MATLAB uses the standard IEEE floating point form to store a double.

See that if we subtract off a tiny amount from 4, MATLAB still diplays 4 as the result.

```
>> format long g
>> 4 - eps(2)
ans =
4
```

In fact, MATLAB stores the number in a binary form. We can see the decimal version of that number as:

```
>> sprintf('%.55f',4-eps(2))
ans =
3.9999999999999995559107901499373838305473327636718750000
```

Clearly MATLAB should not display that entire mess of digits, but by rounding the result to 15 digits, we get 4 for the display.

Clearly, the value in calc(1,11) is such a number, represented internally as less than 4 by just a hair too little that it rounds to 4 on display, but it is NOT exactly 4.

NEVER trust the least significant displayed digit of a result in floating point arithmetic.

Edit:

You seem to think that 3.999999999999999 in MATLAB should be less than 4. Logically, this makes sense. But what happens when you supply that number? AH yes, the granularity of a floating point double is larger than that. MATLAB cannot represent it as a number less than 4. It rounds that number UP to EXACTLY 4 internally.

```
>> sprintf('%.55f',3.9999999999999999)
ans =
4.0000000000000000000000000000000000000000000000000000000
```

`calc(1,11)`

computed/loaded/generated? – tmpearce Sep 26 '12 at 21:46`3.9999999999999999999999999917825619641`

or something of the sort. Floating point math is inexact. Please read any of the other 12986125701 questions on SO showing other errors stemming from FP inaccuracies... – im so confused Sep 26 '12 at 21:57