# Simple floating point multiplication not giving expected result [duplicate]

When given the input `150`, I expect the output to be the mathematically correct answer `70685.7750`, but I am getting the wrong output `70685.7812`.

``````#include<stdio.h>

int main()
{
float A,n,R;

n=3.14159;

scanf("%f",&R);
A=n*(R*R);

printf("A=%.4f\n",A);
}
``````
• Give it another input? – Antti Haapala Sep 6 '19 at 5:36
• Or try using `double`s instead of `float`s, at least the precision is more than 7 digits – Antti Haapala Sep 6 '19 at 5:39
• Why are you expecting that specific output? What is the input for which you expect that? (Consider repeating the desired output in the body to make understanding the question easier.) Joke answer to clarify what I mean: `printf("A=70685.7750\n");` – Yunnosch Sep 6 '19 at 5:49
• The number 3.14159 cannot be stored exactly in an IEE-754 32 bit float - the closest value is approximately 3.14159012. 150*150*3.14159012 is 70685.7777, and the closest value to this that can be represented is 70685.78125, which you are then printing with `%.4f` so you see 70685.7812. – caf Sep 6 '19 at 6:22
• @Yunnosch: It seems to me that the only thing really missing from the question was the input number, which was probably an oversight. Sometimes I think a demonstration of how a question could have been improved is in order. – caf Sep 6 '19 at 6:41

`float` and `double` numbers are not represented very accurately in the memory. The main reason is that the memory is limited, and most non-integers are not.

The best example is `PI`. You can specify as many digits as you want, but it will still be an approximation.

The limited precision of representing the numbers is the reason of the following rule:

when working with `floats` and `double` numbers, not not check for equality (`m == n`), but check that the difference between them is smaller than a certain error (`(m-n) < e`)

Please note, as mentioned in the comments too, that the above rule is not "the mother rule of all rules". There are other rules also.

Careful analysis must be done for each particular situation, in order to have a properly working application.

(Thanks @EricPostpischil for the reminder)

• “Compare with a tolerance” is bad general advice because, although it may reduce false negatives, it increases false positives. Without knowing the purpose of the comparison, this can break an application. For more, see this, this, and this. – Eric Postpischil Sep 6 '19 at 11:57
• I agree that there is no clear solution. Some false results may happen, and the algorithm must be chosen according to the analysis of each particular situation. – virolino Sep 6 '19 at 12:10

It is common for a variable of type `float` to be an IEEE-754 32-bit floating point number.

The number `3.14159` cannot be stored exactly in an IEEE-754 32-bit float - the closest value is approximately `3.14159012`. `150 * 150 * 3.14159012` is `70685.7777`, and the closest value to this that can be represented in a 32-bit float is `70685.78125`, which you are then printing with `%.4f` so you see `70685.7812`.

Another way of thinking about this is that your `n` value only ends up being accurate to the sixth significant figure, so - as you are just calculating a series of multiplications - your result is also only acccurate to the sixth significant figure (ie `70685.8`). (In the general case this can be worse - for example subtraction of two close values can lead to a large increase in the relative error).

If you switch to using variables of type `double` (and change the `scanf()` to use `%lf`), then you will likely get the answer you are after. `double` is typically a 64-bit float, which means that the error in the representation of your `n` values and the result is small enough not to affect the fourth decimal place.

• It is not good to teach that a numerical format which represents six significant decimal digits generally produces results accurate to six significant figures. In anything but the simplest computations, numerical errors compound in complicated and hard-to-predict ways (there is an entire field of study for them), and the final error can range from zero to infinity or even fail to produce numerical results at all. – Eric Postpischil Sep 6 '19 at 12:00
• @EricPostpischil: I did not intend to imply anything about the general case, I have updated the answer to make this clear. – caf Sep 6 '19 at 13:31

Have you heard that `float` and `double` values aren't always perfectly accurate, have limited precision? Have you heard that type `float` gives you the equivalent of only about 7 decimal digits' worth of precision? This is what that means. Your expected and actual answers, 70685.7750 and 70685.7812, differ in the seventh digit, just about as expected.

I expect the output to be the mathematically correct answer

I am sorry to disappoint you, but that's your mistake. As a general rule, when you're doing floating-point arithmetic, you will never get the mathematically correct answer, you will always get a limited-precision approximation of the mathematically correct answer.

The canonical SO answers to this sort of question are collected at Is floating point math broken?. You might want to read some of those answers for more enlightenment.