# Fast Floor and Ceiling alternatives for positive System.Double values

``````double d = 0; // random decimal value with it's integral part within the range of Int32 and always positive.
int floored = (int) Math.Floor(d); // Less than or equal to.
int ceiled  = (int) Math.Ceiling(d); // Greater than or equal to.
int lessThan = ? // Less than.
int moreThan = ? // Greater than.
``````

The Floor and ceiling functions include the largest/smallest integer that is less than/greater than or equal to `d` respectively. I want to find out the largest/smallest integer that is less than/greater than but NOT equal to `d` respectively.

OF course this can be achieved through a few `if's and but's` but I am looking for a method that either does not include branching or is at least a very fast since this operation will be performed billions of times in an algorithm.

Is binary manipulation possible? If not, what would be the best alternative?

The obvious solution would be something like:

``````int lessThan = (d - floored) > double.Epsilon ? floored : (floored-1);
int moreThan = (ceiled - d) > double.Epsilon ? ceiled : (ceiled+1);
``````

NOTE: The objective is to find out whether `d` is closer to `lessThan` or `moreThan`.

-
Have you tried to implement it in using the few ifs and actually measured that it's too slow for you? – svick Aug 12 '12 at 14:57
It's already implemented as above. I'm trying to speed up the algorithm by optimizing it in various ways. – Raheel Khan Aug 12 '12 at 15:01
Is `d` always positive? – harold Aug 12 '12 at 15:06
Yes, always positive. – Raheel Khan Aug 12 '12 at 15:07
Doesn't that mean you actually want to know whether `d % 1` is more than or less than a half or 0 (special case)? – harold Aug 12 '12 at 15:24

Since `d` is always positive, you can use that casting to an integer truncates (ie it's the floor for positive input and the ceiling for negative input).

`floor(d + 1)` is the same as `ceil(d) + 1 if integer, ceil(d) otherwise` and `ceil(d - 1)` is the same as `floor(d) - 1 if integer, floor(d) otherwise`

``````int moreThan = (int)(d + 1); // floor(d + 1)
int lessThan = int.MaxValue + (int)((d - int.MaxValue) - 1) // ceil(d - 1)
``````

The `lessThan` is somewhat convoluted, I wouldn't be surprised if someone else has a better idea.

But since you want this:

The objective is to find out whether d is closer to lessThan or moreThan

It should be even simpler:

``````double x = d % 1;
if (x == 0 || x == 0.5)
// d is equally far from either one, either by a difference of 1 or of 0.5
else if (x < 0.5)
// d is closer to lessThan
else
// d is closer to moreThan
``````
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Thanks. I understand moreThan. Could you please explain why you use int.MaxValue for lessThan? – Raheel Khan Aug 12 '12 at 15:41
@RaheelKhan the idea there is to "shift" (as opposed to "mirroring", which is what negation would do) `d` into the negatives so that casting to int rounds the other way. It doesn't have to be `int.MaxValue`, just the maximum value that `d` can take. – harold Aug 12 '12 at 15:43
Perfect. I just did some comparison and overhead of addition / subtraction is far less than branching on the target. Will just make sure if there are any corner cases to be considered for lessThan. – Raheel Khan Aug 12 '12 at 15:47

I can missunderstand question, but to find nearest integer value of d:

``````int floored = (int)d;
int ceiled = (int)(d + 1);
int mathRounded = (int)(d + 0.5)
``````
-

Haven't perf tested this but you could test to see if your double is an integer already and then perform the appropriate operation:

``````double d = 0;
int lessThan;
int moreThan;

if (d % 1 == 0)
{
lessThan = d - 1;
moreThan = d + 1;
}
else
{
lessThan = (int) Math.Floor(d);
moreThan  = (int) Math.Ceiling(d);
}
``````
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If `(d - ((int) d)` is less than `double.Epsilon`, then `d % 1 == 0` would also be true right? – Raheel Khan Aug 12 '12 at 15:35
I believe so for positive values of d. – David Archer Aug 12 '12 at 15:56

I don't know what results you want to achieve at the end.

If you want the ceil, floor and what is the closest:

``````int lessThan = (int) Math.Floor(d); // Less than or equal to.
int moreThan = (int) Math.Ceiling(d); // Greater than or equal to.

if (lessThan == moreThan)
{
lessThan--;
moreThan++;
}

bool isCloserToFloor = (d - .5) < lessThan;
bool isCloserToCeil = !isCloserToFloor;
``````
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Your if branch will never be hit. – Raheel Khan Aug 12 '12 at 15:24
Why not? Math.Floor and Math.Ceiling will return the same integer if the floor and ceiling are equal to `d`. Test it and tell me. – devundef Aug 12 '12 at 15:26
Ummm... Not sure I understand, Floor and Ceiling will only be the same if `d` were itself an integer (which will not be the case here). – Raheel Khan Aug 12 '12 at 15:29
Well, the only way the Floor and Ceil return a value that is equal to `d` is if `d` itself is an integer (on a decimal struct). If you're sure that `d` will never be an integral value, then you don't need to make any check, just use `Math.Floor` and `Ceiling` that you will always get the correct values for lessThan and moreThan. – devundef Aug 12 '12 at 15:30

You can cheat a bit: use Convert.ToInt32(bool):

``````double d = 0; // random decimal value with it's integral part within the range of Int32 and always positive.
int floored = (int) Math.Floor(d); // Less than or equal to.
int ceiled  = (int) Math.Ceiling(d); // Greater than or equal to.
int lessThan = floored - Convert.ToInt32(Math.Abs(d-floored) < epsilon);
int moreThan = ceiled + Convert.ToInt32(Math.Abs(d-ceiled) < epsilon);
``````
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Thanks. Could you explain the last two lines please. – Raheel Khan Aug 12 '12 at 15:37
@Raheel Khan: Convert.ToInt32(true) == 1; Convert.ToInt32(false) == 0; We just want to substract 1 when Math.Abs(d-floored) < epsilon and add 1 when Math.Abs(d-ceiled) < epsilon and do nothing in other case. Convert.ToInt32(bool) is exactly what we need – dvvrd Aug 12 '12 at 15:39
Hmmm... I like the syntax but will have to test this. Convert.ToInt32 is a method call and the overhead may outweigh even branching. – Raheel Khan Aug 12 '12 at 15:49
@Raheel Khan: Could you please tell the results of the test here, I am really interested about the speed of this code in the release mode – dvvrd Aug 12 '12 at 15:56
Keeping harold's reply above as the benchmark (5.64 seconds) for 1 billion iterations of my function, replacing with your code takes about 6.26 seconds. That is (four add/subtract, 2 casts) versus (two add/subtract, two functions, one comparison) in your case. The difference adds up since I using this for an algorithm that runs for hours on end. – Raheel Khan Aug 12 '12 at 16:19