INTERNAL_PROGRAM_ERROR; } } void DecNum::normalize() { uprv_decNumberReduce(fData, fData, &fContext); } void DecNum::multiplyBy(const DecNum& rhs, UErrorCode& status) { uprv_decNumberMultiply(fData, fData, rhs.fData, &fContext); if (fContext.status != 0) { status = U_INTERNAL_PROGRAM_ERROR; } } void DecNum::divideBy(const DecNum& rhs, UErrorCode& status) { uprv_decNumberDivide(fData, fData, rhs.fData, &fContext); if (fContext.status != 0) { status = U_INTERNAL_PROGRAM_ERROR; } } bool DecNum::isNegative() const { return decNumberIsNegative(fData.getAlias()); } bool DecNum::isZero() const { return decNumberIsZero(fData.getAlias()); } #endif /* #if !UCONFIG_NO_FORMATTING */