# Project Euler Problem 1

I just started with solving Project Eulers problems. Even though this one is very simple. I want to take your opinion on the best solution.

If we list all the natural numbers below 10 that are multiples of 3 or 5, we get 3, 5, 6 and 9. The sum of these multiples is 23.

Find the sum of all the multiples of 3 or 5 below 1000.

This is how I coded it:

``````package com.problem.one.ten;
public class NaturalNumber {
static int sum=0;
public static void main(String args[])  {

for(int i=0; i<1000; i++) {
if((i%3 == 0) || (i%5 == 0)){
sum += i;
}
}
System.out.println(sum);
}
}
``````
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–  jball Nov 9 '10 at 19:00
Are you asking for a code review or a list of alternative ways to solve the problem? In the latter case you should just look at the forum-discussion attached to the problem, which includes plenty of alternative solutions. –  sepp2k Nov 9 '10 at 19:00
The best solution in what regard? Speed, size, comprehensibility...? –  Anonymous Coward Nov 9 '10 at 19:01
@sepp2k, Code review and alternative way. Like Matthew suggested one. –  t0mcat Nov 9 '10 at 19:03
@jball, Added the problem. –  t0mcat Nov 9 '10 at 19:04
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## 8 Answers

It looks fine, though I would put `sum` in main. It's not a big deal on such a simple program. But in general, you should declare variables in the narrowest possible scope.

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+1 for limiting variable scope. –  sepp2k Nov 9 '10 at 19:03
Thanks Matthew. I am looking for suggestion like yours. –  t0mcat Nov 9 '10 at 19:03
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A better solution is a simple application of inclusion-exclusion principle. The sum of all numbers we are interested in is (1) the sum of all numbers divisible by 3, plus (2) the sum of all numbers divisible by 5, minus (3) the sum of all numbers divisible by 15. Each of the 3 sums is a sum of an arithmetic progression, which is relatively easy to find. Basically, you don't need a loop.

The number of non-negative integers divisible by n below N is exactly [(N - 1) / n] + 1. The maximal such number is n * ([(N - 1) / n], therefore by the arithmetic progression sum formula, their sum is [(N - 1) / n] * ([(N - 1) / n] + 1) * n / 2.

For our case, we have got:

1. N = 1000, n = 3, [(N - 1) / n] = 333, sum = 333*334*3/2.
2. N = 1000, n = 5, [(N - 1) / n] = 199, sum = 199*200*5/2.
3. N = 1000, n = 15, [(N - 1) / n] = 66, sum = 66*67*15/2.

The final result is 233168.

Perhaps an even better solution exists.

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Thanks Vlad.... –  t0mcat Nov 9 '10 at 19:20
@Jay: I'm including 0 as well, for simplicity. It doesn't actually change the sum. That's why I write "non-negative numbers" and not just "positive" –  Vlad Nov 9 '10 at 19:55
@starblue: there is no "better" or "worse". Pragmatically speaking, any solutions which produces correct result in finite time is acceptable. There is an aesthetic value in the designing not a more efficient and sophisticated solution. There is a pure aesthetic value in designing the fastest possible algorithm. The following code: `if (1 % 3 == 0) || 1 % 5 == 0) count++; if (2 % 3 == 0) || 2 % 5 == 0) count++; ... if (999 % 3 == 0) || 999 % 5 == 0) count++;` is correct, too, and is even simpler. :-P –  Vlad Nov 10 '10 at 12:35
@Vlad: "any solutions which produces correct result in finite time is acceptable". I have to disagree. A program that requires 1,000 years to run is surely inferior to one that runs in 1 second, especially if I want to use the results in my lifetime. A program to determine the proper trajectory of an anti-missile defense is useless if it does not come up with an answer before the incoming missile hits. –  Jay Nov 10 '10 at 14:34
@starblue: ease of understanding depends a lot of the reader's algorithmical and mathematical etc. background. In any case, the quality criteria should be defined in advance, and they can be different depending on the practical application. For particularly our case, I personally would see 1000 as just an arbitrary number, therefore I tried to make a solution which would work efficiently for a broader range of input numbers. Other people's understanding of what is actually needed may of course be different. –  Vlad Nov 10 '10 at 21:39
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Your solution is the logically simplest and thus easiest to verify. Analytical solutions like Vlad's and Luke's are most efficient.

But for what it's worth, my first thought when I saw the problem was:

``````public int doit()
{
int sum=0;
for (int n=0;n<1000;n+=3)
{
sum+=n;
}
for (int n=0;n<1000;n+=5)
{
if (n%3!=0) // Don't pick up the 3's twice
sum+=n;
}
return sum;
}
``````

This would be more efficient than your solution as it would skip over numbers we know we're not interested in. And it's still intuitively pretty obvious how it works.

A no-loop solution is better, but I post this just because I have a meeting in 5 minutes and I was already here.

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Typo: `n<5000`? –  Ishtar Nov 9 '10 at 20:29
Thanks Jay..... –  t0mcat Nov 9 '10 at 21:57
@Ishtar: Oops, typo. Fixed. Thanks. –  Jay Nov 10 '10 at 14:26
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While I'm sure there is an O(1) solution to this problem, figuring it out would not be worth the effort considering you're only asked to provide the answer for 1000.

I agree with Matthew that sum should be a local variable, but otherwise, your code looks fine to me as well.

solution without code (just for fun):

Using the fact that `sum(1+2+3+...+n)` = `n(n+1)/2`, we can derive that the sum of multiples of x below 1000 is `floor(1000/x)*(floor(1000/x)+1)/2*x`.

The answer we need is the sum of multiples of 3 below 1000, plus the sum of multiples of 5, minus the sum of multiples of 15 (which would otherwise be doublecounted).

There are 999/3 = 333 multiples of 3 below 1000, 999/5 = 199 multiples of 5 below 1000, and 999/15 = 66 multiples of 15 below 1000

So the sum of all multiples of 3 below 1000 = 333*334/2*3 = 166833, the sum of multiples of 5 below 1000 = 199*200/2*5 = 99500, and the sum of multiples of 15 below 1000 = 66*67/2*15 = 33165

Making the answer 166833 + 99500 - 33165 = 233168

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Loop versus no-loop solutions raise an interesting point: The no-loop solutions are faster, but harder to verify. In general I'd take the time to test and verify, but the slower, "more obvious" solution would be preferable if you only need to run the program once and the run-time would be less than the time it would take to verify the more complex program. Debatable in cases where accuracy is vital and verification is difficult. –  Jay Oct 31 '11 at 16:48
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Vlad's solution rules.
But here' another along the lines of what Jay posted, but with 1 loop

``````def ProjectEuler1(upper_limit):
num_3mult = (upper_limit-1)//3  # total multiples of 3, less than upper_limit
num_5mult = (upper_limit-1)//5  # total multiples of 5, less than upper_limit
sum_multiples = 0
for i in range(1,num_3mult+1):
sum_multiples += i*3
if i <= num_5mult and i%3!=0: # only add the multiples of 5 which are not multiple of 3 (to avoid adding duplicates)
sum_multiples += i*5
print('Sum of all multiples of 3 and 5 below 1000 = ', sum_multiples, end='\n')

ProjectEuler1(1000)
``````
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You can solve this in .NET with a single LINQ expression

``````Dim sum = (From num In Enumerable.Range(1, 999)
Where num Mod 3 = 0 OrElse num Mod 5 = 0
Select num).Sum()
``````
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LINQ is powerful. –  Faisal Jan 23 at 14:19
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well the obvious arithmetic series sumation is:

``````int s=0,n,N=1000;
n=(N-1)/ 3; s+= 3*n*(n+1);
n=(N-1)/ 5; s+= 5*n*(n+1);
n=(N-1)/15; s-=15*n*(n+1); s>>=1;
// can further optimize by precomputing N-1, n+1 to some temp vars
// also multiplication can be shift added instead
``````

I saw some suma fors here and why to heck are you people

• use division for suma ???
• use +1 increment for +3i and +5i multiplicants ???

try this instead:

``````int s=0,N=1000;
for (int i=0;i<N;i+=5) s+=i;
for (int i=0,j=0;i<N;i+=3,j++) if (j==5)  j=0; else s+=i;
``````

I know is trivial but hopefully helps someone to realize how to write things better.

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Week 5 of my first JAVA course... this is how I would solve it ;) it's a real piece de triomphe

``````import java.util.Scanner;
public class Counter {
public static void main(String args[]) {

System.out.println("Enter an integer, and COUNTER will find the sum of all the multiples of THREE and FIVE:");
int entry;
Scanner input = new Scanner(System.in);
entry = input.nextInt();

int three = 0;
int threeOut = 0;
int threeOpTot = (entry / 3);
int threeOp = 0;

while( threeOp < threeOpTot) {
three = three + 3 ;
threeOut = three + threeOut ;
threeOp += 1;
System.out.println(threeOp + " times 3 is " + three + ". ");
System.out.println("     " + threeOut + ", is the total sum of " + threeOp + "/" +
threeOpTot + " threes");
}

int five = 0;
int fiveOut = 0;
int fiveOpTot = (entry / 5);
int fiveOp = 1;

while( fiveOp < fiveOpTot) {
five = five + 5 ;
fiveOut = five + fiveOut ;
fiveOp += 1 ;
System.out.println(threeOp + " times 3 is " + three + ". ");
System.out.println("     " + threeOut + ", is the total sum of " +
threeOp + "/" + threeOpTot + " threes");
}

int fifteen = 0;
int fifteenOut = 0;
int fifteenOpTot = (entry / 15);
int fifteenOp = 0;

while( fifteenOp < fifteenOpTot) {
fifteen = fifteen + 15 ;
fifteenOut = fifteen + fifteenOut ;
fifteenOp += 1 ;

System.out.println(fifteenOp + " times fifteen is " + fifteen + ".");
System.out.println("     " + fifteenOut + ", is the total sum of " + fifteenOp +
"/" + fifteenOpTot + " fifteens");
}

System.out.println("The final values of threes' are " + (threeOut) );
System.out.println("The final values of five' are " + (fiveOut) );
System.out.println("The sum of the over-lapping 15 factors are " + (fifteenOut) );
System.out.println("Grand total: " + (fiveOut + threeOut - fifteenOut) );
}
}
``````
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