Here is another solution based on `BigDecimal`

(that does not go through a `String`

).

```
private static double[] method(double d) {
BigDecimal bd = new BigDecimal(d);
return new double[] { bd.intValue(),
bd.remainder(BigDecimal.ONE).doubleValue() };
}
```

As you'll note, you still won't get just `0.6`

as output for the fractional part. (You can't even store `0.6`

in a `double`

!) This is due to the fact that the mathematical, real number, 5.6 is actually not represented by a double exactly as 5.6 but as 5.599999...

You could also do

```
private static double[] method(double d) {
BigDecimal bd = BigDecimal.valueOf(d);
return new double[] { bd.intValue(),
bd.remainder(BigDecimal.ONE).doubleValue() };
}
```

which actually does yield `[5.0, 0.6]`

.

The `BigDecimal.valueOf`

is in most JDK's (internally) implemented through a call to `Double.toString`

however. But at least the string-related stuff doesn't clutter *your* code :-)

Good follow-up question in comment:

**If it is represented as 5.599999999..., then why **`Double.toString(5.6)`

gives exactly `"5.6"`

The `Double.toString`

method is actually *very sophisticated*. From the documentation of `Double.toString`

:

[...]

**How many digits must be printed for the fractional part of m or a? There must be at least one digit to represent the fractional part, and beyond that as many, but only as many, more digits as are needed to uniquely distinguish the argument value from adjacent values of type double.** That is, suppose that x is the exact mathematical value represented by the decimal representation produced by this method for a finite nonzero argument d. Then d must be the double value nearest to x; or if two double values are equally close to x, then d must be one of them and the least significant bit of the significand of d must be 0.

[...]

The code for getting the characters `"5.6"`

boils down to `FloatingDecimal.getChars`

:

```
private int getChars(char[] result) {
assert nDigits <= 19 : nDigits; // generous bound on size of nDigits
int i = 0;
if (isNegative) { result[0] = '-'; i = 1; }
if (isExceptional) {
System.arraycopy(digits, 0, result, i, nDigits);
i += nDigits;
} else {
if (decExponent > 0 && decExponent < 8) {
// print digits.digits.
int charLength = Math.min(nDigits, decExponent);
System.arraycopy(digits, 0, result, i, charLength);
i += charLength;
if (charLength < decExponent) {
charLength = decExponent-charLength;
System.arraycopy(zero, 0, result, i, charLength);
i += charLength;
result[i++] = '.';
result[i++] = '0';
} else {
result[i++] = '.';
if (charLength < nDigits) {
int t = nDigits - charLength;
System.arraycopy(digits, charLength, result, i, t);
i += t;
} else {
result[i++] = '0';
}
}
} else if (decExponent <=0 && decExponent > -3) {
result[i++] = '0';
result[i++] = '.';
if (decExponent != 0) {
System.arraycopy(zero, 0, result, i, -decExponent);
i -= decExponent;
}
System.arraycopy(digits, 0, result, i, nDigits);
i += nDigits;
} else {
result[i++] = digits[0];
result[i++] = '.';
if (nDigits > 1) {
System.arraycopy(digits, 1, result, i, nDigits-1);
i += nDigits-1;
} else {
result[i++] = '0';
}
result[i++] = 'E';
int e;
if (decExponent <= 0) {
result[i++] = '-';
e = -decExponent+1;
} else {
e = decExponent-1;
}
// decExponent has 1, 2, or 3, digits
if (e <= 9) {
result[i++] = (char)(e+'0');
} else if (e <= 99) {
result[i++] = (char)(e/10 +'0');
result[i++] = (char)(e%10 + '0');
} else {
result[i++] = (char)(e/100+'0');
e %= 100;
result[i++] = (char)(e/10+'0');
result[i++] = (char)(e%10 + '0');
}
}
}
return i;
}
```