# Strange results with C++ ceiling function

I've been trying the ceiling function and have been getting some strange results. If I perform the ceil operation on a decimal number multiplied by hundred I get a certain result. However if i directly perform ceil on the result of that multiplication I get a completely different output. Another twist is that these different results only occur for certain numbers. Any help would be appreciated.

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

int main ()
{
cout << "The ceiling of " << 411 << " is " << ceil(411) << endl;
cout << "The ceiling of 4.11*100  is " << ceil(4.11*100) << endl;

cout << "The ceiling of  " << 121 << " is " << ceil(121) << endl;
cout << "The ceiling of 1.21*100  is " << ceil(1.21*100) << endl;;
}

OUTPUT:

The ceiling of 411 is 411
The ceiling of 4.11*100  is 412
The ceiling of  121 is 121
The ceiling of 1.21*100  is 121
``````
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The problem here is that floating-point numbers cannot be reliably represented by computer. That means, `4.11` is not represented as `4.11`, but something very close to it. And when this "very close to 4.11" number is multiplied by `100`, the `ceil` of the product turns out to be `412`, much to your surprise! But once you know how floating-point numbers are stored and retrieved, it's not a surprise at all.

Just see this interesting demonstration:

``````float a = 3.2; //3.2 is double!
if ( a == 3.2 )
cout << "a is equal to 3.2"<<endl;
else
cout << "a is not equal to 3.2"<<endl;

float b = 3.2f; //3.2f is a float. Note: f is appended to make it float!
if ( b == 3.2f )
cout << "b is equal to 3.2f"<<endl;
else
cout << "b is not equal to 3.2f"<<endl;
``````

Output:

a is not equal to 3.2
b is equal to 3.2f

Do experiment here at ideone: http://www.ideone.com/pAGzM

Try changing the type of the variable `a` from `float` to `double`, see the result again.

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But the same occurs even if I use double. And this consistently happens with some numbers but doesn't happen with others that's what really confuses me. –  sowmya Apr 6 '11 at 7:07
You do use `double` in your sample code. No `float` numbers are used there. –  Serge Dundich Apr 6 '11 at 7:13
@sowmya: "shouldn't i get 412 if I just simply multiply 4.11*100" No, you shouldn't. You get 411 + very_very_small_number. `ceil(411)` would return 411. But `ceil( 411 + very_very_small_number )` returns 412. –  Serge Dundich Apr 6 '11 at 7:32
@sowmya: Great! May be you accept the answer that helped you the most. –  Serge Dundich Apr 6 '11 at 8:08
I'ld take issue with the wording in the original answer: floating-point numbers are exact and reliable on the computer. The problem is that computer floating-point numbers are not real numbers, most real numbers cannot be represented by a computer floating-point number, and floating-point arithmetic doesn't follow the rules of real number arithmetic. Only an infinitely small subset of the real numbers have a representation in machine floating point (411 is one of them, but 4.11 isn't), and `a + (b + c)` isn't necessarily the same as `(a + b) + c`.) –  James Kanze Apr 6 '11 at 8:23

From the FAQ:

[29.16] Why is floating point so inaccurate? Why doesn't this print 0.43?

``````#include <iostream>

int main()
{
float a = 1000.43;
float b = 1000.0;
std::cout << a - b << '\n';
...
}
``````

Disclaimer: Frustration with rounding/truncation/approximation isn't really a C++ issue; it's a computer science issue. However, people keep asking about it on comp.lang.c++, so what follows is a nominal answer.

Answer: Floating point is an approximation. The IEEE standard for 32 bit float supports 1 bit of sign, 8 bits of exponent, and 23 bits of mantissa. Since a normalized binary-point mantissa always has the form 1.xxxxx... the leading 1 is dropped and you get effectively 24 bits of mantissa. The number 1000.43 (and many, many others, including some really common ones like 0.1) is not exactly representable in float or double format. 1000.43 is actually represented as the following bitpattern (the "s" shows the position of the sign bit, the "e"s show the positions of the exponent bits, and the "m"s show the positions of the mantissa bits):

`````` seeeeeeeemmmmmmmmmmmmmmmmmmmmmmm
01000100011110100001101110000101
``````

The shifted mantissa is 1111101000.01101110000101 or 1000 + 7045/16384. The fractional part is 0.429992675781. With 24 bits of mantissa you only get about 1 part in 16M of precision for float. The double type provides more precision (53 bits of mantissa).

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The `ceil(x)` function returns the smallest integral number not less then `x`.

Since the constants you type (like `4.11` or `1.21`) is not represented precisely - they may happen to be represented with slightly smaller number or with slightly larger number or in rare cases with equal numbers. E.g. your compiler represents constant `4.11` as a slightly larger number so `4.11*100` happens to be slightly larger than 411 so `ceil(4.11*100) == 412` (because 412 is the smallest number not less than the number slightly larger than 411), but `1.21` is represented as slightly smaller number so `1.21*100` is slightly smaller than 121 so `ceil(1.21*100)==121`.

Also note that multiplication is not precise too.

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