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I know that C++ provides us with a ceil function. For practice, I was wondering how can we implement the ceil function in C++. The signature of the method is public static int ceil(float num)

Please provide some insight.

I thought of a simple way: Convert num to a string, find the index of the decimal point, check if the decimal part is greater than 0. If yes, return num+1 else return num. But I want to avoid using the string conversion

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The signature of std::ceil() is not public static int ceil(float). Beware of Java or C# references that might look like C++ at a quick glance. Always make sure the reference you consult is for C++. – André Caron Dec 4 '11 at 18:34

5 Answers 5

up vote 2 down vote accepted

Here is a naive implementation for positive numbers (this uses the fact that casting to (int) truncates toward zero):

int ceil(float num) {
    int inum = (int)num;
    if (num == (float)inum) {
        return inum;
    return inum + 1;

It is easy to extend this to work with negative numbers too.

Your question asked for a function returning int, but normally the ceil() function returns the same type as its argument so there are no problems with the range (that is, float ceil(float num)). For example, the above function will fail if num is 1e20.

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Given that most integers cannot be represented exactly in popular float implementations, I doubt this is a reliable way to implement ceil(). – André Caron Dec 4 '11 at 18:37
@AndréCaron: That's true, but it shouldn't be a problem for this particular implementation, since the input to the function is not an integer. – Greg Hewgill Dec 4 '11 at 18:42
I was looking for something simple like your answer – TimeToCodeTheRoad Dec 5 '11 at 3:09
inum + 1 should be done only for positive numbers. – Jarod42 Aug 12 at 6:34

You can take apart the ingredients of an IEEE754 floating point number and implement the logic yourself:

#include <cstring>

float my_ceil(float f)
    unsigned input;
    memcpy(&input, &f, 4);
    int exponent = ((input >> 23) & 255) - 127;
    if (exponent < 0) return (f > 0);
    // small numbers get rounded to 0 or 1, depending on their sign

    int fractional_bits = 23 - exponent;
    if (fractional_bits <= 0) return f;
    // numbers without fractional bits are mapped to themselves

    unsigned integral_mask = 0xffffffff << fractional_bits;
    unsigned output = input & integral_mask;
    // round the number down by masking out the fractional bits

    memcpy(&f, &output, 4);
    if (f > 0 && output != input) ++f;
    // positive numbers need to be rounded up, not down

    return f;

(Insert the usual "not portable" disclaimer here.)

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You could use frexp and ldexp to do the extraction and recombination. – Oliver Charlesworth Dec 4 '11 at 19:42
@OliCharlesworth: frexp returns a float, not an int. How would you propose to mask out the fractional bits then? – fredoverflow Dec 4 '11 at 19:46
Can't believe yours is not the accepted answer (not to mention the accepted answer is wrong)! – BeyelerStudios Feb 8 at 19:11

That is essentially what you have to do, but without converting to string.

A floating-point number is represented as (+/-) M * 2^E. The exponent, E, tells you how far away you are from the binary point*. If E is big enough, there is no fractional part, so there's nothing to do. If E is small enough, there is no integer part, so the answer is 1 (assuming M is non-zero, and the number is positive). Otherwise, E tells you where the binary point appears within your mantissa, which you can use to do a check, and then perform rounding.

* Not decimal point, because we're in base-2, not base-10.

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@Charlesworth:yes, I know this fact. I am more concerned with how can i exploit this to determine the decimal part? – TimeToCodeTheRoad Dec 4 '11 at 18:10
@Time: You can use the frexp() function to extract M and E. You can then use E to identify how many digits in M are above the binary point, and how many are below. – Oliver Charlesworth Dec 4 '11 at 18:15

Something like this:

  double param, fractpart, intpart;

  param = 3.14159265;
  fractpart = modf (param , &intpart);

  int intv = static_cast<int>(intpart); // can overflow - so handle that.

  if (fractpart > some_epsilon)

You just need to define some_epsilon value to whatever you want the fractional part to be bigger than before the integer part is incremented. Other things to consider are sign (i.e. if the value is negative etc.)

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I would imagine that you'd want epsilon to be 0. – Oliver Charlesworth Dec 4 '11 at 19:09
@OliCharlesworth, really? shouldn't it rather be value as close to 0 as possible (say for argument sake 1E-6) to allow for representation issues? – Nim Dec 4 '11 at 21:45
Isn't that what std::numeric_limits<float>::epsilon() is for? – Violet Giraffe May 27 at 10:45

Try this...

int ceil(float val)
    int temp  = val * 10;
    return (temp+1);
    return temp;
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I was just typing that – Matt Dec 4 '11 at 18:12
Needs to be adjusted for -ve values. – Oliver Charlesworth Dec 4 '11 at 18:13
Also, it doesn't deal with e.g. val = 0.01. – Oliver Charlesworth Dec 4 '11 at 18:13
Right, and then it doesn't handle 0.001. – R. Martinho Fernandes Dec 4 '11 at 18:18
But this is not a solution to the problem of "implement ceil". – R. Martinho Fernandes Dec 4 '11 at 18:51

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