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)
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:
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
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.
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.
The final int-based answer
For signed integers:
For unsigned integers:
The reasoning for this answer
Integer division '
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 '
The only check remaining is then whether any rounding has occurred, for which
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
The path travelled
Replace (note I replaced the second
The only caveat being that if
Reason this is wrong: -1000000 and 3999 should give -250, this gives -249
That should give the correct result in
Reason this is wrong: -1 and -5 should give 1, this gives 0
EDIT (once more, with feeling):
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)
All the answers here so far seem rather over-complicated.
In C# and Java, for positive dividend and divisor, you simply need to do:
Perfect chance to use an extension method:
This makes your code uber readable too:
You could write a helper.
You could use something like the following.
Maybe unit testing would be valid here? You can very easily put together a suite of tests with expected values and run as many attempts as you like through them until you get some code that works.
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
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:
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.