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// © 2017 and later: Unicode, Inc. and others. 
// License & terms of use: http://www.unicode.org/copyright.html 
 
#include "unicode/utypes.h" 
 
#if !UCONFIG_NO_FORMATTING 
 
#include <cstdlib> 
#include "number_scientific.h" 
#include "number_utils.h" 
#include "formatted_string_builder.h" 
#include "unicode/unum.h" 
#include "number_microprops.h" 
 
using namespace icu; 
using namespace icu::number; 
using namespace icu::number::impl; 
 
// NOTE: The object lifecycle of ScientificModifier and ScientificHandler differ greatly in Java and C++. 
// 
// During formatting, we need to provide an object with state (the exponent) as the inner modifier. 
// 
// In Java, where the priority is put on reducing object creations, the unsafe code path re-uses the 
// ScientificHandler as a ScientificModifier, and the safe code path pre-computes 25 ScientificModifier 
// instances.  This scheme reduces the number of object creations by 1 in both safe and unsafe. 
// 
// In C++, MicroProps provides a pre-allocated ScientificModifier, and ScientificHandler simply populates 
// the state (the exponent) into that ScientificModifier. There is no difference between safe and unsafe. 
 
ScientificModifier::ScientificModifier() : fExponent(0), fHandler(nullptr) {} 
 
void ScientificModifier::set(int32_t exponent, const ScientificHandler *handler) { 
    // ScientificModifier should be set only once. 
    U_ASSERT(fHandler == nullptr); 
    fExponent = exponent; 
    fHandler = handler; 
} 
 
int32_t ScientificModifier::apply(FormattedStringBuilder &output, int32_t /*leftIndex*/, int32_t rightIndex, 
                                  UErrorCode &status) const { 
    // FIXME: Localized exponent separator location. 
    int i = rightIndex; 
    // Append the exponent separator and sign 
    i += output.insert( 
            i, 
            fHandler->fSymbols->getSymbol(DecimalFormatSymbols::ENumberFormatSymbol::kExponentialSymbol), 
            {UFIELD_CATEGORY_NUMBER, UNUM_EXPONENT_SYMBOL_FIELD}, 
            status); 
    if (fExponent < 0 && fHandler->fSettings.fExponentSignDisplay != UNUM_SIGN_NEVER) { 
        i += output.insert( 
                i, 
                fHandler->fSymbols 
                        ->getSymbol(DecimalFormatSymbols::ENumberFormatSymbol::kMinusSignSymbol), 
                {UFIELD_CATEGORY_NUMBER, UNUM_EXPONENT_SIGN_FIELD}, 
                status); 
    } else if (fExponent >= 0 && fHandler->fSettings.fExponentSignDisplay == UNUM_SIGN_ALWAYS) { 
        i += output.insert( 
                i, 
                fHandler->fSymbols 
                        ->getSymbol(DecimalFormatSymbols::ENumberFormatSymbol::kPlusSignSymbol), 
                {UFIELD_CATEGORY_NUMBER, UNUM_EXPONENT_SIGN_FIELD}, 
                status); 
    } 
    // Append the exponent digits (using a simple inline algorithm) 
    int32_t disp = std::abs(fExponent); 
    for (int j = 0; j < fHandler->fSettings.fMinExponentDigits || disp > 0; j++, disp /= 10) { 
        auto d = static_cast<int8_t>(disp % 10); 
        i += utils::insertDigitFromSymbols( 
                output, 
                i - j, 
                d, 
                *fHandler->fSymbols, 
                {UFIELD_CATEGORY_NUMBER, UNUM_EXPONENT_FIELD}, 
                status); 
    } 
    return i - rightIndex; 
} 
 
int32_t ScientificModifier::getPrefixLength() const { 
    // TODO: Localized exponent separator location. 
    return 0; 
} 
 
int32_t ScientificModifier::getCodePointCount() const { 
    // NOTE: This method is only called one place, NumberRangeFormatterImpl. 
    // The call site only cares about != 0 and != 1. 
    // Return a very large value so that if this method is used elsewhere, we should notice. 
    return 999; 
} 
 
bool ScientificModifier::isStrong() const { 
    // Scientific is always strong 
    return true; 
} 
 
bool ScientificModifier::containsField(Field field) const { 
    (void)field; 
    // This method is not used for inner modifiers. 
    UPRV_UNREACHABLE; 
} 
 
void ScientificModifier::getParameters(Parameters& output) const { 
    // Not part of any plural sets 
    output.obj = nullptr; 
} 
 
bool ScientificModifier::semanticallyEquivalent(const Modifier& other) const { 
    auto* _other = dynamic_cast<const ScientificModifier*>(&other); 
    if (_other == nullptr) { 
        return false; 
    } 
    // TODO: Check for locale symbols and settings as well? Could be less efficient. 
    return fExponent == _other->fExponent; 
} 
 
// Note: Visual Studio does not compile this function without full name space. Why? 
icu::number::impl::ScientificHandler::ScientificHandler(const Notation *notation, const DecimalFormatSymbols *symbols, 
	const MicroPropsGenerator *parent) :  
	fSettings(notation->fUnion.scientific), fSymbols(symbols), fParent(parent) {} 
 
void ScientificHandler::processQuantity(DecimalQuantity &quantity, MicroProps &micros, 
                                        UErrorCode &status) const { 
    fParent->processQuantity(quantity, micros, status); 
    if (U_FAILURE(status)) { return; } 
 
    // Do not apply scientific notation to special doubles 
    if (quantity.isInfinite() || quantity.isNaN()) { 
        micros.modInner = &micros.helpers.emptyStrongModifier; 
        return; 
    } 
 
    // Treat zero as if it had magnitude 0 
    int32_t exponent; 
    if (quantity.isZeroish()) { 
        if (fSettings.fRequireMinInt && micros.rounder.isSignificantDigits()) { 
            // Show "00.000E0" on pattern "00.000E0" 
            micros.rounder.apply(quantity, fSettings.fEngineeringInterval, status); 
            exponent = 0; 
        } else { 
            micros.rounder.apply(quantity, status); 
            exponent = 0; 
        } 
    } else { 
        exponent = -micros.rounder.chooseMultiplierAndApply(quantity, *this, status); 
    } 
 
    // Use MicroProps's helper ScientificModifier and save it as the modInner. 
    ScientificModifier &mod = micros.helpers.scientificModifier; 
    mod.set(exponent, this); 
    micros.modInner = &mod; 
 
    // Change the exponent only after we select appropriate plural form 
    // for formatting purposes so that we preserve expected formatted 
    // string behavior. 
    quantity.adjustExponent(exponent); 
 
    // We already performed rounding. Do not perform it again. 
    micros.rounder = RoundingImpl::passThrough(); 
} 
 
int32_t ScientificHandler::getMultiplier(int32_t magnitude) const { 
    int32_t interval = fSettings.fEngineeringInterval; 
    int32_t digitsShown; 
    if (fSettings.fRequireMinInt) { 
        // For patterns like "000.00E0" and ".00E0" 
        digitsShown = interval; 
    } else if (interval <= 1) { 
        // For patterns like "0.00E0" and "@@@E0" 
        digitsShown = 1; 
    } else { 
        // For patterns like "##0.00" 
        digitsShown = ((magnitude % interval + interval) % interval) + 1; 
    } 
    return digitsShown - magnitude - 1; 
} 
 
#endif /* #if !UCONFIG_NO_FORMATTING */