[apple/icu.git] / icuSources / i18n / precision.cpp

// © 2016 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
/*
 * Copyright (C) 2015, International Business Machines
 * Corporation and others.  All Rights Reserved.
 *
 * file name: precisison.cpp
 */

#include <math.h>

#include "unicode/utypes.h"

#if !UCONFIG_NO_FORMATTING

#include "digitlst.h"
#include "fmtableimp.h"
#include "precision.h"
#include "putilimp.h"
#include "visibledigits.h"

U_NAMESPACE_BEGIN

static const int32_t gPower10[] = {1, 10, 100, 1000};

FixedPrecision::FixedPrecision() 
        : fExactOnly(FALSE), fFailIfOverMax(FALSE), fRoundingMode(DecimalFormat::kRoundHalfEven) {
    fMin.setIntDigitCount(1);
    fMin.setFracDigitCount(0);
}

UBool
FixedPrecision::isRoundingRequired(
        int32_t upperExponent, int32_t lowerExponent) const {
    int32_t leastSigAllowed = fMax.getLeastSignificantInclusive();
    int32_t maxSignificantDigits = fSignificant.getMax();
    int32_t roundDigit;
    if (maxSignificantDigits == INT32_MAX) {
        roundDigit = leastSigAllowed;
    } else {
        int32_t limitDigit = upperExponent - maxSignificantDigits;
        roundDigit =
                limitDigit > leastSigAllowed ? limitDigit : leastSigAllowed;
    }
    return (roundDigit > lowerExponent);
}

DigitList &
FixedPrecision::round(
        DigitList &value, int32_t exponent, UErrorCode &status) const {
    if (U_FAILURE(status)) {
        return value;
    }
    value .fContext.status &= ~DEC_Inexact;
    if (!fRoundingIncrement.isZero()) {
        if (exponent == 0) {
            value.quantize(fRoundingIncrement, status);
        } else {
            DigitList adjustedIncrement(fRoundingIncrement);
            adjustedIncrement.shiftDecimalRight(exponent);
            value.quantize(adjustedIncrement, status);
        }
        if (U_FAILURE(status)) {
            return value;
        }
    }
    int32_t leastSig = fMax.getLeastSignificantInclusive();
    if (leastSig == INT32_MIN) {
        value.round(fSignificant.getMax());
    } else {
        value.roundAtExponent(
                exponent + leastSig,
                fSignificant.getMax());
    }
    if (fExactOnly && (value.fContext.status & DEC_Inexact)) {
        status = U_FORMAT_INEXACT_ERROR;
    } else if (fFailIfOverMax) {
        // Smallest interval for value stored in interval
        DigitInterval interval;
        value.getSmallestInterval(interval);
        if (fMax.getIntDigitCount() < interval.getIntDigitCount()) {
            status = U_ILLEGAL_ARGUMENT_ERROR;
        }
    }
    return value;
}

DigitInterval &
FixedPrecision::getIntervalForZero(DigitInterval &interval) const {
    interval = fMin;
    if (fSignificant.getMin() > 0) {
        interval.expandToContainDigit(interval.getIntDigitCount() - fSignificant.getMin());
    }
    interval.shrinkToFitWithin(fMax);
    return interval;
}

DigitInterval &
FixedPrecision::getInterval(
        int32_t upperExponent, DigitInterval &interval) const {
    if (fSignificant.getMin() > 0) {
        interval.expandToContainDigit(
                upperExponent - fSignificant.getMin());
    }
    interval.expandToContain(fMin);
    interval.shrinkToFitWithin(fMax);
    return interval;
}

DigitInterval &
FixedPrecision::getInterval(
        const DigitList &value, DigitInterval &interval) const {
    if (value.isZero()) {
        interval = fMin;
        if (fSignificant.getMin() > 0) {
            interval.expandToContainDigit(interval.getIntDigitCount() - fSignificant.getMin());
        }
    } else {
        value.getSmallestInterval(interval);
        if (fSignificant.getMin() > 0) {
            interval.expandToContainDigit(
                    value.getUpperExponent() - fSignificant.getMin());
        }
        interval.expandToContain(fMin);
    }
    interval.shrinkToFitWithin(fMax);
    return interval;
}

UBool
FixedPrecision::isFastFormattable() const {
    return (fMin.getFracDigitCount() == 0 && fSignificant.isNoConstraints() && fRoundingIncrement.isZero() && !fFailIfOverMax);
}

UBool
FixedPrecision::handleNonNumeric(DigitList &value, VisibleDigits &digits) {
    if (value.isNaN()) {
        digits.setNaN();
        return TRUE;
    }
    if (value.isInfinite()) {
        digits.setInfinite();
        if (!value.isPositive()) {
            digits.setNegative();
        }
        return TRUE;
    }
    return FALSE;
}

VisibleDigits &
FixedPrecision::initVisibleDigits(
        DigitList &value,
        VisibleDigits &digits,
        UErrorCode &status) const {
    if (U_FAILURE(status)) {
        return digits;
    }
    digits.clear();
    if (handleNonNumeric(value, digits)) {
        return digits;
    }
    if (!value.isPositive()) {
        digits.setNegative();
    }
    value.setRoundingMode(fRoundingMode);
    round(value, 0, status);
    getInterval(value, digits.fInterval);
    digits.fExponent = value.getLowerExponent();
    value.appendDigitsTo(digits.fDigits, status);
    return digits;
}

VisibleDigits &
FixedPrecision::initVisibleDigits(
        int64_t value,
        VisibleDigits &digits,
        UErrorCode &status) const {
    if (U_FAILURE(status)) {
        return digits;
    }
    if (!fRoundingIncrement.isZero()) {
        // If we have round increment, use digit list.
        DigitList digitList;
        digitList.set(value);
        return initVisibleDigits(digitList, digits, status);
    }
    // Try fast path
    if (initVisibleDigits(value, 0, digits, status)) {
        digits.fAbsDoubleValue = fabs((double) value);
        digits.fAbsDoubleValueSet = U_SUCCESS(status) && !digits.isOverMaxDigits();
        return digits;
    }
    // Oops have to use digit list
    DigitList digitList;
    digitList.set(value);
    return initVisibleDigits(digitList, digits, status);
}

VisibleDigits &
FixedPrecision::initVisibleDigits(
        double value,
        VisibleDigits &digits,
        UErrorCode &status) const {
    if (U_FAILURE(status)) {
        return digits;
    }
    digits.clear();
    if (uprv_isNaN(value)) {
        digits.setNaN();
        return digits;
    }
    if (uprv_isPositiveInfinity(value)) {
        digits.setInfinite();
        return digits;
    }
    if (uprv_isNegativeInfinity(value)) {
        digits.setInfinite();
        digits.setNegative();
        return digits;
    }
    if (!fRoundingIncrement.isZero()) {
        // If we have round increment, use digit list.
        DigitList digitList;
        digitList.set(value);
        return initVisibleDigits(digitList, digits, status);
    }
    // Try to find n such that value * 10^n is an integer
    int32_t n = -1;
    double scaled;
    for (int32_t i = 0; i < UPRV_LENGTHOF(gPower10); ++i) {
        scaled = value * gPower10[i];
        if (scaled > MAX_INT64_IN_DOUBLE || scaled < -MAX_INT64_IN_DOUBLE) {
            break;
        }
        if (scaled == floor(scaled)) {
            n = i;
            break;
        }
    }
    // Try fast path
    if (n >= 0 && initVisibleDigits(scaled, -n, digits, status)) {
        digits.fAbsDoubleValue = fabs(value);
        digits.fAbsDoubleValueSet = U_SUCCESS(status) && !digits.isOverMaxDigits();
        // Adjust for negative 0 becuase when we cast to an int64,
        // negative 0 becomes positive 0.
        if (scaled == 0.0 && uprv_isNegative(scaled)) {
            digits.setNegative();
        }
        return digits;
    }

    // Oops have to use digit list
    DigitList digitList;
    digitList.set(value);
    return initVisibleDigits(digitList, digits, status);
}

UBool
FixedPrecision::initVisibleDigits(
        int64_t mantissa,
        int32_t exponent,
        VisibleDigits &digits,
        UErrorCode &status) const {
    if (U_FAILURE(status)) {
        return TRUE;
    }
    digits.clear();

    // Precompute fAbsIntValue if it is small enough, but we don't know yet
    // if it will be valid.
    UBool absIntValueComputed = FALSE;
    if (mantissa > -1000000000000000000LL /* -1e18 */
            && mantissa < 1000000000000000000LL /* 1e18 */) {
        digits.fAbsIntValue = mantissa;
        if (digits.fAbsIntValue < 0) {
            digits.fAbsIntValue = -digits.fAbsIntValue;
        }
        int32_t i = 0;
        int32_t maxPower10Exp = UPRV_LENGTHOF(gPower10) - 1;
        for (; i > exponent + maxPower10Exp; i -= maxPower10Exp) {
            digits.fAbsIntValue /= gPower10[maxPower10Exp];
        }
        digits.fAbsIntValue /= gPower10[i - exponent];
        absIntValueComputed = TRUE;
    }
    if (mantissa == 0) {
        getIntervalForZero(digits.fInterval);
        digits.fAbsIntValueSet = absIntValueComputed;
        return TRUE;
    }
    // be sure least significant digit is non zero
    while (mantissa % 10 == 0) {
        mantissa /= 10;
        ++exponent;
    }
    if (mantissa < 0) {
        digits.fDigits.append((char) -(mantissa % -10), status);
        mantissa /= -10;
        digits.setNegative();
    }
    while (mantissa) {
        digits.fDigits.append((char) (mantissa % 10), status);
        mantissa /= 10;
    }
    if (U_FAILURE(status)) {
        return TRUE;
    }
    digits.fExponent = exponent;
    int32_t upperExponent = exponent + digits.fDigits.length();
    if (fFailIfOverMax && upperExponent > fMax.getIntDigitCount()) {
        status = U_ILLEGAL_ARGUMENT_ERROR;
        return TRUE;
    }
    UBool roundingRequired =
            isRoundingRequired(upperExponent, exponent);
    if (roundingRequired) {
        if (fExactOnly) {
            status = U_FORMAT_INEXACT_ERROR;
            return TRUE;
        }
        return FALSE;
    }
    digits.fInterval.setLeastSignificantInclusive(exponent);
    digits.fInterval.setMostSignificantExclusive(upperExponent);
    getInterval(upperExponent, digits.fInterval);

    // The intValue we computed above is only valid if our visible digits
    // doesn't exceed the maximum integer digits allowed.
    digits.fAbsIntValueSet = absIntValueComputed && !digits.isOverMaxDigits();
    return TRUE;
}

VisibleDigitsWithExponent &
FixedPrecision::initVisibleDigitsWithExponent(
        DigitList &value,
        VisibleDigitsWithExponent &digits,
        UErrorCode &status) const {
    digits.clear();
    initVisibleDigits(value, digits.fMantissa, status);
    return digits;
}

VisibleDigitsWithExponent &
FixedPrecision::initVisibleDigitsWithExponent(
        double value,
        VisibleDigitsWithExponent &digits,
        UErrorCode &status) const {
    digits.clear();
    initVisibleDigits(value, digits.fMantissa, status);
    return digits;
}

VisibleDigitsWithExponent &
FixedPrecision::initVisibleDigitsWithExponent(
        int64_t value,
        VisibleDigitsWithExponent &digits,
        UErrorCode &status) const {
    digits.clear();
    initVisibleDigits(value, digits.fMantissa, status);
    return digits;
}

ScientificPrecision::ScientificPrecision() : fMinExponentDigits(1) {
}

DigitList &
ScientificPrecision::round(DigitList &value, UErrorCode &status) const {
    if (U_FAILURE(status)) {
        return value;
    }
    int32_t exponent = value.getScientificExponent(
            fMantissa.fMin.getIntDigitCount(), getMultiplier());
    return fMantissa.round(value, exponent, status);
}

int32_t
ScientificPrecision::toScientific(DigitList &value) const {
    return value.toScientific(
            fMantissa.fMin.getIntDigitCount(), getMultiplier());
}

int32_t
ScientificPrecision::getMultiplier() const {
    int32_t maxIntDigitCount = fMantissa.fMax.getIntDigitCount();
    if (maxIntDigitCount == INT32_MAX) {
        return 1;
    }
    int32_t multiplier =
        maxIntDigitCount - fMantissa.fMin.getIntDigitCount() + 1;
    return (multiplier < 1 ? 1 : multiplier);
}

VisibleDigitsWithExponent &
ScientificPrecision::initVisibleDigitsWithExponent(
        DigitList &value,
        VisibleDigitsWithExponent &digits,
        UErrorCode &status) const {
    if (U_FAILURE(status)) {
        return digits;
    }
    digits.clear();
    if (FixedPrecision::handleNonNumeric(value, digits.fMantissa)) {
        return digits;
    }
    value.setRoundingMode(fMantissa.fRoundingMode);
    int64_t exponent = toScientific(round(value, status));
    fMantissa.initVisibleDigits(value, digits.fMantissa, status);
    FixedPrecision exponentPrecision;
    exponentPrecision.fMin.setIntDigitCount(fMinExponentDigits);
    exponentPrecision.initVisibleDigits(exponent, digits.fExponent, status);
    digits.fHasExponent = TRUE;
    return digits;
}

VisibleDigitsWithExponent &
ScientificPrecision::initVisibleDigitsWithExponent(
        double value,
        VisibleDigitsWithExponent &digits,
        UErrorCode &status) const {
    if (U_FAILURE(status)) {
        return digits;
    }
    DigitList digitList;
    digitList.set(value);
    return initVisibleDigitsWithExponent(digitList, digits, status);
}

VisibleDigitsWithExponent &
ScientificPrecision::initVisibleDigitsWithExponent(
        int64_t value,
        VisibleDigitsWithExponent &digits,
        UErrorCode &status) const {
    if (U_FAILURE(status)) {
        return digits;
    }
    DigitList digitList;
    digitList.set(value);
    return initVisibleDigitsWithExponent(digitList, digits, status);
}


U_NAMESPACE_END
#endif /* #if !UCONFIG_NO_FORMATTING */
Commit	Line	Data
f3c0d7a5 A	1	// © 2016 and later: Unicode, Inc. and others.
f3c0d7a5 A	2	// License & terms of use: http://www.unicode.org/copyright.html
2ca993e8 A	3	/*
	4	* Copyright (C) 2015, International Business Machines
	5	* Corporation and others. All Rights Reserved.
	6	*
	7	* file name: precisison.cpp
	8	*/
	9
	10	#include <math.h>
	11
	12	#include "unicode/utypes.h"
	13
	14	#if !UCONFIG_NO_FORMATTING
	15
	16	#include "digitlst.h"
	17	#include "fmtableimp.h"
	18	#include "precision.h"
	19	#include "putilimp.h"
	20	#include "visibledigits.h"
	21
	22	U_NAMESPACE_BEGIN
	23
	24	static const int32_t gPower10[] = {1, 10, 100, 1000};
	25
	26	FixedPrecision::FixedPrecision()
	27	: fExactOnly(FALSE), fFailIfOverMax(FALSE), fRoundingMode(DecimalFormat::kRoundHalfEven) {
	28	fMin.setIntDigitCount(1);
	29	fMin.setFracDigitCount(0);
	30	}
	31
	32	UBool
	33	FixedPrecision::isRoundingRequired(
	34	int32_t upperExponent, int32_t lowerExponent) const {
	35	int32_t leastSigAllowed = fMax.getLeastSignificantInclusive();
	36	int32_t maxSignificantDigits = fSignificant.getMax();
	37	int32_t roundDigit;
	38	if (maxSignificantDigits == INT32_MAX) {
	39	roundDigit = leastSigAllowed;
	40	} else {
	41	int32_t limitDigit = upperExponent - maxSignificantDigits;
	42	roundDigit =
	43	limitDigit > leastSigAllowed ? limitDigit : leastSigAllowed;
	44	}
	45	return (roundDigit > lowerExponent);
	46	}
	47
	48	DigitList &
	49	FixedPrecision::round(
	50	DigitList &value, int32_t exponent, UErrorCode &status) const {
	51	if (U_FAILURE(status)) {
	52	return value;
	53	}
	54	value .fContext.status &= ~DEC_Inexact;
	55	if (!fRoundingIncrement.isZero()) {
	56	if (exponent == 0) {
	57	value.quantize(fRoundingIncrement, status);
	58	} else {
	59	DigitList adjustedIncrement(fRoundingIncrement);
	60	adjustedIncrement.shiftDecimalRight(exponent);
	61	value.quantize(adjustedIncrement, status);
	62	}
	63	if (U_FAILURE(status)) {
	64	return value;
	65	}
	66	}
67	int32_t leastSig = fMax.getLeastSignificantInclusive();
68	if (leastSig == INT32_MIN) {
69	value.round(fSignificant.getMax());
70	} else {
71	value.roundAtExponent(
72	exponent + leastSig,
73	fSignificant.getMax());
74	}
75	if (fExactOnly && (value.fContext.status & DEC_Inexact)) {
76	status = U_FORMAT_INEXACT_ERROR;
77	} else if (fFailIfOverMax) {
78	// Smallest interval for value stored in interval
79	DigitInterval interval;
80	value.getSmallestInterval(interval);
81	if (fMax.getIntDigitCount() < interval.getIntDigitCount()) {
82	status = U_ILLEGAL_ARGUMENT_ERROR;
83	}
84	}
85	return value;
86	}
87
88	DigitInterval &
89	FixedPrecision::getIntervalForZero(DigitInterval &interval) const {
90	interval = fMin;
91	if (fSignificant.getMin() > 0) {
92	interval.expandToContainDigit(interval.getIntDigitCount() - fSignificant.getMin());
93	}
94	interval.shrinkToFitWithin(fMax);
95	return interval;
96	}
97
98	DigitInterval &
99	FixedPrecision::getInterval(
100	int32_t upperExponent, DigitInterval &interval) const {
101	if (fSignificant.getMin() > 0) {
102	interval.expandToContainDigit(
103	upperExponent - fSignificant.getMin());
104	}
105	interval.expandToContain(fMin);
106	interval.shrinkToFitWithin(fMax);
107	return interval;
108	}
109
110	DigitInterval &
111	FixedPrecision::getInterval(
112	const DigitList &value, DigitInterval &interval) const {
113	if (value.isZero()) {
114	interval = fMin;
115	if (fSignificant.getMin() > 0) {
116	interval.expandToContainDigit(interval.getIntDigitCount() - fSignificant.getMin());
117	}
118	} else {
119	value.getSmallestInterval(interval);
120	if (fSignificant.getMin() > 0) {
121	interval.expandToContainDigit(
122	value.getUpperExponent() - fSignificant.getMin());
123	}
124	interval.expandToContain(fMin);
125	}
126	interval.shrinkToFitWithin(fMax);
127	return interval;
128	}
129
130	UBool
131	FixedPrecision::isFastFormattable() const {
132	return (fMin.getFracDigitCount() == 0 && fSignificant.isNoConstraints() && fRoundingIncrement.isZero() && !fFailIfOverMax);
133	}
134
135	UBool
136	FixedPrecision::handleNonNumeric(DigitList &value, VisibleDigits &digits) {
137	if (value.isNaN()) {
138	digits.setNaN();
139	return TRUE;
140	}
141	if (value.isInfinite()) {
142	digits.setInfinite();
143	if (!value.isPositive()) {
144	digits.setNegative();
145	}
146	return TRUE;
147	}
148	return FALSE;
149	}
150
151	VisibleDigits &
152	FixedPrecision::initVisibleDigits(
153	DigitList &value,
154	VisibleDigits &digits,
155	UErrorCode &status) const {
156	if (U_FAILURE(status)) {
157	return digits;
158	}
159	digits.clear();
160	if (handleNonNumeric(value, digits)) {
161	return digits;
162	}
163	if (!value.isPositive()) {
164	digits.setNegative();
165	}
166	value.setRoundingMode(fRoundingMode);
167	round(value, 0, status);
168	getInterval(value, digits.fInterval);
169	digits.fExponent = value.getLowerExponent();
170	value.appendDigitsTo(digits.fDigits, status);
171	return digits;
172	}
173
174	VisibleDigits &
175	FixedPrecision::initVisibleDigits(
176	int64_t value,
177	VisibleDigits &digits,
178	UErrorCode &status) const {
179	if (U_FAILURE(status)) {
180	return digits;
181	}
182	if (!fRoundingIncrement.isZero()) {
183	// If we have round increment, use digit list.
184	DigitList digitList;
185	digitList.set(value);
186	return initVisibleDigits(digitList, digits, status);
187	}
188	// Try fast path
189	if (initVisibleDigits(value, 0, digits, status)) {
190	digits.fAbsDoubleValue = fabs((double) value);
191	digits.fAbsDoubleValueSet = U_SUCCESS(status) && !digits.isOverMaxDigits();
192	return digits;
193	}
194	// Oops have to use digit list
195	DigitList digitList;
196	digitList.set(value);
197	return initVisibleDigits(digitList, digits, status);
198	}
199
200	VisibleDigits &
201	FixedPrecision::initVisibleDigits(
202	double value,
203	VisibleDigits &digits,
204	UErrorCode &status) const {
205	if (U_FAILURE(status)) {
206	return digits;
207	}
208	digits.clear();
209	if (uprv_isNaN(value)) {
210	digits.setNaN();
211	return digits;
212	}
213	if (uprv_isPositiveInfinity(value)) {
214	digits.setInfinite();
215	return digits;
216	}
217	if (uprv_isNegativeInfinity(value)) {
218	digits.setInfinite();
219	digits.setNegative();
220	return digits;
221	}
222	if (!fRoundingIncrement.isZero()) {
223	// If we have round increment, use digit list.
224	DigitList digitList;
225	digitList.set(value);
226	return initVisibleDigits(digitList, digits, status);
227	}
228	// Try to find n such that value * 10^n is an integer
229	int32_t n = -1;
230	double scaled;
231	for (int32_t i = 0; i < UPRV_LENGTHOF(gPower10); ++i) {
232	scaled = value * gPower10[i];
233	if (scaled > MAX_INT64_IN_DOUBLE \|\| scaled < -MAX_INT64_IN_DOUBLE) {
234	break;
235	}
236	if (scaled == floor(scaled)) {
237	n = i;
238	break;
239	}
240	}
241	// Try fast path
242	if (n >= 0 && initVisibleDigits(scaled, -n, digits, status)) {
243	digits.fAbsDoubleValue = fabs(value);
244	digits.fAbsDoubleValueSet = U_SUCCESS(status) && !digits.isOverMaxDigits();
245	// Adjust for negative 0 becuase when we cast to an int64,
246	// negative 0 becomes positive 0.
247	if (scaled == 0.0 && uprv_isNegative(scaled)) {
248	digits.setNegative();
249	}
250	return digits;
251	}
252
253	// Oops have to use digit list
254	DigitList digitList;
255	digitList.set(value);
256	return initVisibleDigits(digitList, digits, status);
257	}
258
259	UBool
260	FixedPrecision::initVisibleDigits(
261	int64_t mantissa,
262	int32_t exponent,
263	VisibleDigits &digits,
264	UErrorCode &status) const {
265	if (U_FAILURE(status)) {
266	return TRUE;
267	}
268	digits.clear();
269
270	// Precompute fAbsIntValue if it is small enough, but we don't know yet
271	// if it will be valid.
272	UBool absIntValueComputed = FALSE;
273	if (mantissa > -1000000000000000000LL /* -1e18 */
274	&& mantissa < 1000000000000000000LL /* 1e18 */) {
275	digits.fAbsIntValue = mantissa;
276	if (digits.fAbsIntValue < 0) {
277	digits.fAbsIntValue = -digits.fAbsIntValue;
278	}
279	int32_t i = 0;
280	int32_t maxPower10Exp = UPRV_LENGTHOF(gPower10) - 1;
281	for (; i > exponent + maxPower10Exp; i -= maxPower10Exp) {
282	digits.fAbsIntValue /= gPower10[maxPower10Exp];
283	}
284	digits.fAbsIntValue /= gPower10[i - exponent];
285	absIntValueComputed = TRUE;
286	}
287	if (mantissa == 0) {
288	getIntervalForZero(digits.fInterval);
289	digits.fAbsIntValueSet = absIntValueComputed;
290	return TRUE;
291	}
292	// be sure least significant digit is non zero
293	while (mantissa % 10 == 0) {
294	mantissa /= 10;
295	++exponent;
296	}
297	if (mantissa < 0) {
298	digits.fDigits.append((char) -(mantissa % -10), status);
299	mantissa /= -10;
300	digits.setNegative();
301	}
302	while (mantissa) {
303	digits.fDigits.append((char) (mantissa % 10), status);
304	mantissa /= 10;
305	}
306	if (U_FAILURE(status)) {
307	return TRUE;
308	}
309	digits.fExponent = exponent;
310	int32_t upperExponent = exponent + digits.fDigits.length();
311	if (fFailIfOverMax && upperExponent > fMax.getIntDigitCount()) {
312	status = U_ILLEGAL_ARGUMENT_ERROR;
313	return TRUE;
314	}
315	UBool roundingRequired =
316	isRoundingRequired(upperExponent, exponent);
317	if (roundingRequired) {
318	if (fExactOnly) {
319	status = U_FORMAT_INEXACT_ERROR;
320	return TRUE;
321	}
322	return FALSE;
323	}
324	digits.fInterval.setLeastSignificantInclusive(exponent);
325	digits.fInterval.setMostSignificantExclusive(upperExponent);
326	getInterval(upperExponent, digits.fInterval);
327
328	// The intValue we computed above is only valid if our visible digits
329	// doesn't exceed the maximum integer digits allowed.
330	digits.fAbsIntValueSet = absIntValueComputed && !digits.isOverMaxDigits();
331	return TRUE;
332	}
333
334	VisibleDigitsWithExponent &
335	FixedPrecision::initVisibleDigitsWithExponent(
336	DigitList &value,
337	VisibleDigitsWithExponent &digits,
338	UErrorCode &status) const {
339	digits.clear();
340	initVisibleDigits(value, digits.fMantissa, status);
341	return digits;
342	}
343
344	VisibleDigitsWithExponent &
345	FixedPrecision::initVisibleDigitsWithExponent(
346	double value,
347	VisibleDigitsWithExponent &digits,
348	UErrorCode &status) const {
349	digits.clear();
350	initVisibleDigits(value, digits.fMantissa, status);
351	return digits;
352	}
353
354	VisibleDigitsWithExponent &
355	FixedPrecision::initVisibleDigitsWithExponent(
356	int64_t value,
357	VisibleDigitsWithExponent &digits,
358	UErrorCode &status) const {
359	digits.clear();
360	initVisibleDigits(value, digits.fMantissa, status);
361	return digits;
362	}
363
364	ScientificPrecision::ScientificPrecision() : fMinExponentDigits(1) {
365	}
366
367	DigitList &
368	ScientificPrecision::round(DigitList &value, UErrorCode &status) const {
369	if (U_FAILURE(status)) {
370	return value;
371	}
372	int32_t exponent = value.getScientificExponent(
373	fMantissa.fMin.getIntDigitCount(), getMultiplier());
374	return fMantissa.round(value, exponent, status);
375	}
376
377	int32_t
378	ScientificPrecision::toScientific(DigitList &value) const {
379	return value.toScientific(
380	fMantissa.fMin.getIntDigitCount(), getMultiplier());
381	}
382
383	int32_t
384	ScientificPrecision::getMultiplier() const {
385	int32_t maxIntDigitCount = fMantissa.fMax.getIntDigitCount();
386	if (maxIntDigitCount == INT32_MAX) {
387	return 1;
388	}
389	int32_t multiplier =
390	maxIntDigitCount - fMantissa.fMin.getIntDigitCount() + 1;
391	return (multiplier < 1 ? 1 : multiplier);
392	}
393
394	VisibleDigitsWithExponent &
395	ScientificPrecision::initVisibleDigitsWithExponent(
396	DigitList &value,
397	VisibleDigitsWithExponent &digits,
398	UErrorCode &status) const {
399	if (U_FAILURE(status)) {
400	return digits;
401	}
402	digits.clear();
403	if (FixedPrecision::handleNonNumeric(value, digits.fMantissa)) {
404	return digits;
405	}
406	value.setRoundingMode(fMantissa.fRoundingMode);
407	int64_t exponent = toScientific(round(value, status));
408	fMantissa.initVisibleDigits(value, digits.fMantissa, status);
409	FixedPrecision exponentPrecision;
410	exponentPrecision.fMin.setIntDigitCount(fMinExponentDigits);
411	exponentPrecision.initVisibleDigits(exponent, digits.fExponent, status);
412	digits.fHasExponent = TRUE;
413	return digits;
414	}
415
416	VisibleDigitsWithExponent &
417	ScientificPrecision::initVisibleDigitsWithExponent(
418	double value,
419	VisibleDigitsWithExponent &digits,
420	UErrorCode &status) const {
421	if (U_FAILURE(status)) {
422	return digits;
423	}
424	DigitList digitList;
425	digitList.set(value);
426	return initVisibleDigitsWithExponent(digitList, digits, status);
427	}
428
429	VisibleDigitsWithExponent &
430	ScientificPrecision::initVisibleDigitsWithExponent(
431	int64_t value,
432	VisibleDigitsWithExponent &digits,
433	UErrorCode &status) const {
434	if (U_FAILURE(status)) {
435	return digits;
436	}
437	DigitList digitList;
438	digitList.set(value);
439	return initVisibleDigitsWithExponent(digitList, digits, status);
440	}
441
442
443	U_NAMESPACE_END
444	#endif /* #if !UCONFIG_NO_FORMATTING */