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i am trying to find total pages in building a pager on a website (so i want the result to be an integer. i get a list of records and i want to split into 10 per page (the page count)

when i do this:

list.Count() / 10

or

list.Count() / (decimal)10

and the list.Count() =12, i get a result of 1.

How would I code it so i get 2 in this case (the remainder should always add 1)

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marked as duplicate by Liam, nvoigt, Mormegil, Adriano Repetti, peko Dec 16 '13 at 12:57

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

3  
(list.Count()+9)/10 - that's the best :) –  bestsss Jan 31 '11 at 0:18
    
Math.Round(8.28, 0, MidpointRounding.AwayFromZero) –  Andreas Sep 10 '14 at 6:07

8 Answers 8

up vote 57 down vote accepted
Math.Ceiling((double)list.Count() / 10);
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2  
converting int to floating point is just bad (and slow) for such a simple operation –  bestsss Jan 31 '11 at 0:19
    
@Rob, you do.. twice, int->floating point(double)->int. it requires double flush of the CPU, the solution is the worst possible correct (for int but not long) one –  bestsss Jan 31 '11 at 0:26
1  
@Rob - The difference is not simply in the floating point conversion, you also have additional function call overhead for the call to Ceiling(). This isn't "extra readability" it's "extra work" and is not the right way to do this. This question gets asked in myriad ways over and over again on SO and there is a better solution that involves no typecasting and no additional functional call. New programmers need to learn to do it the right way. It turns out doing it correctly is quite readable and seeing someone do it wrong calls all of their code into question. –  par Jan 31 '11 at 0:42
    
@Rob, you sure all your code was not dead code eliminated? Do you know how to write proper micro-benchmark (almost all developers don't know, so it's a fair question) –  bestsss Jan 31 '11 at 0:47
    
I'll point out also that your solution requires Math.Ceiling() to be available. The solution utilizing knowledge of basic integer math is completely portable. –  par Jan 31 '11 at 0:54

This will also work:

c = (count - 1) / 10 + 1;
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I like this most, very nice –  Ondrej Petrzilka Nov 23 '13 at 19:14
    
I see multiple problems with your code, especially with numbers like 0 and 20(would return 3) or any larger number than 10. –  Rumplin Mar 22 '14 at 9:05
    
@Rumplin, you are right about 0, but for 20 it returns 2 as expected. –  finnw Mar 28 '14 at 4:02
    
You are right, it works ok for number > 0 –  Rumplin Mar 28 '14 at 11:31
    
A nice solution, but IMO this is less readable than using Math.Ceiling. At a glance it is not clear what the code is meant to be doing. –  Co7e Jan 21 at 10:14

A proper benchamrk or how the number may lie

Following the argument about Math.ceil(value/10d) and (value+9)/10 I ended up coding a proper non-dead code, non-interpret mode benchmark. I've been telling that wring micro benchmark is not an easy task. The code below illustrates.
Starting the results

00:21:40.109 starting up....
00:21:40.140 doubleCeil: 19444599
00:21:40.140 integerCeil: 19444599
00:21:40.140 warming up...
00:21:44.375 warmup doubleCeil: 194445990000
00:21:44.625 warmup integerCeil: 194445990000
00:22:27.437 exec doubleCeil: 1944459900000, elapsed: 42.806s
00:22:29.796 exec integerCeil: 1944459900000, elapsed: 2.363s

The benchmark is in Java since I know well how Hotspot optimizes and make sure it's a fair result. With such results, no statistics, noise or anything can tint it.

Integer alike ceil is insanely much faster.

The code

package t1;

import java.math.BigDecimal;

import java.util.Random;

public class Div {
    static int[] vals;

    static long doubleCeil(){
        int[] v= vals;
        long sum = 0;
        for (int i=0;i<v.length;i++){
            int value = v[i];
            sum+=Math.ceil(value/10d);
        }
        return sum;
    }

    static long integerCeil(){      
        int[] v= vals;
        long sum = 0;
        for (int i=0;i<v.length;i++){
            int value = v[i];
            sum+=(value+9)/10;
        }
        return sum;     
    }

    public static void main(String[] args) {
        vals = new  int[7000];
        Random r= new Random(77);
        for (int i = 0; i < vals.length; i++) {
            vals[i] = r.nextInt(55555);
        }
        log("starting up....");

        log("doubleCeil: %d", doubleCeil());
        log("integerCeil: %d", integerCeil());
        log("warming up...");       

        final int warmupCount = (int) 1e4;
        log("warmup doubleCeil: %d", execDoubleCeil(warmupCount));
        log("warmup integerCeil: %d", execIntegerCeil(warmupCount));

        final int execCount = (int) 1e5;

        {       
        long time = System.nanoTime();
        long s = execDoubleCeil(execCount);
        long elapsed = System.nanoTime() - time;
        log("exec doubleCeil: %d, elapsed: %.3fs",  s, BigDecimal.valueOf(elapsed, 9));
        }

        {
        long time = System.nanoTime();
        long s = execIntegerCeil(execCount);
        long elapsed = System.nanoTime() - time;
        log("exec integerCeil: %d, elapsed: %.3fs",  s, BigDecimal.valueOf(elapsed, 9));            
        }
    }

    static long execDoubleCeil(int count){
        long sum = 0;
        for(int i=0;i<count;i++){
            sum+=doubleCeil();
        }
        return sum;
    }


    static long execIntegerCeil(int count){
        long sum = 0;
        for(int i=0;i<count;i++){
            sum+=integerCeil();
        }
        return sum;
    }

    static void log(String msg, Object... params){
        String s = params.length>0?String.format(msg, params):msg;
        System.out.printf("%tH:%<tM:%<tS.%<tL %s%n", new Long(System.currentTimeMillis()), s);
    }   
}
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1  
Great answer. Assertions are one thing, proof is something else entirely. –  par Feb 4 '11 at 4:01
    
good point, proof is something else –  JDandChips Jun 14 '13 at 8:31

To round up to the next whole integer but not round up if you are already at an integer, you just add the number you are dividing by minus one prior to the division.

In this case you are dividing by 10, 10-1 = 9, so you do:

( list.Count() + 9 ) / 10.

EDIT per Julian's comment:

OP is asking how to perform integer division such that the result (i.e. the quotient) is an integer that is always rounding up to the next (whole) integer whenever there is a fractional remainder.

In a more general sense, this thread is about integer division as it pertains to the pigeonhole principle. Put another way, what OP is really asking is:

"I have x items. If y items will fit in in one hole, how many holes do I need to make sure I have enough holes to store all items?"

In your comment, you give the example (113 + 4) / 5 = 23.4. Presumably then you are saying the following:

I have 113 objects. If I can make holes that each fit 5 objects, how many holes do I need?

To answer this in the context of integer division, you calculate (113+(5-1))/5. Which simplifies to your equation, (113+4)/5, which simplifies to 117/5 and has the answer 23.4, which after integer division is truncated to 23.

23 holes * 5 objects per hole means we have enough holes to hold 115 objects, clearly enough (and no more than necessary) to contain your original amount of 113.

If we had started with 110, (110+4)/5 = 114/5 = 22.8 = 22. 5 * 22 == 110.

So to round the quotient to the next whole integer, you add (divisor-1) to the dividend, then perform integer division.

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Either this is wrong, or the following statement is false: 113 + 4 / 5 = 23,4 –  Julian Nov 20 '14 at 10:17
1  
Your statement is false (it's actually 23, which is what we want). See my revised answer. –  par Nov 20 '14 at 14:01

I think the easiest way is to divide two integers and increase by one :

int r = list.Count() / 10;
r += (list.Count() % 10 == 0 ? 0 : 1);

No need of libraries or functions.

edited with the right code.

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that doesn't work correctly when count % 10 ==0. i.e. returns 2 for 10 –  bestsss Jan 31 '11 at 0:20
    
Not correct if list.Count() == 10 prior to the division. Then you get 2 when 1 is correct. –  par Jan 31 '11 at 0:20
    
Oops, missed that. You're right guys :) –  Radoslav Georgiev Jan 31 '11 at 0:22

Check by using mod - if there is a remainder, simply increment the value by one.

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The you have to do mod followed by a test followed by an increment (which is an add and a store). Too expensive. It's easier to do add then divide only (as expensive as mod). No test required. –  par Jan 31 '11 at 0:24

Xform to double (and back) for a simple ceil?

list.Count()/10 + (list.Count()%10 >0?1:0) - this bad, div + mod

edit 1st: on a 2n thought that's probably faster (depends on the optimization): div * mul (mul is faster than div and mod)

int c=list.Count()/10;
if (c*10<list.Count()) c++;

edit2 scarpe all. forgot the most natural (adding 9 ensures rounding up for integers)

(list.Count()+9)/10

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