I want to ensure that a division of integers is always rounded up if necessary. Is there a better way than this? There is a lot of casting going on. :-)

(int)Math.Ceiling((double)myInt1 / myInt2)
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    Can you more clearly define what you consider "better"? Faster? Shorter? More accurate? More robust? More obviously correct? – Eric Lippert May 28 '09 at 16:40
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    You always have lots of casting with maths in C# - that's why it's not a great language for this sort of thing. Do you want the values rounded up or away from zero - should -3.1 go to -3 (up) or -4 (away from zero) – Keith May 29 '09 at 10:43
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    Eric: What do you mean by "More accurate? More robust? More obviously correct?" Actually what I did mean was just "better", I would let the reader put meaning into better. So if someone had a shorter piece of code, great, if another one had a faster, also great :-) What about you do you have any suggestions? – Karsten May 29 '09 at 20:13
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    Am I the only one who, upon reading the title, though, "Oh, it's some sort of roundup of C#?" – Matt Ball Sep 16 '10 at 21:04
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    It's really amazing how subtly difficult this question turned out to be, and how instructive the discussion has been. – Justin Morgan Jan 13 '11 at 18:05

UPDATE: This question was the subject of my blog in January 2013. Thanks for the great question!

Getting integer arithmetic correct is hard. As has been demonstrated amply thus far, the moment you try to do a "clever" trick, odds are good that you've made a mistake. And when a flaw is found, changing the code to fix the flaw without considering whether the fix breaks something else is not a good problem-solving technique. So far we've had I think five different incorrect integer arithmetic solutions to this completely not-particularly-difficult problem posted.

The right way to approach integer arithmetic problems -- that is, the way that increases the likelihood of getting the answer right the first time - is to approach the problem carefully, solve it one step at a time, and use good engineering principles in doing so.

Start by reading the specification for what you're trying to replace. The specification for integer division clearly states:

  1. The division rounds the result towards zero

  2. The result is zero or positive when the two operands have the same sign and zero or negative when the two operands have opposite signs

  3. If the left operand is the smallest representable int and the right operand is –1, an overflow occurs. [...] it is implementation-defined as to whether [an ArithmeticException] is thrown or the overflow goes unreported with the resulting value being that of the left operand.

  4. If the value of the right operand is zero, a System.DivideByZeroException is thrown.

What we want is an integer division function which computes the quotient but rounds the result always upwards, not always towards zero.

So write a specification for that function. Our function int DivRoundUp(int dividend, int divisor) must have behaviour defined for every possible input. That undefined behaviour is deeply worrying, so let's eliminate it. We'll say that our operation has this specification:

  1. operation throws if divisor is zero

  2. operation throws if dividend is int.minval and divisor is -1

  3. if there is no remainder -- division is 'even' -- then the return value is the integral quotient

  4. Otherwise it returns the smallest integer that is greater than the quotient, that is, it always rounds up.

Now we have a specification, so we know we can come up with a testable design. Suppose we add an additional design criterion that the problem be solved solely with integer arithmetic, rather than computing the quotient as a double, since the "double" solution has been explicitly rejected in the problem statement.

So what must we compute? Clearly, to meet our spec while remaining solely in integer arithmetic, we need to know three facts. First, what was the integer quotient? Second, was the division free of remainder? And third, if not, was the integer quotient computed by rounding up or down?

Now that we have a specification and a design, we can start writing code.

public static int DivRoundUp(int dividend, int divisor)
  if (divisor == 0 ) throw ...
  if (divisor == -1 && dividend == Int32.MinValue) throw ...
  int roundedTowardsZeroQuotient = dividend / divisor;
  bool dividedEvenly = (dividend % divisor) == 0;
  if (dividedEvenly) 
    return roundedTowardsZeroQuotient;

  // At this point we know that divisor was not zero 
  // (because we would have thrown) and we know that 
  // dividend was not zero (because there would have been no remainder)
  // Therefore both are non-zero.  Either they are of the same sign, 
  // or opposite signs. If they're of opposite sign then we rounded 
  // UP towards zero so we're done. If they're of the same sign then 
  // we rounded DOWN towards zero, so we need to add one.

  bool wasRoundedDown = ((divisor > 0) == (dividend > 0));
  if (wasRoundedDown) 
    return roundedTowardsZeroQuotient + 1;
    return roundedTowardsZeroQuotient;

Is this clever? No. Beautiful? No. Short? No. Correct according to the specification? I believe so, but I have not fully tested it. It looks pretty good though.

We're professionals here; use good engineering practices. Research your tools, specify the desired behaviour, consider error cases first, and write the code to emphasize its obvious correctness. And when you find a bug, consider whether your algorithm is deeply flawed to begin with before you just randomly start swapping the directions of comparisons around and break stuff that already works.

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    Excellent exemplary answer – Gavin Miller May 29 '09 at 20:29
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    What I care about is not the behaviour; either behaviour seems justifiable. What I care about is that it's not specified, which means it cannot easily be tested. In this case, we're defining our own operator, so we can specify whatever behaviour we like. i don't care whether that behaviour is "throw" or "don't throw", but I do care that it be stated. – Eric Lippert May 30 '09 at 6:27
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    Darn it, pedantry fail :( – Jon Skeet Jun 10 '09 at 15:57
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    Man - Could you write a book on that, please? – xtofl Sep 8 '09 at 6:52
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    @finnw: Whether I've tested it or not is irrelevant. Solving this integer arithmetic problem isn't my business problem; if it were, then I'd be testing it. If someone wants to take code from strangers off the internet to solve their business problem then the onus is on them to thoroughly test it. – Eric Lippert May 4 '11 at 16:21

The final int-based answer

For signed integers:

int div = a / b;
if (((a ^ b) >= 0) && (a % b != 0))

For unsigned integers:

int div = a / b;
if (a % b != 0)

The reasoning for this answer

Integer division '/' is defined to round towards zero (7.7.2 of the spec), but we want to round up. This means that negative answers are already rounded correctly, but positive answers need to be adjusted.

Non-zero positive answers are easy to detect, but answer zero is a little trickier, since that can be either the rounding up of a negative value or the rounding down of a positive one.

The safest bet is to detect when the answer should be positive by checking that the signs of both integers are identical. Integer xor operator '^' on the two values will result in a 0 sign-bit when this is the case, meaning a non-negative result, so the check (a ^ b) >= 0 determines that the result should have been positive before rounding. Also note that for unsigned integers, every answer is obviously positive, so this check can be omitted.

The only check remaining is then whether any rounding has occurred, for which a % b != 0 will do the job.

Lessons learned

Arithmetic (integer or otherwise) isn't nearly as simple as it seems. Thinking carefully required at all times.

Also, although my final answer is perhaps not as 'simple' or 'obvious' or perhaps even 'fast' as the floating point answers, it has one very strong redeeming quality for me; I have now reasoned through the answer, so I am actually certain it is correct (until someone smarter tells me otherwise -furtive glance in Eric's direction-).

To get the same feeling of certainty about the floating point answer, I'd have to do more (and possibly more complicated) thinking about whether there is any conditions under which the floating-point precision might get in the way, and whether Math.Ceiling perhaps does something undesirable on 'just the right' inputs.

The path travelled

Replace (note I replaced the second myInt1 with myInt2, assuming that was what you meant):

(int)Math.Ceiling((double)myInt1 / myInt2)


(myInt1 - 1 + myInt2) / myInt2

The only caveat being that if myInt1 - 1 + myInt2 overflows the integer type you are using, you might not get what you expect.

Reason this is wrong: -1000000 and 3999 should give -250, this gives -249

Considering this has the same error as the other integer solution for negative myInt1 values, it might be easier to do something like:

int rem;
int div = Math.DivRem(myInt1, myInt2, out rem);
if (rem > 0)

That should give the correct result in div using only integer operations.

Reason this is wrong: -1 and -5 should give 1, this gives 0

EDIT (once more, with feeling):
The division operator rounds towards zero; for negative results this is exactly right, so only non-negative results need adjustment. Also considering that DivRem just does a / and a % anyway, let's skip the call (and start with the easy comparison to avoid modulo calculation when it is not needed):

int div = myInt1 / myInt2;
if ((div >= 0) && (myInt1 % myInt2 != 0))

Reason this is wrong: -1 and 5 should give 0, this gives 1

(In my own defence of the last attempt I should never have attempted a reasoned answer while my mind was telling me I was 2 hours late for sleep)

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All the answers here so far seem rather over-complicated.

In C# and Java, for positive dividend and divisor, you simply need to do:

( dividend + divisor - 1 ) / divisor 

Source: Number Conversion, Roland Backhouse, 2001

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  • Awesome. Although, you should've added the parentheses, to remove the ambiguities.The proof for it was a bit lengthy, but you can feel it in the gut, that it is right, just by looking at it. – Jörgen Sigvardsson Dec 5 '10 at 20:37
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    Hmmm... what about dividend=4, divisor=(-2)??? 4 / (-2) = (-2) = (-2) after being rounded up. but the algorithm you provided (4 + (-2) - 1) / (-2) = 1 / (-2) = (-0.5) = 0 after being rounded up. – Scott Feb 17 '11 at 21:41
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    @Scott - sorry, I omitted to mention that this solution only holds for positive dividend and divisor. I have updated my answer to mention clarify this. – Ian Nelson Feb 18 '11 at 8:44
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    i like it, of course you could have a somewhat artificial overflow in the numerator as a byproduct of this approach ... – TCC Oct 11 '13 at 20:52
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    @PIntag: The idea is good, but the use of modulo wrong. Take 13 and 3. Expected result 5, but ((13-1)%3)+1) gives 1 as result. Taking the right kind of division, 1+(dividend - 1)/divisor gives the same result as the answer for positive dividend and divisor. Also, no overflow problems, however artificial they may be. – Lutz Lehmann Mar 8 '14 at 21:46

Perfect chance to use an extension method:

public static class Int32Methods
    public static int DivideByAndRoundUp(this int number, int divideBy)
        return (int)Math.Ceiling((float)number / (float)divideBy);

This makes your code uber readable too:

int result = myInt.DivideByAndRoundUp(4);
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    Erm, what? Your code would be called myInt.DivideByAndRoundUp() and would always return 1 except for an input of 0 which would cause an Exception... – configurator Sep 20 '09 at 3:59
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    Epic failure. (-2).DivideByAndRoundUp(2) returns 0. – Timwi Oct 6 '09 at 13:21
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    I'm really late to the party, but does this code compile? My Math class does not contain a Ceiling method that takes two arguments. – R. Martinho Fernandes Apr 3 '10 at 3:46

You could write a helper.

static int DivideRoundUp(int p1, int p2) {
  return (int)Math.Ceiling((double)p1 / p2);
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    Still the same amount of casting going on though – ChrisF May 29 '09 at 10:24
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    @Outlaw, presume all you want. But for me if they don't put it into the question, I generally assume they didn't consider it. – JaredPar Aug 28 '09 at 18:34
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    Writing a helper is useless if it is just that. Instead, write a helper with a comprehensive test suite. – dolmen Aug 2 '11 at 8:27
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    @dolmen Are you familiar with the concept of code reuse? o.O – Rushyo Aug 30 '12 at 15:27

You could use something like the following.

a / b + ((Math.Sign(a) * Math.Sign(b) > 0) && (a % b != 0)) ? 1 : 0)
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    This code is obviously wrong in two ways. First off, there is a minor error in syntax; you need more parentheses. But more importantly, it does not compute the desired result. For example, try testing with a=-1000000 and b = 3999. The regular integer division result is -250. The double division is -250.0625... The desired behaviour is to round up. Clearly the correct rounding up from -250.0625 is to round up to -250, but your code rounds up to -249. – Eric Lippert May 28 '09 at 16:17
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    I'm sorry to have to keep saying this but your code is STILL WRONG Daniel. 1/2 should round UP to 1, but your code rounds it DOWN to 0. Every time I find a bug you "fix" it by introducing another bug. My advice: stop doing that. When someone finds a bug in your code, don't just slap together a fix without thinking through clearly what caused the bug in the first place. Use good engineering practices; find the flaw in the algorithm and fix it. The flaw in all three incorrect versions of your algorithm is that you are not correctly determining when the rounding was "down". – Eric Lippert May 29 '09 at 16:23
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    Unbelievable how many bugs can be in this small piece of code. I did never have much time to think about it - the result manifests in the comments. (1) a * b > 0 would be correct if it did not overflow. There are 9 combinations for the sign of a and b - [-1, 0, +1] x [-1, 0, +1]. We can ignore the case b == 0 leaving the 6 cases [-1, 0, +1] x [-1, +1]. a / b rounds towards zero, that is rounding up for negative results and rounding down for positve resuls. Hence the adjustment must be performed if a and b have the same sign and are not both zero. – Daniel Brückner May 30 '09 at 10:24
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    This answer is probably the worst thing I wrote on SO ... and it is now linked by Eric's blog... Well, my intention was not to give a readable solution; I was really locking for a short and fast hack. And to defend my solution again, I got the idea right the first time, but did not think about overflows. It was obviously my mistake to post the code without writing and testing it in VisualStudio. The "fixes" are even worse - I did not realize that it was an overflow problem and thought I made an logical mistake. In consequence the first "fixes" did not change anything; I just inverted the – Daniel Brückner Nov 20 '09 at 12:05
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    logic and pushed the bug around. Here I made the next mistakes; as Eric already mentioned I did not really analyze the bug and just did the first thing that seemed right. And I still did not use VisualStudio. Okay, I was in a hurry and did not spend more then five minutes on the "fix", but this should not be an excuse. After I Eric repeatedly pointed out the bug, I fired up VisualStudio and found the real problem. The fix using Sign() makes the thing even more unreadable and turns it into code you don't really want to maintain. I learned my lesson and will no longer underestimate how tricky – Daniel Brückner Nov 20 '09 at 12:12

Some of the above answers use floats, this is inefficient and really not necessary. For unsigned ints this is an efficient answer for int1/int2:

(int1 == 0) ? 0 : (int1 - 1) / int2 + 1;

For signed ints this will not be correct

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  • Not what the OP asked in the first place, does not really add to the other answers. – santamanno Nov 3 '19 at 22:27

The problem with all the solutions here is either that they need a cast or they have a numerical problem. Casting to float or double is always an option, but we can do better.

When you use the code of the answer from @jerryjvl

int div = myInt1 / myInt2;
if ((div >= 0) && (myInt1 % myInt2 != 0))

there is a rounding error. 1 / 5 would round up, because 1 % 5 != 0. But this is wrong, because rounding will only occur if you replace the 1 with a 3, so the result is 0.6. We need to find a way to round up when the calculation give us a value greater than or equal to 0.5. The result of the modulo operator in the upper example has a range from 0 to myInt2-1. The rounding will only occur if the remainder is greater than 50% of the divisor. So the adjusted code looks like this:

int div = myInt1 / myInt2;
if (myInt1 % myInt2 >= myInt2 / 2)

Of course we have a rounding problem at myInt2 / 2 too, but this result will give you a better rounding solution than the other ones on this site.

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  • "We need to find a way to round up when the calculation give us a value greater than or equal to 0.5" - you've missed the point of this question - or always round up i.e. the OP wants to round up 0.001 to 1 . – Grhm Jan 30 '13 at 13:37

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