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cobalt / cobalt / b95ea55ccebda33f820d043e4b4dc85c10d7584d / . / third_party / icu / source / i18n / units_complexconverter.cpp
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// © 2020 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 <cmath>
#include "cmemory.h"
#include "number_decimalquantity.h"
#include "number_roundingutils.h"
#include "uarrsort.h"
#include "uassert.h"
#include "unicode/fmtable.h"
#include "unicode/localpointer.h"
#include "unicode/measunit.h"
#include "unicode/measure.h"
#include "units_complexconverter.h"
#include "units_converter.h"
U_NAMESPACE_BEGIN
namespace units {
ComplexUnitsConverter::ComplexUnitsConverter(const MeasureUnitImpl &inputUnit,
const MeasureUnitImpl &outputUnits,
const ConversionRates &ratesInfo, UErrorCode &status)
: units_(outputUnits.extractIndividualUnits(status)) {
if (U_FAILURE(status)) {
return;
}
U_ASSERT(units_.length() != 0);
// Save the desired order of output units before we sort units_
for (int32_t i = 0; i < units_.length(); i++) {
outputUnits_.emplaceBackAndCheckErrorCode(status, units_[i]->copy(status).build(status));
}
// NOTE:
// This comparator is used to sort the units in a descending order. Therefore, we return -1 if
// the left is bigger than right and so on.
auto descendingCompareUnits = [](const void *context, const void *left, const void *right) {
UErrorCode status = U_ZERO_ERROR;
const auto *leftPointer = static_cast<const MeasureUnitImpl *const *>(left);
const auto *rightPointer = static_cast<const MeasureUnitImpl *const *>(right);
UnitConverter fromLeftToRight(**leftPointer, //
**rightPointer, //
*static_cast<const ConversionRates *>(context), //
status);
double rightFromOneLeft = fromLeftToRight.convert(1.0);
if (std::abs(rightFromOneLeft - 1.0) < 0.0000000001) { // Equals To
return 0;
} else if (rightFromOneLeft > 1.0) { // Greater Than
return -1;
}
return 1; // Less Than
};
uprv_sortArray(units_.getAlias(), //
units_.length(), //
sizeof units_[0], /* NOTE: we have already asserted that the units_ is not empty.*/ //
descendingCompareUnits, //
&ratesInfo, //
false, //
&status //
);
// In case the `outputUnits` are `UMEASURE_UNIT_MIXED` such as `foot+inch`. In this case we need more
// converters to convert from the `inputUnit` to the first unit in the `outputUnits`. Then, a
// converter from the first unit in the `outputUnits` to the second unit and so on.
// For Example:
// - inputUnit is `meter`
// - outputUnits is `foot+inch`
// - Therefore, we need to have two converters:
// 1. a converter from `meter` to `foot`
// 2. a converter from `foot` to `inch`
// - Therefore, if the input is `2 meter`:
// 1. convert `meter` to `foot` --> 2 meter to 6.56168 feet
// 2. convert the residual of 6.56168 feet (0.56168) to inches, which will be (6.74016
// inches)
// 3. then, the final result will be (6 feet and 6.74016 inches)
for (int i = 0, n = units_.length(); i < n; i++) {
if (i == 0) { // first element
unitConverters_.emplaceBackAndCheckErrorCode(status, inputUnit, *units_[i], ratesInfo,
status);
} else {
unitConverters_.emplaceBackAndCheckErrorCode(status, *units_[i - 1], *units_[i], ratesInfo,
status);
}
if (U_FAILURE(status)) {
return;
}
}
}
UBool ComplexUnitsConverter::greaterThanOrEqual(double quantity, double limit) const {
U_ASSERT(unitConverters_.length() > 0);
// First converter converts to the biggest quantity.
double newQuantity = unitConverters_[0]->convert(quantity);
return newQuantity >= limit;
}
MaybeStackVector<Measure> ComplexUnitsConverter::convert(double quantity,
icu::number::impl::RoundingImpl *rounder,
UErrorCode &status) const {
// TODO(hugovdm): return an error for "foot-and-foot"?
MaybeStackVector<Measure> result;
int sign = 1;
if (quantity < 0) {
quantity *= -1;
sign = -1;
}
// For N converters:
// - the first converter converts from the input unit to the largest unit,
// - N-1 converters convert to bigger units for which we want integers,
// - the Nth converter (index N-1) converts to the smallest unit, for which
// we keep a double.
MaybeStackArray<int64_t, 5> intValues(unitConverters_.length() - 1, status);
if (U_FAILURE(status)) {
return result;
}
uprv_memset(intValues.getAlias(), 0, (unitConverters_.length() - 1) * sizeof(int64_t));
for (int i = 0, n = unitConverters_.length(); i < n; ++i) {
quantity = (*unitConverters_[i]).convert(quantity);
if (i < n - 1) {
// The double type has 15 decimal digits of precision. For choosing
// whether to use the current unit or the next smaller unit, we
// therefore nudge up the number with which the thresholding
// decision is made. However after the thresholding, we use the
// original values to ensure unbiased accuracy (to the extent of
// double's capabilities).
int64_t roundedQuantity = floor(quantity * (1 + DBL_EPSILON));
intValues[i] = roundedQuantity;
// Keep the residual of the quantity.
// For example: `3.6 feet`, keep only `0.6 feet`
//
// When the calculation is near enough +/- DBL_EPSILON, we round to
// zero. (We also ensure no negative values here.)
if ((quantity - roundedQuantity) / quantity < DBL_EPSILON) {
quantity = 0;
} else {
quantity -= roundedQuantity;
}
} else { // LAST ELEMENT
if (rounder == nullptr) {
// Nothing to do for the last element.
break;
}
// Round the last value
// TODO(ICU-21288): get smarter about precision for mixed units.
number::impl::DecimalQuantity quant;
quant.setToDouble(quantity);
rounder->apply(quant, status);
if (U_FAILURE(status)) {
return result;
}
quantity = quant.toDouble();
if (i == 0) {
// Last element is also the first element, so we're done
break;
}
// Check if there's a carry, and bubble it back up the resulting intValues.
int64_t carry = floor(unitConverters_[i]->convertInverse(quantity) * (1 + DBL_EPSILON));
if (carry <= 0) {
break;
}
quantity -= unitConverters_[i]->convert(carry);
intValues[i - 1] += carry;
// We don't use the first converter: that one is for the input unit
for (int32_t j = i - 1; j > 0; j--) {
carry = floor(unitConverters_[j]->convertInverse(intValues[j]) * (1 + DBL_EPSILON));
if (carry <= 0) {
break;
}
intValues[j] -= round(unitConverters_[j]->convert(carry));
intValues[j - 1] += carry;
}
}
}
// Package values into Measure instances in result:
for (int i = 0, n = unitConverters_.length(); i < n; ++i) {
if (i < n - 1) {
Formattable formattableQuantity(intValues[i] * sign);
// Measure takes ownership of the MeasureUnit*
MeasureUnit *type = new MeasureUnit(units_[i]->copy(status).build(status));
if (result.emplaceBackAndCheckErrorCode(status, formattableQuantity, type, status) ==
nullptr) {
// Ownership wasn't taken
U_ASSERT(U_FAILURE(status));
delete type;
}
if (U_FAILURE(status)) {
return result;
}
} else { // LAST ELEMENT
// Add the last element, not an integer:
Formattable formattableQuantity(quantity * sign);
// Measure takes ownership of the MeasureUnit*
MeasureUnit *type = new MeasureUnit(units_[i]->copy(status).build(status));
if (result.emplaceBackAndCheckErrorCode(status, formattableQuantity, type, status) ==
nullptr) {
// Ownership wasn't taken
U_ASSERT(U_FAILURE(status));
delete type;
}
if (U_FAILURE(status)) {
return result;
}
U_ASSERT(result.length() == i + 1);
U_ASSERT(result[i] != nullptr);
}
}
MaybeStackVector<Measure> orderedResult;
int32_t unitsCount = outputUnits_.length();
U_ASSERT(unitsCount == units_.length());
Measure **arr = result.getAlias();
// O(N^2) is fine: mixed units' unitsCount is usually 2 or 3.
for (int32_t i = 0; i < unitsCount; i++) {
for (int32_t j = i; j < unitsCount; j++) {
// Find the next expected unit, and swap it into place.
U_ASSERT(result[j] != nullptr);
if (result[j]->getUnit() == *outputUnits_[i]) {
if (j != i) {
Measure *tmp = arr[j];
arr[j] = arr[i];
arr[i] = tmp;
}
}
}
}
return result;
}
} // namespace units
U_NAMESPACE_END
#endif /* #if !UCONFIG_NO_FORMATTING */