// © 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
#ifndef __NUMBER_DECIMALQUANTITY_H__
#define __NUMBER_DECIMALQUANTITY_H__
#include <cstdint>
#include "unicode/umachine.h"
#include "standardplural.h"
#include "plurrule_impl.h"
#include "number_types.h"
U_NAMESPACE_BEGIN namespace number {
namespace impl {
// Forward-declare (maybe don't want number_utils.h included here):
class DecNum;
/**
* An class for representing a number to be processed by the decimal formatting pipeline. Includes
* methods for rounding, plural rules, and decimal digit extraction.
*
* <p>By design, this is NOT IMMUTABLE and NOT THREAD SAFE. It is intended to be an intermediate
* object holding state during a pass through the decimal formatting pipeline.
*
* <p>Represents numbers and digit display properties using Binary Coded Decimal (BCD).
*
* <p>Java has multiple implementations for testing, but C++ has only one implementation.
*/
class U_I18N_API DecimalQuantity : public IFixedDecimal, public UMemory {
public:
/** Copy constructor. */
DecimalQuantity(const DecimalQuantity &other);
/** Move constructor. */
DecimalQuantity(DecimalQuantity &&src) U_NOEXCEPT;
DecimalQuantity();
~DecimalQuantity() override;
/**
* Sets this instance to be equal to another instance.
*
* @param other The instance to copy from.
*/
DecimalQuantity &operator=(const DecimalQuantity &other);
/** Move assignment */
DecimalQuantity &operator=(DecimalQuantity&& src) U_NOEXCEPT;
/**
* Sets the minimum and maximum integer digits that this {@link DecimalQuantity} should generate.
* This method does not perform rounding.
*
* @param minInt The minimum number of integer digits.
* @param maxInt The maximum number of integer digits.
*/
void setIntegerLength(int32_t minInt, int32_t maxInt);
/**
* Sets the minimum and maximum fraction digits that this {@link DecimalQuantity} should generate.
* This method does not perform rounding.
*
* @param minFrac The minimum number of fraction digits.
* @param maxFrac The maximum number of fraction digits.
*/
void setFractionLength(int32_t minFrac, int32_t maxFrac);
/**
* Rounds the number to a specified interval, such as 0.05.
*
* <p>If rounding to a power of ten, use the more efficient {@link #roundToMagnitude} instead.
*
* @param roundingIncrement The increment to which to round.
* @param mathContext The {@link RoundingMode} to use if rounding is necessary.
*/
void roundToIncrement(double roundingIncrement, RoundingMode roundingMode,
int32_t maxFrac, UErrorCode& status);
/** Removes all fraction digits. */
void truncate();
/**
* Rounds the number to a specified magnitude (power of ten).
*
* @param roundingMagnitude The power of ten to which to round. For example, a value of -2 will
* round to 2 decimal places.
* @param mathContext The {@link RoundingMode} to use if rounding is necessary.
*/
void roundToMagnitude(int32_t magnitude, RoundingMode roundingMode, UErrorCode& status);
/**
* Rounds the number to an infinite number of decimal points. This has no effect except for
* forcing the double in {@link DecimalQuantity_AbstractBCD} to adopt its exact representation.
*/
void roundToInfinity();
/**
* Multiply the internal value. Uses decNumber.
*
* @param multiplicand The value by which to multiply.
*/
void multiplyBy(const DecNum& multiplicand, UErrorCode& status);
/**
* Divide the internal value. Uses decNumber.
*
* @param multiplicand The value by which to multiply.
*/
void divideBy(const DecNum& divisor, UErrorCode& status);
/** Flips the sign from positive to negative and back. */
void negate();
/**
* Scales the number by a power of ten. For example, if the value is currently "1234.56", calling
* this method with delta=-3 will change the value to "1.23456".
*
* @param delta The number of magnitudes of ten to change by.
* @return true if integer overflow occured; false otherwise.
*/
bool adjustMagnitude(int32_t delta);
/**
* @return The power of ten corresponding to the most significant nonzero digit.
* The number must not be zero.
*/
int32_t getMagnitude() const;
/** @return Whether the value represented by this {@link DecimalQuantity} is zero. */
bool isZero() const;
/** @return Whether the value represented by this {@link DecimalQuantity} is less than zero. */
bool isNegative() const;
/** @return -1 if the value is negative; 1 if positive; or 0 if zero. */
int8_t signum() const;
/** @return Whether the value represented by this {@link DecimalQuantity} is infinite. */
bool isInfinite() const U_OVERRIDE;
/** @return Whether the value represented by this {@link DecimalQuantity} is not a number. */
bool isNaN() const U_OVERRIDE;
/** @param truncateIfOverflow if false and the number does NOT fit, fails with an assertion error. */
int64_t toLong(bool truncateIfOverflow = false) const;
uint64_t toFractionLong(bool includeTrailingZeros) const;
/**
* Returns whether or not a Long can fully represent the value stored in this DecimalQuantity.
* @param ignoreFraction if true, silently ignore digits after the decimal place.
*/
bool fitsInLong(bool ignoreFraction = false) const;
/** @return The value contained in this {@link DecimalQuantity} approximated as a double. */
double toDouble() const;
/** Computes a DecNum representation of this DecimalQuantity, saving it to the output parameter. */
void toDecNum(DecNum& output, UErrorCode& status) const;
DecimalQuantity &setToInt(int32_t n);
DecimalQuantity &setToLong(int64_t n);
DecimalQuantity &setToDouble(double n);
/** decNumber is similar to BigDecimal in Java. */
DecimalQuantity &setToDecNumber(StringPiece n, UErrorCode& status);
/** Internal method if the caller already has a DecNum. */
DecimalQuantity &setToDecNum(const DecNum& n, UErrorCode& status);
/**
* Appends a digit, optionally with one or more leading zeros, to the end of the value represented
* by this DecimalQuantity.
*
* <p>The primary use of this method is to construct numbers during a parsing loop. It allows
* parsing to take advantage of the digit list infrastructure primarily designed for formatting.
*
* @param value The digit to append.
* @param leadingZeros The number of zeros to append before the digit. For example, if the value
* in this instance starts as 12.3, and you append a 4 with 1 leading zero, the value becomes
* 12.304.
* @param appendAsInteger If true, increase the magnitude of existing digits to make room for the
* new digit. If false, append to the end like a fraction digit. If true, there must not be
* any fraction digits already in the number.
* @internal
* @deprecated This API is ICU internal only.
*/
void appendDigit(int8_t value, int32_t leadingZeros, bool appendAsInteger);
double getPluralOperand(PluralOperand operand) const U_OVERRIDE;
bool hasIntegerValue() const U_OVERRIDE;
/**
* Gets the digit at the specified magnitude. For example, if the represented number is 12.3,
* getDigit(-1) returns 3, since 3 is the digit corresponding to 10^-1.
*
* @param magnitude The magnitude of the digit.
* @return The digit at the specified magnitude.
*/
int8_t getDigit(int32_t magnitude) const;
/**
* Gets the largest power of ten that needs to be displayed. The value returned by this function
* will be bounded between minInt and maxInt.
*
* @return The highest-magnitude digit to be displayed.
*/
int32_t getUpperDisplayMagnitude() const;
/**
* Gets the smallest power of ten that needs to be displayed. The value returned by this function
* will be bounded between -minFrac and -maxFrac.
*
* @return The lowest-magnitude digit to be displayed.
*/
int32_t getLowerDisplayMagnitude() const;
int32_t fractionCount() const;
int32_t fractionCountWithoutTrailingZeros() const;
void clear();
/** This method is for internal testing only. */
uint64_t getPositionFingerprint() const;
// /**
// * If the given {@link FieldPosition} is a {@link UFieldPosition}, populates it with the fraction
// * length and fraction long value. If the argument is not a {@link UFieldPosition}, nothing
// * happens.
// *
// * @param fp The {@link UFieldPosition} to populate.
// */
// void populateUFieldPosition(FieldPosition fp);
/**
* Checks whether the bytes stored in this instance are all valid. For internal unit testing only.
*
* @return An error message if this instance is invalid, or null if this instance is healthy.
*/
const char16_t* checkHealth() const;
UnicodeString toString() const;
/** Returns the string in standard exponential notation. */
UnicodeString toScientificString() const;
/** Returns the string without exponential notation. Slightly slower than toScientificString(). */
UnicodeString toPlainString() const;
/** Visible for testing */
inline bool isUsingBytes() { return usingBytes; }
/** Visible for testing */
inline bool isExplicitExactDouble() { return explicitExactDouble; };
bool operator==(const DecimalQuantity& other) const;
inline bool operator!=(const DecimalQuantity& other) const {
return !(*this == other);
}
/**
* Bogus flag for when a DecimalQuantity is stored on the stack.
*/
bool bogus = false;
private:
/**
* The power of ten corresponding to the least significant digit in the BCD. For example, if this
* object represents the number "3.14", the BCD will be "0x314" and the scale will be -2.
*
* <p>Note that in {@link java.math.BigDecimal}, the scale is defined differently: the number of
* digits after the decimal place, which is the negative of our definition of scale.
*/
int32_t scale;
/**
* The number of digits in the BCD. For example, "1007" has BCD "0x1007" and precision 4. The
* maximum precision is 16 since a long can hold only 16 digits.
*
* <p>This value must be re-calculated whenever the value in bcd changes by using {@link
* #computePrecisionAndCompact()}.
*/
int32_t precision;
/**
* A bitmask of properties relating to the number represented by this object.
*
* @see #NEGATIVE_FLAG
* @see #INFINITY_FLAG
* @see #NAN_FLAG
*/
int8_t flags;
// The following three fields relate to the double-to-ascii fast path algorithm.
// When a double is given to DecimalQuantityBCD, it is converted to using a fast algorithm. The
// fast algorithm guarantees correctness to only the first ~12 digits of the double. The process
// of rounding the number ensures that the converted digits are correct, falling back to a slow-
// path algorithm if required. Therefore, if a DecimalQuantity is constructed from a double, it
// is *required* that roundToMagnitude(), roundToIncrement(), or roundToInfinity() is called. If
// you don't round, assertions will fail in certain other methods if you try calling them.
/**
* Whether the value in the BCD comes from the double fast path without having been rounded to
* ensure correctness
*/
UBool isApproximate;
/**
* The original number provided by the user and which is represented in BCD. Used when we need to
* re-compute the BCD for an exact double representation.
*/
double origDouble;
/**
* The change in magnitude relative to the original double. Used when we need to re-compute the
* BCD for an exact double representation.
*/
int32_t origDelta;
// Four positions: left optional '(', left required '[', right required ']', right optional ')'.
// These four positions determine which digits are displayed in the output string. They do NOT
// affect rounding. These positions are internal-only and can be specified only by the public
// endpoints like setFractionLength, setIntegerLength, and setSignificantDigits, among others.
//
// * Digits between lReqPos and rReqPos are in the "required zone" and are always displayed.
// * Digits between lOptPos and rOptPos but outside the required zone are in the "optional zone"
// and are displayed unless they are trailing off the left or right edge of the number and
// have a numerical value of zero. In order to be "trailing", the digits need to be beyond
// the decimal point in their respective directions.
// * Digits outside of the "optional zone" are never displayed.
//
// See the table below for illustrative examples.
//
// +---------+---------+---------+---------+------------+------------------------+--------------+
// | lOptPos | lReqPos | rReqPos | rOptPos | number | positions | en-US string |
// +---------+---------+---------+---------+------------+------------------------+--------------+
// | 5 | 2 | -1 | -5 | 1234.567 | ( 12[34.5]67 ) | 1,234.567 |
// | 3 | 2 | -1 | -5 | 1234.567 | 1(2[34.5]67 ) | 234.567 |
// | 3 | 2 | -1 | -2 | 1234.567 | 1(2[34.5]6)7 | 234.56 |
// | 6 | 4 | 2 | -5 | 123456789. | 123(45[67]89. ) | 456,789. |
// | 6 | 4 | 2 | 1 | 123456789. | 123(45[67]8)9. | 456,780. |
// | -1 | -1 | -3 | -4 | 0.123456 | 0.1([23]4)56 | .0234 |
// | 6 | 4 | -2 | -2 | 12.3 | ( [ 12.3 ]) | 0012.30 |
// +---------+---------+---------+---------+------------+------------------------+--------------+
//
int32_t lOptPos = INT32_MAX;
int32_t lReqPos = 0;
int32_t rReqPos = 0;
int32_t rOptPos = INT32_MIN;
/**
* The BCD of the 16 digits of the number represented by this object. Every 4 bits of the long map
* to one digit. For example, the number "12345" in BCD is "0x12345".
*
* <p>Whenever bcd changes internally, {@link #compact()} must be called, except in special cases
* like setting the digit to zero.
*/
union {
struct {
int8_t *ptr;
int32_t len;
} bcdBytes;
uint64_t bcdLong;
} fBCD;
bool usingBytes = false;
/**
* Whether this {@link DecimalQuantity} has been explicitly converted to an exact double. true if
* backed by a double that was explicitly converted via convertToAccurateDouble; false otherwise.
* Used for testing.
*/
bool explicitExactDouble = false;
/**
* Returns a single digit from the BCD list. No internal state is changed by calling this method.
*
* @param position The position of the digit to pop, counted in BCD units from the least
* significant digit. If outside the range supported by the implementation, zero is returned.
* @return The digit at the specified location.
*/
int8_t getDigitPos(int32_t position) const;
/**
* Sets the digit in the BCD list. This method only sets the digit; it is the caller's
* responsibility to call {@link #compact} after setting the digit.
*
* @param position The position of the digit to pop, counted in BCD units from the least
* significant digit. If outside the range supported by the implementation, an AssertionError
* is thrown.
* @param value The digit to set at the specified location.
*/
void setDigitPos(int32_t position, int8_t value);
/**
* Adds zeros to the end of the BCD list. This will result in an invalid BCD representation; it is
* the caller's responsibility to do further manipulation and then call {@link #compact}.
*
* @param numDigits The number of zeros to add.
*/
void shiftLeft(int32_t numDigits);
void shiftRight(int32_t numDigits);
/**
* Sets the internal representation to zero. Clears any values stored in scale, precision,
* hasDouble, origDouble, origDelta, and BCD data.
*/
void setBcdToZero();
/**
* Sets the internal BCD state to represent the value in the given int. The int is guaranteed to
* be either positive. The internal state is guaranteed to be empty when this method is called.
*
* @param n The value to consume.
*/
void readIntToBcd(int32_t n);
/**
* Sets the internal BCD state to represent the value in the given long. The long is guaranteed to
* be either positive. The internal state is guaranteed to be empty when this method is called.
*
* @param n The value to consume.
*/
void readLongToBcd(int64_t n);
void readDecNumberToBcd(const DecNum& dn);
void readDoubleConversionToBcd(const char* buffer, int32_t length, int32_t point);
void copyFieldsFrom(const DecimalQuantity& other);
void copyBcdFrom(const DecimalQuantity &other);
void moveBcdFrom(DecimalQuantity& src);
/**
* Removes trailing zeros from the BCD (adjusting the scale as required) and then computes the
* precision. The precision is the number of digits in the number up through the greatest nonzero
* digit.
*
* <p>This method must always be called when bcd changes in order for assumptions to be correct in
* methods like {@link #fractionCount()}.
*/
void compact();
void _setToInt(int32_t n);
void _setToLong(int64_t n);
void _setToDoubleFast(double n);
void _setToDecNum(const DecNum& dn, UErrorCode& status);
void convertToAccurateDouble();
/** Ensure that a byte array of at least 40 digits is allocated. */
void ensureCapacity();
void ensureCapacity(int32_t capacity);
/** Switches the internal storage mechanism between the 64-bit long and the byte array. */
void switchStorage();
};
} // namespace impl
} // namespace number
U_NAMESPACE_END
#endif //__NUMBER_DECIMALQUANTITY_H__
#endif /* #if !UCONFIG_NO_FORMATTING */