The explanation as to why the parsed value is off by `19`

lies in the how `double`

values are represented, as IEEE floating-point numbers with 53 bits of precision. That is, for large values as you're inputting, the precision is actually greater than `1`

. The method `Math.ulp`

, for "unit in last place", gives the closest `double`

values can be apart at the magnitude of its argument.

```
double d2 = 1234567879123456789d;
DecimalFormat df = new DecimalFormat("#.##");
System.out.println(Math.ulp(d2));
System.out.println(df.format(d2));
```

This outputs

```
256.0
1234567879123456770
```

So, you get the closest `double`

value to the number you type in the source code. Section 3.10.2 of the JLS covers `double`

literals:

The elements of the types float and double are those values that can be represented using the IEEE 754 32-bit single-precision and 64-bit double-precision binary floating-point formats, respectively.

The details of proper input conversion from a Unicode string representation of a floating-point number to the internal IEEE 754 binary floating-point representation are described for the methods valueOf of class Float and class Double of the package java.lang.

And referring to `Double.valueOf`

javadocs:

s is regarded as representing an exact decimal value in the usual "computerized scientific notation" or as an exact hexadecimal value; this exact numerical value is then conceptually converted to an "infinitely precise" binary value that is then rounded to type double by the usual round-to-nearest rule of IEEE 754 floating-point arithmetic [...]

Additionally, this value is still within the range of `long`

values, which will still represent the integer value correctly.

```
long l2 = 1234567879123456789L;
DecimalFormat df = new DecimalFormat("#.##");
System.out.println(df.format(l2));
```

This outputs

```
1234567879123456789
```

`double`

's (im)precision... – fge Feb 25 '14 at 23:46