# Java rounding up to an int using Math.ceil

``````int total = (int) Math.ceil(157/32);
``````

Why does it still return 4? `157/32 = 4.90625`, I need to round up, I've looked around and this seems to be the right method.

I tried `total` as `double` type, but get 4.0.

What am I doing wrong?

You are doing `157/32` which is dividing two integers with each other, which always result in a rounded down integer. Therefore the `(int) Math.ceil(...)` isn't doing anything. There are three possible solutions to achieve what you want. I recommend using either option 1 or option 2. Please do NOT use option 0.

## Option 0

Convert `a` and `b` to a double, and you can use the division and `Math.ceil` as you wanted it to work. However I strongly discourage the use of this approach, because double division can be imprecise. To read more about imprecision of doubles see this question.

``````int n = (int) Math.ceil((double) a / b));
``````

## Option 1

``````int n = a / b + ((a % b == 0) ? 0 : 1);
``````

You do `a / b` with always floor if `a` and `b` are both integers. Then you have an inline if-statement witch checks whether or not you should ceil instead of floor. So +1 or +0, if there is a remainder with the division you need +1. `a % b == 0` checks for the remainder.

## Option 2

This option is very short, but maybe for some less intuitive. I think this less intuitive approach would be faster than the double division and comparison approach:
Please note that this doesn't work for `b < 0`.

``````int n = (a + b - 1) / b;
``````

To reduce the chance of overflow you could use the following. However please note that it doesn't work for `a = 0` and `b < 1`.

``````int n = (a - 1) / b + 1;
``````

## Explanation behind the "less intuitive approach"

Since dividing two integer in Java (and most other programming languages) will always floor the result. So:

``````int a, b;
int result = a/b (is the same as floor(a/b) )
``````

But we don't want `floor(a/b)`, but `ceil(a/b)`, and using the definitions and plots from Wikipedia:

With these plots of the floor and ceil function you can see the relationship.

You can see that `floor(x) <= ceil(x)`. We need `floor(x + s) = ceil(x)`. So we need to find `s`. If we take `1/2 <= s < 1` it will be just right (try some numbers and you will see it does, I find it hard myself to prove this). And `1/2 <= (b-1) / b < 1`, so

``````ceil(a/b) = floor(a/b + s)
= floor(a/b + (b-1)/b)
= floor( (a+b-1)/b) )
``````

This is not a real proof, but I hope your are satisfied with it. If someone can explain it better I would appreciate it too. Maybe ask it on MathOverflow.

• It will be a huge favour if you could explain the intuition behind the less intuitive approach? I know this is correct, I want to know how you got to it, and how can I mathematically show it is correct. I tried solving it mathematically, wasn't convinced. Apr 20 '14 at 11:40
• I hope you are satisfied with my edit, I can't do any better I think :( Apr 20 '14 at 15:39
• I assume Math.floor and ceil are only correct for integer division not for long division when values are casted to doubles. Counter examples are 4611686018427386880 / 4611686018427387137 fails on floor and 4611686018427386881 / 4611686018427386880 fails on ceil Jul 11 '16 at 12:20
• A point of clarification: The results of option 2's two sub-options are not identical in all cases. A value of zero for a will provide 0 in the first, and 1 in the second (which is not the correct answer for most applications). Aug 10 '16 at 23:31
• Are you sure you didn't mean "However please note that it doesn't work for a = 0 and b < 1" Feb 22 '17 at 19:23

157/32 is `int/int`, which results in an `int`.

Try using the double literal - `157/32d`, which is `int/double`, which results in a `double`.

`157/32` is an integer division because all numerical literals are integers unless otherwise specified with a suffix (`d` for double `l` for long)

the division is rounded down (to 4) before it is converted to a double (4.0) which is then rounded up (to 4.0)

if you use a variables you can avoid that

``````double a1=157;
double a2=32;
int total = (int) Math.ceil(a1/a2);
``````
``````int total = (int) Math.ceil((double)157/32);
``````

Nobody has mentioned the most intuitive:

``````int x = (int) Math.round(Math.ceil((double) 157 / 32));
``````

This solution fixes the double division imprecision.

• Math.round returns long Mar 28 '19 at 11:29
• Thanks @ZulqurnainJutt, added a cast Dec 20 '19 at 15:50

In Java adding a .0 will make it a double...

``````int total = (int) Math.ceil(157.0 / 32.0);
``````

When dividing two integers, e.g.,

`int c = (int) a / (int) b;`

the result is an `int`, the value of which is `a` divided by `b`, rounded toward zero. Because the result is already rounded, `ceil()` doesn't do anything. Note that this rounding is not the same as `floor()`, which rounds towards negative infinity. So, `3/2` equals `1` (and `floor(1.5)` equals `1.0`, but `(-3)/2` equals `-1` (but `floor(-1.5)` equals `-2.0`).

This is significant because if `a/b` were always the same as `floor(a / (double) b)`, then you could just implement `ceil()` of `a/b` as `-( (-a) / b)`.

The suggestion of getting `ceil(a/b)` from

`int n = (a + b - 1) / b;`, which is equivalent to `a / b + (b - 1) / b`, or `(a - 1) / b + 1`

works because `ceil(a/b)` is always one greater than `floor(a/b)`, except when `a/b` is a whole number. So, you want to bump it to (or past) the next whole number, unless `a/b` is a whole number. Adding `1 - 1 / b` will do this. For whole numbers, it won't quite push them up to the next whole number. For everything else, it will.

Yikes. Hopefully that makes sense. I'm sure there's a more mathematically elegant way to explain it.

Also to convert a number from integer to real number you can add a dot:

``````int total = (int) Math.ceil(157/32.);
``````

And the result of (157/32.) will be real too. ;)

``````int total = (int) Math.ceil( (double)157/ (double) 32);
``````

Check the solution below for your question:

``````int total = (int) Math.ceil(157/32);
``````

Here you should multiply Numerator with 1.0, then it will give your answer.

``````int total = (int) Math.ceil(157*1.0/32);
``````

Use double to cast like

`Math.ceil((double)value)` or like

``````Math.ceil((double)value1/(double)value2);
``````

Java provides only floor division `/` by default. But we can write ceiling in terms of floor. Let's see:

Any integer `y` can be written with the form `y == q*k+r`. According to the definition of floor division (here `floor`) which rounds off `r`,

``````floor(q*k+r, k) == q  , where 0 ≤ r ≤ k-1
``````

and of ceiling division (here `ceil`) which rounds up `r₁`,

``````ceil(q*k+r₁, k) == q+1  , where 1 ≤ r₁ ≤ k
``````

where we can substitute `r+1` for `r₁`:

``````ceil(q*k+r+1, k) == q+1  , where 0 ≤ r ≤ k-1
``````

Then we substitute the first equation into the third for `q` getting

``````ceil(q*k+r+1, k) == floor(q*k+r, k) + 1  , where 0 ≤ r ≤ k-1
``````

Finally, given any integer `y` where `y = q*k+r+1` for some `q`,`k`,`r`, we have

``````ceil(y, k) == floor(y-1, k) + 1
``````

And we are done. Hope this helps.

• I'm sure this is correct, but since the point of this is to clarify, it's not clear to me why `ceil` is defined as such from the intiuitive definition, in particular where we are taking the ceil of an integer, i.e. r1 = k. Since the edge cases are what's tricky about this, I think it needs to be spelled out a bit more. Dec 2 '18 at 14:29
• @LuigiPlinge To me the derivation cannot be simpler due to the intrinsic difference between floor and ceiling in context of division operation. I think you don't need to focus on the edge case - it's a natural fact when you try to unify the definitions of floor and ceiling via breaking down an integer. As a result, the proof is just three steps, and the conclusion can be roughly remembered as "one amortized step back, then one absolute step forward". Apr 3 '19 at 20:52

There are two methods by which you can round up your double value.

1. Math.ceil
2. Math.floor

If you want your answer 4.90625 as 4 then you should use Math.floor and if you want your answer 4.90625 as 5 then you can use Math.ceil

You can refer following code for that.

``````public class TestClass {

public static void main(String[] args) {
int floorValue = (int) Math.floor((double)157 / 32);
int ceilValue = (int) Math.ceil((double)157 / 32);
System.out.println("Floor: "+floorValue);
System.out.println("Ceil: "+ceilValue);

}

}
``````

I know this is an old question but in my opinion, we have a better approach which is using BigDecimal to avoid precision loss. By the way, using this solution we have the possibility to use several rounding and scale strategies.

``````final var dividend = BigDecimal.valueOf(157);
final var divisor = BigDecimal.valueOf(32);
final var result = dividend.divide(divisor, RoundingMode.CEILING).intValue();
``````
``````int total = (157-1)/32 + 1
``````

or more general

``````(a-1)/b +1
``````
• I think this works, but you've not really explained why the original version didn't work. Oct 8 '14 at 14:41
• "However please note that it doesn't work for a = 0 and b < 1" Aug 30 '17 at 8:32