First of all, I was not studying math in English language, so I may use wrong words in my text.

**Float numbers can be finite(42.36) and infinite (42.363636...)**

**In C/C++ numbers are stored at base 2**. **Our minds operate floats at base 10**.

The problem is -

`many (a lot, actually) of float numbers with base 10, that are finite, have no exact finite representation in base 2, and vice-versa.`

This doesn't mean anything most of the time. The **last digit of double may be off by 1 bit** - not a problem.

A problem arises when we compute two floats that are actually integers. `99.0/3.0`

on C++ can result in `33.0`

as well as `32.9999...99`

. And if you convert it to integer then - you are in for a surprise. I always add a special value **(2*smallest value for given type and architecture)** before rounding up in C for this reason. Should I do it in **Python or not**?

I have run some tests in Python and it *seems* float division always results as expected. But *some tests* are not enough because the problem is architecture-dependent. Do somebody know for sure if it is taken care of, and on what level - in float type itself or only in rounding up and shortening functions?

P.S. And if somebody can clarify the same thing for **Haskell**, which I am only starting with - it would be great.

**UPDATE**
Folks pointed out to an official document stating there *is* uncertainty in floating point arithmetic. The remaining question is - do `math`

functions like `ceil`

take care of them or should I do it on my own? This **must** be pointed out to beginner users every time we speak of these functions, because otherwise they will all stumble on that problem.

`math.ceil((0.1 + 0.2)*10)`

is`4.0`

. So no,`ceil`

does not "take care" of floating point issues. – unutbu Apr 2 '14 at 12:42approximate representationof real numbers with which mathematic applications deal. The representation is always finite and, unless you positively can prove the opposite, must be thought of as inexact. There are coutable subclasses of real numbers which can be represented exactly. The most useful one is that of rational numbers. Unlike most languages, Haskell has out-of-the-box support for exact representation rational numbers, but that's a different story. – Andrey Chernyakhovskiy Apr 2 '14 at 12:42