# Understanding CEILING macro use cases

I've found the following macro in a utility header in our codebase:

``````#define CEILING(x,y) (((x) + (y) - 1) / (y))
``````

Which (with help from this answer) I've parsed as:

``````// Return the smallest multiple N of y such that:
//   x <= y * N
``````

But, no matter how much I stare at how this macro is used in our codebase, I can't understand the value of such an operation. None of the usages are commented, which seems to indicate it is something obvious.

Can anyone offer an English explanation of a use-case for this macro? It's probably blindingly obvious, I just can't see it...

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## 5 Answers

Say you want to allocate memory in chunks (think: cache lines, disk sectors); how much memory will it take to hold an integral number of chunks that will contain the `X` bytes? If the chuck size is `Y`, then the answer is: `CEILING(X,Y)`

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I upvoted all answers since they were all helpful in different ways. However, this answer is simple and direct, and gives me an easy way to consider the operation. Thanks! –  proc-self-maps Jul 6 '12 at 13:57
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When you use an integer division in C like this

``````y = a / b
``````

you get a result of division rounded towards zero, i.e. `5 / 2 == 1`, `-5 / 2 == -1`. Somtimes it's desirable to round it another way so that `5 / 2 == 2`, for example, if you want to take minimal integer array size to hold `n` bytes, you would want `n / sizeof(int)` rounded up, because you want space to hold that extra bytes.

So this macro does exactly this: `CEILING(5,2) == 2`, but note that it works for positive `y` only, so be careful.

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Let's try some test values

``````CEILING(6, 3) = (6 + 3 -1) / 3 = 8 / 3 = 2 // integer division
CEILING(7, 3) = (7 + 3 -1) / 3 = 9 / 3 = 3
CEILING(8, 3) = (8 + 3 -1) / 3 = 10 / 3 = 3
CEILING(9, 3) = (9 + 3 -1) / 3 = 11 / 3 = 3
CEILING(10, 3) = (9 + 3 -1) / 3 = 12 / 3 = 4
``````

As you see, the result of the macro is an integer, the smallest possible `z` which satisfies: `z * y >= x`.

We can try with symbolics, as well:

``````CEILING(k*y, y) = (k*y + y -1) / y = ((k+1)*y - 1) / y = k
CEILING(k*y + 1, y) = ((k*y + 1) + y -1) / y = ((k+1)*y) / y = k + 1
CEILING(k*y + 2, y) = ((k*y + 2) + y -1) / y = ((k+1)*y + 1) / y = k + 1
....
CEILING(k*y + y - 1, y) = ((k*y + y - 1) + y -1) / y = ((k+1)*y + y - 2) / y = k + 1
CEILING(k*y + y, y) = ((k*y + y) + y -1) / y = ((k+1)*y + y - 1) / y = k + 1
CEILING(k*y + y + 1, y) = ((k*y + y + 1) + y -1) / y = ((k+2)*y) / y = k + 2
``````

You canuse this to allocate memory with a size multiple of a constant, to determine how many tiles are needed to fill a screen, etc.

Watch out, though. This works only for positive `y`.

Hope it helps.

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Hmm... English example... You can only buy bananas in bunches of 5. You have 47 people who want a banana. How many bunches do you need? Answer = CEILING(47,5) = ((47 + 5) - 1) / 5 = 51 / 5 = 10 (dropping the remainder - integer division).

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Damn those banana merchants and their stubborn sales tactics! Thanks, though. It is good to step back from thinking in technical terms to understand things in a broader sense. –  proc-self-maps Jul 6 '12 at 14:07
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`CEILING(x,y)` gives you, assuming `y > 0`, the ceiling of `x/y` (mathematical division). One use case for that would be a prime sieve starting at an offset `x`, where you'd mark all multiples of the prime `y` in the sieve range as composites.

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