java.math.BigDecimal Maven / Gradle / Ivy
/*
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stub files, must be accompanied by this notice in its entirety.
This work corresponds to the API signatures of JSR 219: Foundation
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*/
package java.math;
/**
* Immutable, arbitrary-precision signed decimal numbers. A BigDecimal
* consists of an arbitrary precision integer unscaled value and a
* non-negative 32-bit integer scale, which represents the number of
* digits to the right of the decimal point. The number represented by the
* BigDecimal is (unscaledValue/10scale). BigDecimal
* provides operations for basic arithmetic, scale manipulation, comparison,
* hashing, and format conversion.
*
* The BigDecimal class gives its user complete control over rounding
* behavior, forcing the user to explicitly specify a rounding
* behavior for operations capable of discarding precision ({@link
* #divide(BigDecimal, int)}, {@link #divide(BigDecimal, int, int)},
* and {@link #setScale}). Eight rounding modes are provided
* for this purpose.
*
* Two types of operations are provided for manipulating the scale of a
* BigDecimal: scaling/rounding operations and decimal point motion
* operations. Scaling/rounding operations (setScale) return a
* BigDecimal whose value is approximately (or exactly) equal to that of the
* operand, but whose scale is the specified value; that is, they increase or
* decrease the precision of the number with minimal effect on its value.
* Decimal point motion operations ({@link #movePointLeft} and
* {@link #movePointRight}) return a BigDecimal created from the operand by
* moving the decimal point a specified distance in the specified direction;
* that is, they change a number's value without affecting its precision.
*
* For the sake of brevity and clarity, pseudo-code is used throughout the
* descriptions of BigDecimal methods. The pseudo-code expression
* (i + j) is shorthand for "a BigDecimal whose value is
* that of the BigDecimal i plus that of the BigDecimal j."
* The pseudo-code expression (i == j) is shorthand for
* "true if and only if the BigDecimal i represents the same
* value as the the BigDecimal j." Other pseudo-code expressions are
* interpreted similarly.
*
* Note: care should be exercised if BigDecimals are to be used as
* keys in a {@link java.util.SortedMap} or elements in a {@link
* java.util.SortedSet}, as BigDecimal's natural ordering is
* inconsistent with equals. See {@link Comparable}, {@link
* java.util.SortedMap} or {@link java.util.SortedSet} for more
* information.
*
* All methods and constructors for this class
* throw NullPointerException when passed
* a null object reference for any input parameter.
*
* @see BigInteger
* @see java.util.SortedMap
* @see java.util.SortedSet
* @version 1.33, 08/19/02
* @author Josh Bloch
*/
public class BigDecimal extends Number implements Comparable
{
/**
* Rounding mode to round away from zero. Always increments the
* digit prior to a non-zero discarded fraction. Note that this rounding
* mode never decreases the magnitude of the calculated value.
*/
public static final int ROUND_UP = 0;
/**
* Rounding mode to round towards zero. Never increments the digit
* prior to a discarded fraction (i.e., truncates). Note that this
* rounding mode never increases the magnitude of the calculated value.
*/
public static final int ROUND_DOWN = 1;
/**
* Rounding mode to round towards positive infinity. If the
* BigDecimal is positive, behaves as for ROUND_UP; if negative,
* behaves as for ROUND_DOWN. Note that this rounding mode never
* decreases the calculated value.
*/
public static final int ROUND_CEILING = 2;
/**
* Rounding mode to round towards negative infinity. If the
* BigDecimal is positive, behave as for ROUND_DOWN; if negative,
* behave as for ROUND_UP. Note that this rounding mode never
* increases the calculated value.
*/
public static final int ROUND_FLOOR = 3;
/**
* Rounding mode to round towards "nearest neighbor" unless both
* neighbors are equidistant, in which case round up.
* Behaves as for ROUND_UP if the discarded fraction is >= .5;
* otherwise, behaves as for ROUND_DOWN. Note that this is the
* rounding mode that most of us were taught in grade school.
*/
public static final int ROUND_HALF_UP = 4;
/**
* Rounding mode to round towards "nearest neighbor" unless both
* neighbors are equidistant, in which case round down.
* Behaves as for ROUND_UP if the discarded fraction is > .5;
* otherwise, behaves as for ROUND_DOWN.
*/
public static final int ROUND_HALF_DOWN = 5;
/**
* Rounding mode to round towards the "nearest neighbor" unless both
* neighbors are equidistant, in which case, round towards the even
* neighbor. Behaves as for ROUND_HALF_UP if the digit to the left of the
* discarded fraction is odd; behaves as for ROUND_HALF_DOWN if it's even.
* Note that this is the rounding mode that minimizes cumulative error
* when applied repeatedly over a sequence of calculations.
*/
public static final int ROUND_HALF_EVEN = 6;
/**
* Rounding mode to assert that the requested operation has an exact
* result, hence no rounding is necessary. If this rounding mode is
* specified on an operation that yields an inexact result, an
* ArithmeticException is thrown.
*/
public static final int ROUND_UNNECESSARY = 7;
/**
* The unscaled value of this BigDecimal, as returned by unscaledValue().
*
* @serial
* @see #unscaledValue
*/
private BigInteger intVal;
/**
* The scale of this BigDecimal, as returned by scale().
*
* @serial
* @see #scale
*/
private int scale;
private static final long serialVersionUID = 6108874887143696463L;
/**
* Translates the String representation of a BigDecimal into a
* BigDecimal. The String representation consists of an optional
* sign, '+' ('\u002B') or '-'
* ('\u002D'), followed by a sequence of zero or more
* decimal digits ("the integer"), optionally followed by a
* fraction, optionally followed by an exponent.
*
*
The fraction consists of of a decimal point followed by zero or more
* decimal digits. The string must contain at least one digit in either
* the integer or the fraction. The number formed by the sign, the
* integer and the fraction is referred to as the significand.
*
*
The exponent consists of the character 'e'
* ('\u0075') or 'E' ('\u0045')
* followed by one or more decimal digits. The value of the
* exponent must lie between -{@link Integer#MAX_VALUE} ({@link
* Integer#MIN_VALUE}+1) and {@link Integer#MAX_VALUE}, inclusive.
*
*
More formally, the strings this constructor accepts are
* described by the following grammar:
*
*
* - BigDecimalString:
*
- Signopt Significand Exponentopt
*
*
- Sign:
*
+
* -
*
*
- Significand:
*
- IntegerPart
. FractionPartopt
* . FractionPart
* - IntegerPart
*
*
- IntegerPart:
*
- Digits
*
*
- FractionPart:
*
- Digits
*
*
- Exponent:
*
- ExponentIndicator SignedInteger
*
*
- ExponentIndicator:
*
e
* E
*
*
- SignedInteger:
*
- Signopt Digits
*
*
- Digits:
*
- Digit
*
- Digits Digit
*
*
- Digit:
*
- any character for which {@link Character#isDigit}
* returns
true, including 0, 1, 2 ...
*
*
*
* The scale of the returned BigDecimal will be the number of digits in
* the fraction, or zero if the string contains no decimal point, subject
* to adjustment for any exponent: If the string contains an exponent, the
* exponent is subtracted from the scale. If the resulting scale is
* negative, the scale of the returned BigDecimal is zero and the unscaled
* value is multiplied by the appropriate power of ten so that, in every
* case, the resulting BigDecimal is equal to significand ×
* 10exponent. (If in the future this specification is
* amended to permit negative scales, the final step of zeroing the scale
* and adjusting the unscaled value will be eliminated.)
*
*
The character-to-digit mapping is provided by {@link
* java.lang.Character#digit} set to convert to radix 10. The
* String may not contain any extraneous characters (whitespace,
* for example).
*
*
Note: For values other float and double
* NaN and ±Infinity, this constructor is compatible with
* the values returned by {@link Float#toString} and {@link
* Double#toString}. This is generally the preferred way to
* convert a float or double into a BigDecimal,
* as it doesn't suffer from the unpredictability of the {@link
* #BigDecimal(double)} constructor.
*
*
Note: the optional leading plus sign and trailing exponent were
* added in release 1.3.
*
* @param val String representation of BigDecimal.
* @throws NumberFormatException val is not a valid representation
* of a BigDecimal.
*/
public BigDecimal(String val) { }
/**
* Translates a double into a BigDecimal. The scale
* of the BigDecimal is the smallest value such that
* (10scale * val) is an integer.
*
* Note: the results of this constructor can be somewhat unpredictable.
* One might assume that new BigDecimal(.1) is exactly equal
* to .1, but it is actually equal
* to .1000000000000000055511151231257827021181583404541015625.
* This is so because .1 cannot be represented exactly as a double
* (or, for that matter, as a binary fraction of any finite length).
* Thus, the long value that is being passed in to the constructor
* is not exactly equal to .1, appearances notwithstanding.
*
* The (String) constructor, on the other hand, is perfectly predictable:
* new BigDecimal(".1") is exactly equal to .1, as one
* would expect. Therefore, it is generally recommended that the (String)
* constructor be used in preference to this one.
*
* @param val double value to be converted to BigDecimal.
* @throws NumberFormatException val if val is
* infinite or NaN.
*/
public BigDecimal(double val) { }
/**
* Translates a BigInteger into a BigDecimal. The scale of the BigDecimal
* is zero.
*
* @param val BigInteger value to be converted to BigDecimal.
*/
public BigDecimal(BigInteger val) { }
/**
* Translates a BigInteger unscaled value and an int
* scale into a BigDecimal. The value of the BigDecimal is
* (unscaledVal/10scale).
*
* @param unscaledVal unscaled value of the BigDecimal.
* @param scale scale of the BigDecimal.
* @throws NumberFormatException scale is negative
*/
public BigDecimal(BigInteger unscaledVal, int scale) { }
/**
* Translates a long unscaled value and an
* int scale into a BigDecimal. This "static factory
* method" is provided in preference to a (long,
* int) constructor because it allows for reuse of
* frequently used BigDecimals.
*
* @param unscaledVal unscaled value of the BigDecimal.
* @param scale scale of the BigDecimal.
* @return a BigDecimal whose value is
* (unscaledVal/10scale).
*/
public static BigDecimal valueOf(long unscaledVal, int scale) {
return null;
}
/**
* Translates a long value into a BigDecimal with a
* scale of zero. This "static factory method" is provided in
* preference to a (long) constructor because it
* allows for reuse of frequently used BigDecimals.
*
* @param val value of the BigDecimal.
* @return a BigDecimal whose value is val.
*/
public static BigDecimal valueOf(long val) {
return null;
}
/**
* Returns a BigDecimal whose value is (this + val), and whose
* scale is max(this.scale(), val.scale()).
*
* @param val value to be added to this BigDecimal.
* @return this + val
*/
public BigDecimal add(BigDecimal val) {
return null;
}
/**
* Returns a BigDecimal whose value is (this - val), and whose
* scale is max(this.scale(), val.scale()).
*
* @param val value to be subtracted from this BigDecimal.
* @return this - val
*/
public BigDecimal subtract(BigDecimal val) {
return null;
}
/**
* Returns a BigDecimal whose value is (this * val), and whose
* scale is (this.scale() + val.scale()).
*
* @param val value to be multiplied by this BigDecimal.
* @return this * val
*/
public BigDecimal multiply(BigDecimal val) {
return null;
}
/**
* Returns a BigDecimal whose value is (this / val), and whose
* scale is as specified. If rounding must be performed to generate a
* result with the specified scale, the specified rounding mode is
* applied.
*
* @param val value by which this BigDecimal is to be divided.
* @param scale scale of the BigDecimal quotient to be returned.
* @param roundingMode rounding mode to apply.
* @return this / val
* @throws ArithmeticException val is zero, scale is
* negative, or roundingMode==ROUND_UNNECESSARY and
* the specified scale is insufficient to represent the result
* of the division exactly.
* @throws IllegalArgumentException roundingMode does not
* represent a valid rounding mode.
* @see #ROUND_UP
* @see #ROUND_DOWN
* @see #ROUND_CEILING
* @see #ROUND_FLOOR
* @see #ROUND_HALF_UP
* @see #ROUND_HALF_DOWN
* @see #ROUND_HALF_EVEN
* @see #ROUND_UNNECESSARY
*/
public BigDecimal divide(BigDecimal val, int scale, int roundingMode) {
return null;
}
/**
* Returns a BigDecimal whose value is (this / val), and whose
* scale is this.scale(). If rounding must be performed to
* generate a result with the given scale, the specified rounding mode is
* applied.
*
* @param val value by which this BigDecimal is to be divided.
* @param roundingMode rounding mode to apply.
* @return this / val
* @throws ArithmeticException val==0, or
* roundingMode==ROUND_UNNECESSARY and
* this.scale() is insufficient to represent the result
* of the division exactly.
* @throws IllegalArgumentException roundingMode does not
* represent a valid rounding mode.
* @see #ROUND_UP
* @see #ROUND_DOWN
* @see #ROUND_CEILING
* @see #ROUND_FLOOR
* @see #ROUND_HALF_UP
* @see #ROUND_HALF_DOWN
* @see #ROUND_HALF_EVEN
* @see #ROUND_UNNECESSARY
*/
public BigDecimal divide(BigDecimal val, int roundingMode) {
return null;
}
/**
* Returns a BigDecimal whose value is the absolute value of this
* BigDecimal, and whose scale is this.scale().
*
* @return abs(this)
*/
public BigDecimal abs() {
return null;
}
/**
* Returns a BigDecimal whose value is (-this), and whose scale
* is this.scale().
*
* @return -this
*/
public BigDecimal negate() {
return null;
}
/**
* Returns the signum function of this BigDecimal.
*
* @return -1, 0 or 1 as the value of this BigDecimal is negative, zero or
* positive.
*/
public int signum() {
return 0;
}
/**
* Returns the scale of this BigDecimal. (The scale is the number
* of digits to the right of the decimal point.)
*
* @return the scale of this BigDecimal.
*/
public int scale() {
return 0;
}
/**
* Returns a BigInteger whose value is the unscaled value of this
* BigDecimal. (Computes (this * 10this.scale()).)
*
* @return the unscaled value of this BigDecimal.
* @since 1.2
*/
public BigInteger unscaledValue() {
return null;
}
/**
* Returns a BigDecimal whose scale is the specified value, and whose
* unscaled value is determined by multiplying or dividing this
* BigDecimal's unscaled value by the appropriate power of ten to maintain
* its overall value. If the scale is reduced by the operation, the
* unscaled value must be divided (rather than multiplied), and the value
* may be changed; in this case, the specified rounding mode is applied to
* the division.
*
* Note that since BigDecimal objects are immutable, calls of this
* method do not result in the original object being
* modified, contrary to the usual convention of having methods
* named setX mutate field
* X. Instead, setScale returns
* an object with the proper scale; the returned object may or may
* not be newly allocated.
*
* @param scale scale of the BigDecimal value to be returned.
* @param roundingMode The rounding mode to apply.
* @return a BigDecimal whose scale is the specified value, and whose
* unscaled value is determined by multiplying or dividing this
* BigDecimal's unscaled value by the appropriate power of ten to
* maintain its overall value.
* @throws ArithmeticException scale is negative, or
* roundingMode==ROUND_UNNECESSARY and the specified
* scaling operation would require rounding.
* @throws IllegalArgumentException roundingMode does not
* represent a valid rounding mode.
* @see #ROUND_UP
* @see #ROUND_DOWN
* @see #ROUND_CEILING
* @see #ROUND_FLOOR
* @see #ROUND_HALF_UP
* @see #ROUND_HALF_DOWN
* @see #ROUND_HALF_EVEN
* @see #ROUND_UNNECESSARY
*/
public BigDecimal setScale(int scale, int roundingMode) {
return null;
}
/**
* Returns a BigDecimal whose scale is the specified value, and whose
* value is numerically equal to this BigDecimal's. Throws an
* ArithmeticException if this is not possible. This call is typically
* used to increase the scale, in which case it is guaranteed that there
* exists a BigDecimal of the specified scale and the correct value. The
* call can also be used to reduce the scale if the caller knows that the
* BigDecimal has sufficiently many zeros at the end of its fractional
* part (i.e., factors of ten in its integer value) to allow for the
* rescaling without loss of precision.
*
* This method returns the same result as the two argument version
* of setScale, but saves the caller the trouble of specifying a
* rounding mode in cases where it is irrelevant.
*
* Note that since BigDecimal objects are immutable, calls of this
* method do not result in the original object being
* modified, contrary to the usual convention of having methods
* named setX mutate field
* X. Instead, setScale returns
* an object with the proper scale; the returned object may or may
* not be newly allocated.
*
* @param scale scale of the BigDecimal value to be returned.
* @return a BigDecimal whose scale is the specified value, and whose
* unscaled value is determined by multiplying or dividing this
* BigDecimal's unscaled value by the appropriate power of ten to
* maintain its overall value.
* @throws ArithmeticException scale is negative, or
* the specified scaling operation would require rounding.
* @see #setScale(int, int)
*/
public BigDecimal setScale(int scale) {
return null;
}
/**
* Returns a BigDecimal which is equivalent to this one with the decimal
* point moved n places to the left. If n is non-negative, the call merely
* adds n to the scale. If n is negative, the call is equivalent to
* movePointRight(-n). (The BigDecimal returned by this call has value
* (this * 10-n) and scale
* max(this.scale()+n, 0).)
*
* @param n number of places to move the decimal point to the left.
* @return a BigDecimal which is equivalent to this one with the decimal
* point moved n places to the left.
*/
public BigDecimal movePointLeft(int n) {
return null;
}
/**
* Moves the decimal point the specified number of places to the right.
* If this BigDecimal's scale is >= n, the call merely
* subtracts n from the scale; otherwise, it sets the scale to
* zero, and multiplies the integer value by
* 10(n - this.scale). If n
* is negative, the call is equivalent to movePointLeft(-n). (The
* BigDecimal returned by this call has value
* (this * 10n) and scale
* max(this.scale()-n, 0).)
*
* @param n number of places to move the decimal point to the right.
* @return a BigDecimal which is equivalent to this one with the decimal
* point moved n places to the right.
*/
public BigDecimal movePointRight(int n) {
return null;
}
/**
* Compares this BigDecimal with the specified BigDecimal. Two
* BigDecimals that are equal in value but have a different scale (like
* 2.0 and 2.00) are considered equal by this method. This method is
* provided in preference to individual methods for each of the six
* boolean comparison operators (<, ==, >, >=, !=, <=). The
* suggested idiom for performing these comparisons is:
* (x.compareTo(y) <op> 0),
* where <op> is one of the six comparison operators.
*
* @param val BigDecimal to which this BigDecimal is to be compared.
* @return -1, 0 or 1 as this BigDecimal is numerically less than, equal
* to, or greater than val.
*/
public int compareTo(BigDecimal val) {
return 0;
}
/**
* Compares this BigDecimal with the specified Object. If the Object is a
* BigDecimal, this method behaves like {@link #compareTo compareTo}.
* Otherwise, it throws a ClassCastException (as BigDecimals are
* comparable only to other BigDecimals).
*
* @param o Object to which this BigDecimal is to be compared.
* @return a negative number, zero, or a positive number as this
* BigDecimal is numerically less than, equal to, or greater
* than o, which must be a BigDecimal.
* @throws ClassCastException o is not a BigDecimal.
* @see #compareTo(java.math.BigDecimal)
* @see Comparable
* @since 1.2
*/
public int compareTo(Object o) {
return 0;
}
/**
* Compares this BigDecimal with the specified Object for
* equality. Unlike {@link #compareTo compareTo}, this method
* considers two BigDecimals equal only if they are equal in value
* and scale (thus 2.0 is not equal to 2.00 when compared by this
* method).
*
* @param x Object to which this BigDecimal is to be compared.
* @return true if and only if the specified Object is a
* BigDecimal whose value and scale are equal to this BigDecimal's.
* @see #compareTo(java.math.BigDecimal)
*/
public boolean equals(Object x) {
return false;
}
/**
* Returns the minimum of this BigDecimal and val.
*
* @param val value with which the minimum is to be computed.
* @return the BigDecimal whose value is the lesser of this BigDecimal and
* val. If they are equal, as defined by the
* {@link #compareTo compareTo} method, either may be returned.
* @see #compareTo(java.math.BigDecimal)
*/
public BigDecimal min(BigDecimal val) {
return null;
}
/**
* Returns the maximum of this BigDecimal and val.
*
* @param val value with which the maximum is to be computed.
* @return the BigDecimal whose value is the greater of this BigDecimal
* and val. If they are equal, as defined by the
* {@link #compareTo compareTo} method, either may be returned.
* @see #compareTo(java.math.BigDecimal)
*/
public BigDecimal max(BigDecimal val) {
return null;
}
/**
* Returns the hash code for this BigDecimal. Note that two BigDecimals
* that are numerically equal but differ in scale (like 2.0 and 2.00)
* will generally not have the same hash code.
*
* @return hash code for this BigDecimal.
*/
public int hashCode() {
return 0;
}
/**
* Returns the string representation of this BigDecimal. The digit-to-
* character mapping provided by {@link Character#forDigit} is used.
* A leading minus sign is used to indicate sign, and the number of digits
* to the right of the decimal point is used to indicate scale. (This
* representation is compatible with the (String) constructor.)
*
* @return String representation of this BigDecimal.
* @see Character#forDigit
* @see #BigDecimal(java.lang.String)
*/
public String toString() {
return null;
}
/**
* Converts this BigDecimal to a BigInteger. This conversion is
* analogous to a narrowing
* primitive conversion from double to
* long as defined in the Java Language
* Specification: any fractional part of this BigDecimal will
* be discarded. Note that this conversion can lose information
* about the precision of the BigDecimal value.
*
* @return this BigDecimal converted to a BigInteger.
*/
public BigInteger toBigInteger() {
return null;
}
/**
* Converts this BigDecimal to an int. This
* conversion is analogous to a narrowing
* primitive conversion from double to
* short as defined in the Java Language
* Specification: any fractional part of this BigDecimal will
* be discarded, and if the resulting "BigInteger" is
* too big to fit in an int, only the low-order 32
* bits are returned. Note that this conversion can lose
* information about the overall magnitude and precision of the
* BigDecimal value as well as return a result with the opposite
* sign.
*
* @return this BigDecimal converted to an int.
*/
public int intValue() {
return 0;
}
/**
* Converts this BigDecimal to a long. This
* conversion is analogous to a narrowing
* primitive conversion from double to
* short as defined in the Java Language
* Specification: any fractional part of this BigDecimal will
* be discarded, and if the resulting "BigInteger" is
* too big to fit in a long, only the low-order 64
* bits are returned. Note that this conversion can lose
* information about the overall magnitude and precision of the
* BigDecimal value as well as return a result with the opposite
* sign.
*
* @return this BigDecimal converted to an long.
*/
public long longValue() {
return -1;
}
/**
* Converts this BigDecimal to a float. This
* conversion is similar to the narrowing
* primitive conversion from double to
* float defined in the Java Language
* Specification: if this BigDecimal has too great a magnitude
* to represent as a float, it will be converted to
* {@link Float#NEGATIVE_INFINITY} or {@link
* Float#POSITIVE_INFINITY} as appropriate. Note that even when
* the return value is finite, this conversion can lose
* information about the precision of the BigDecimal value.
*
* @return this BigDecimal converted to a float.
*/
public float floatValue() {
return 0.0f;
}
/**
* Converts this BigDecimal to a double. This
* conversion is similar to the narrowing
* primitive conversion from double to
* float as defined in the Java Language
* Specification: if this BigDecimal has too great a magnitude
* represent as a double, it will be converted to
* {@link Double#NEGATIVE_INFINITY} or {@link
* Double#POSITIVE_INFINITY} as appropriate. Note that even when
* the return value is finite, this conversion can lose
* information about the precision of the BigDecimal value.
*
* @return this BigDecimal converted to a double.
*/
public double doubleValue() {
return 0.0d;
}
/**
* Reconstitute the BigDecimal instance from a stream (that is,
* deserialize it).
*/
private synchronized void readObject(java.io.ObjectInputStream s)
throws java.io.IOException, ClassNotFoundException
{ }
}