# Matlab floor bug?

I think I found a bug in Matlab. My only explanation is, that matlab calculates internally with other values than the ones which are displayed:

``````K>> calc(1,11)

ans =

4.000000000000000

K>> floor(ans)

ans =

3
``````

Displayed code is an output from the Matlab console. calc(x,y) is just an array of double values.

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how was the value `calc(1,11)` computed/loaded/generated? – tmpearce Sep 26 '12 at 21:46
found this. it's for python but it may give an idea.. – gokcehan Sep 26 '12 at 21:50
I suspect if you took calc(1,11) out to its full precision, you would find that it is `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
No. it is not a bug, so you are apparently not as familiar as you think with floating point. – user85109 Sep 26 '12 at 22:50
like my old professor of programming 101 said: "Don't you ever dare claiming that C/Matlab/whatheverlanguage is bugged! 99.999% of the cases is your fault / you don't know enough!" – Batsu Sep 26 '12 at 23:36

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
``````
-

What you got was a value really close to but lower than 4, and even with `format long` Matlab has to round to the 15th digit to display the number. Try this:

``````format long
asd = 3.9999999999999997 %first not-9 @16th digit
``````

gives `4.000000000000000`. So if I didn't already know the real value of `asd` I should suspect it is at least 4, but

``````asd >= 4
``````

gives `0`, and so `floor(asd)` returns `3`.

So is a matter of how Matlab rounds the displayed output, the true value stored in the variable is less than 4.

UPDATE:

if you go further with the digits, like 18x9:

``````>> asd = 3.999999999999999999
asd =
4
>> asd == 4
ans =
1
``````

`asd` becomes exactly `4`! (notice is no more `4.000000000000000`) But that's another story, is no more about rounding the number to have a prettier output, but about how the floating point arithmetic works... Real numbers can be represented up to a certain relative precision: in this case the number you gave is so close to 4 that it becomes 4 itself. Take a look to the Python link posted in the comment by @gokcehan, or here.

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My Problem is, that in this case floor() still returns the expected value. E.g. B = 3.9999999999999999 --> B = 4 --> floor(B) = 4. This doesn't match floor(4.00000......) = 3 – uǝq Sep 26 '12 at 23:01
that's because you added even more digits, now is about floating point representation. I updated the answer. – Batsu Sep 26 '12 at 23:23
@Batsu Did you mean to write "`floor(asd)` returns `3`"? (nice answer though, +1) – Colin T Bowers Sep 27 '12 at 0:29
you're right, fixed – Batsu Sep 27 '12 at 7:57

I won't go over the problem, instead I will offer a solution: Use the `single` function:

B = single(A) converts the matrix A to single precision, returning that value in B. A can be any numeric object (such as a double). If A is already single precision, single has no effect. Single-precision quantities require less storage than double-precision quantities, but have less precision and a smaller range.

This is only meant to be a fix to this particular issue, so you would do:

``````K>> calc(1,11)

ans =

4.000000000000000

K>> floor(single(ans))

ans =

4
``````
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