All these languages are using the system-provided floating-point format, which represents values in *binary* rather than in *decimal*. Values like `0.2`

and `0.4`

can't be represented exactly in that format, so instead the closest representable value is stored, resulting in a small error. For example, the numeric literal `0.2`

results in a floating-point number whose exact value is `0.200000000000000011102230246251565404236316680908203125`

. Similarly, any given arithmetic operation on floating-point numbers may result in a value that's not exactly representable, so the true mathematical result is replaced with the closest representable value. These are the fundamental reasons for the errors you're seeing.

However, this doesn't explain the differences between languages: in all of your examples, the exact same computations are being made and the exact same results are being arrived at. The difference then lies in the way that the various languages choose to *display* the results.

Strictly speaking, *none* of the answers you show is correct. Making the (fairly safe) assumption of IEEE 754 binary 64 arithmetic with a round-to-nearest rounding mode, the exact value of the first sum is:

```
0.600000000000000088817841970012523233890533447265625
```

while the exact value of the second sum is:

```
0.59999999999999997779553950749686919152736663818359375
```

However, neither of those outputs is particularly user-friendly, and clearly all of the languages you tested made the sensible decision to abbreviate the output when printing. However, they don't all adopt the same strategy for formatting the output, which is why you're seeing differences.

There are many possible strategies for formatting, but three particularly common ones are:

Compute and display 17 correctly-rounded significant digits, possibly stripping trailing zeros where they appear. The output of 17 digits guarantees that distinct binary64 floats will have distinct representations, so that a floating-point value can be unambiguously recovered from its representation; 17 is the smallest integer with this property. This is the strategy that Python 2.6 uses, for example.

Compute and display the shortest decimal string that rounds back to the given binary64 value under the usual round-ties-to-even rounding mode. This is rather more complicated to implement than strategy 1, but preserves the property that distinct floats have distinct representations, and tends to make for pleasanter output. This appears to be the strategy that all of the languages you tested (besides R) are using.

Compute and display 15 (or fewer) correctly-rounded significant digits. This has the effect of hiding the errors involved in the decimal-to-binary conversions, giving the illusion of exact decimal arithmetic. It has the drawback that distinct floats can have the same representation. This appears to be what R is doing. (Thanks to @hadley for pointing out in the comments that there's an R setting which controls the number of digits used for display; the default is to use 7 significant digits.)

`format(.4 + .1 + .1, digits=17)`

,`format(.4 + .2, digits=17)`

. – tonytonov Feb 19 '14 at 6:38neverexpect it to hold for any two given such numbers, consider any exceptions (precise integers or negative powers of two) merely flukes. As long as you onlycomparenumbers with`>`

, or e.g. plot something (which is very often completely sufficient), floats work great. – leftaroundabout Feb 19 '14 at 11:44