public class Dfp extends java.lang.Object implements FieldElement<Dfp>
Another floating point class. This one is built using radix 10000 which is 10^{4}, so its almost decimal.
The design goals here are:
Trade offs:
Numbers are represented in the following form:
n = sign × mant × (radix)^{exp};where sign is ±1, mantissa represents a fractional number between zero and one. mant[0] is the least significant digit. exp is in the range of 32767 to 32768
IEEE 8541987 Notes and differences
IEEE 854 requires the radix to be either 2 or 10. The radix here is 10000, so that requirement is not met, but it is possible that a subclassed can be made to make it behave as a radix 10 number. It is my opinion that if it looks and behaves as a radix 10 number then it is one and that requirement would be met.
The radix of 10000 was chosen because it should be faster to operate on 4 decimal digits at once instead of one at a time. Radix 10 behavior can be realized by add an additional rounding step to ensure that the number of decimal digits represented is constant.
The IEEE standard specifically leaves out internal data encoding, so it is reasonable to conclude that such a subclass of this radix 10000 system is merely an encoding of a radix 10 system.
IEEE 854 also specifies the existence of "subnormal" numbers. This class does not contain any such entities. The most significant radix 10000 digit is always nonzero. Instead, we support "gradual underflow" by raising the underflow flag for numbers less with exponent less than expMin, but don't flush to zero until the exponent reaches MIN_EXPdigits. Thus the smallest number we can represent would be: 1E((MIN_EXPdigits1)*4), eg, for digits=5, MIN_EXP=32767, that would be 1e131092.
IEEE 854 defines that the implied radix point lies just to the right of the most significant digit and to the left of the remaining digits. This implementation puts the implied radix point to the left of all digits including the most significant one. The most significant digit here is the one just to the right of the radix point. This is a fine detail and is really only a matter of definition. Any side effects of this can be rendered invisible by a subclass.
DfpField
Modifier and Type  Field and Description 

static int 
ERR_SCALE
The amount under/overflows are scaled by before going to trap handler

static byte 
FINITE
Indicator value for normal finite numbers.

static byte 
INFINITE
Indicator value for Infinity.

static int 
MAX_EXP
The maximum exponent before overflow is signaled and results flushed
to infinity

static int 
MIN_EXP
The minimum exponent before underflow is signaled.

static byte 
QNAN
Indicator value for quiet NaN.

static int 
RADIX
The radix, or base of this system.

static byte 
SNAN
Indicator value for signaling NaN.

Modifier and Type  Method and Description 

Dfp 
add(Dfp x)
Add x to this.

Dfp 
ceil()
Round to an integer using the round ceil mode.

int 
classify()
Returns the type  one of FINITE, INFINITE, SNAN, QNAN.

static Dfp 
copysign(Dfp x,
Dfp y)
Creates an instance that is the same as x except that it has the sign of y.

Dfp 
divide(Dfp divisor)
Divide this by divisor.

Dfp 
divide(int divisor)
Divide by a single digit less than radix.

Dfp 
dotrap(int type,
java.lang.String what,
Dfp oper,
Dfp result)
Raises a trap.

boolean 
equals(java.lang.Object other)
Check if instance is equal to x.

Dfp 
floor()
Round to an integer using the round floor mode.

DfpField 
getField()

Dfp 
getOne()
Get the constant 1.

int 
getRadixDigits()
Get the number of radix digits of the instance.

Dfp 
getTwo()
Get the constant 2.

Dfp 
getZero()
Get the constant 0.

boolean 
greaterThan(Dfp x)
Check if instance is greater than x.

int 
hashCode()
Gets a hashCode for the instance.

int 
intValue()
Convert this to an integer.

boolean 
isInfinite()
Check if instance is infinite.

boolean 
isNaN()
Check if instance is not a number.

boolean 
lessThan(Dfp x)
Check if instance is less than x.

int 
log10()
Get the exponent of the greatest power of 10 that is less than or equal to abs(this).

int 
log10K()
Get the exponent of the greatest power of 10000 that is
less than or equal to the absolute value of this.

Dfp 
multiply(Dfp x)
Multiply this by x.

Dfp 
multiply(int x)
Multiply this by a single digit 0<=x<radix.

Dfp 
negate()
Returns a number that is this number with the sign bit reversed.

Dfp 
newInstance()
Create an instance with a value of 0.

Dfp 
newInstance(byte x)
Create an instance from a byte value.

Dfp 
newInstance(byte sig,
byte code)
Creates an instance with a nonfinite value.

Dfp 
newInstance(Dfp d)
Create an instance by copying an existing one.

Dfp 
newInstance(double x)
Create an instance from a double value.

Dfp 
newInstance(int x)
Create an instance from an int value.

Dfp 
newInstance(long x)
Create an instance from a long value.

Dfp 
newInstance(java.lang.String s)
Create an instance from a String representation.

Dfp 
nextAfter(Dfp x)
Returns the next number greater than this one in the direction of x.

Dfp 
power10(int e)
Return the specified power of 10.

Dfp 
power10K(int e)
Get the specified power of 10000.

Dfp 
remainder(Dfp d)
Returns the IEEE remainder.

Dfp 
rint()
Round to nearest integer using the roundhalfeven method.

Dfp 
sqrt()
Compute the square root.

Dfp 
subtract(Dfp x)
Subtract x from this.

double 
toDouble()
Convert the instance into a double.

double[] 
toSplitDouble()
Convert the instance into a split double.

java.lang.String 
toString()
Get a string representation of the instance.

boolean 
unequal(Dfp x)
Check if instance is not equal to x.

public static final int RADIX
public static final int MIN_EXP
public static final int MAX_EXP
public static final int ERR_SCALE
public static final byte FINITE
public static final byte INFINITE
public static final byte SNAN
public static final byte QNAN
public Dfp(Dfp d)
d
 instance to copypublic Dfp newInstance()
public Dfp newInstance(byte x)
x
 value to convert to an instancepublic Dfp newInstance(int x)
x
 value to convert to an instancepublic Dfp newInstance(long x)
x
 value to convert to an instancepublic Dfp newInstance(double x)
x
 value to convert to an instancepublic Dfp newInstance(Dfp d)
d
 instance to copypublic Dfp newInstance(java.lang.String s)
s
 string representation of the instancepublic Dfp newInstance(byte sig, byte code)
public DfpField getField()
Field
(really a DfpField
) to which the instance belongs.
The field is linked to the number of digits and acts as a factory
for Dfp
instances.
getField
in interface FieldElement<Dfp>
Field
(really a DfpField
) to which the instance belongspublic int getRadixDigits()
public Dfp getZero()
public Dfp getOne()
public Dfp getTwo()
public boolean lessThan(Dfp x)
x
 number to check instance againstpublic boolean greaterThan(Dfp x)
x
 number to check instance againstpublic boolean isInfinite()
public boolean isNaN()
public boolean equals(java.lang.Object other)
equals
in class java.lang.Object
other
 object to check instance againstpublic int hashCode()
hashCode
in class java.lang.Object
public boolean unequal(Dfp x)
x
 number to check instance againstpublic Dfp rint()
public Dfp floor()
public Dfp ceil()
public Dfp remainder(Dfp d)
d
 divisorpublic int intValue()
public int log10K()
public Dfp power10K(int e)
e
 desired powerpublic int log10()
public Dfp power10(int e)
e
 desired powerpublic Dfp add(Dfp x)
add
in interface FieldElement<Dfp>
x
 number to addpublic Dfp negate()
public Dfp subtract(Dfp x)
subtract
in interface FieldElement<Dfp>
x
 number to subtractpublic Dfp multiply(Dfp x)
multiply
in interface FieldElement<Dfp>
x
 multiplicandpublic Dfp multiply(int x)
x
 multiplicandpublic Dfp divide(Dfp divisor)
divide
in interface FieldElement<Dfp>
divisor
 divisorpublic Dfp divide(int divisor)
divisor
 divisorpublic Dfp sqrt()
public java.lang.String toString()
toString
in class java.lang.Object
public Dfp dotrap(int type, java.lang.String what, Dfp oper, Dfp result)
type
 the trap typewhat
  name of routine trap occurred inoper
  input operator to functionresult
  the result computed prior to the trappublic int classify()
public static Dfp copysign(Dfp x, Dfp y)
x
 number to get the value fromy
 number to get the sign frompublic Dfp nextAfter(Dfp x)
x
 direction where to look atpublic double toDouble()
toSplitDouble()
public double[] toSplitDouble()
toDouble()
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