How to check for division by 7 for big number in C++?

I have to check, if given number is divisible by 7, which is usualy done just by doing something like `n % 7 == 0`, but the problem is, that given number can have up to 100000000, which doesn't fit even in `long long`.

Another constrain is, that I have only few kilobytes of memory available, so I can't use an array.

I'm expecting the number to be on stdin and output to be `1`/`0`.

This is an example

``````34123461273648125348912534981264376128345812354821354127346821354982135418235489162345891724592183459321864592158
0
``````

It should be possible to do using only about 7 integer variables and `cin.get()`. It should be also done using only standard libraries.

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Think about how you do division on paper. You look at the first digit or two, and write down the nearest multiple of seven, carry down the remainder, and so on. You can do that on any abritrary length number because you don't have to load the whole number into memory.

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wow, very nice, thanks – Jakub Arnold Oct 11 '09 at 14:14
+1: start with the concept that a number is just a list of digits and you perform division on each digit independently. – D.Shawley Oct 11 '09 at 14:15

you can use a known rule about division by 7 that says: group each 3 digits together starting from the right and start subtracting and adding them alternativly, the divisibility of the result by 7 is the same as the original number:

ex.:

``````testing 341234612736481253489125349812643761283458123548213541273468213
549821354182354891623458917245921834593218645921580

(580-921+645-218+593-834+921-245+917-458+623-891+354-182
+354-821+549-213+468-273+541-213+548-123+458-283+761-643
+812-349+125-489+253-481+736-612+234-341
= 1882 )
% 7 != 0 --> NOK!
``````

there are other alternatives to this rule, all easy to implement.

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This works because 1001 is divisible by 7. – starblue Oct 11 '09 at 18:36
First time I see this rule, any references available? – elcuco Oct 11 '09 at 18:49
@elcuco, it's a nice trick from modular mathematics, using the Chinese Remainder Theorem. It actually works on 11 and 13 too since 1001 = 7*11*13. – rlbond Oct 11 '09 at 19:07
– manji Oct 11 '09 at 19:23
@rlbond For 11 you don't need groups of three digits. Instead add/subtract every other digit. This works because 11 is divisible by 11. :-) – starblue Oct 11 '09 at 20:40

Most of the divisibility by seven rules work on a digit level, so you should have no problem applying them on your string.

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+1 for the link – sean e Oct 11 '09 at 15:58

You can compute the value of the number modulo 7.

That is, for each digit d and value n so far compute n = (10 * n + d) % 7.

This has the advantage of working independently of the divisor 7 or the base 10.

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I'd start by subtracting some big number which is divisible by 7.

Examples of numbers which are divisible by 7 include 700, 7000, 70000, 140000000, 42000000000, etc.

In the particular example you gave, try subtracting 280000000000(some number of zeros)0000.

Even easier to implement, repeatedly subtract the largest possible number like 70000000000(some number of zeros)0000.

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Because I recently did work dealing with breaking up numbers, I will hint that to get specific numbers - which is what you will need with some of the other answers - think about integer division and using the modulus to get digits out of it.

If you had a smaller number, say `123`, how would you get the `1`, the `2`, and the `3` out of it? Especially since you're working in base 10...

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You can compute the value of the number modulo 7.

That is, for each digit d and value n so far compute n = (10 * n + d) % 7.

This has the advantage of working independently of the divisor 7 or the base 10.

I solved this problem exactly the same way on one of programming contests. Here is the fragment of code you need:

``````int sum = 0;
while (true) {
char ch;
cin>>ch;
if (ch<'0' || ch>'9') break; // Reached the end of stdin
sum = sum*10; // The previous sum we had must be multiplied
sum += (int) ch;
sum -= (int) '0'; // Remove the code to get the value of the digit
sum %= 7;
}

if (sum==0) cout<<"1";
else cout<<"0";
``````

This code is working thanks to simple rules of modular arithmetics. It also works not just for 7, but for any divisor actually.

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N = abc

There is a simple algorithm to verify if a three-digit number is a multiple of 7:

Substitute a by x and add it to bc, being x the tens of a two-digit number multiple of 7 whose hundreds is a.

N = 154; x = 2; 2 + 54 = 56; 7|56 and 7|154

N = 931; x = 4; 4 + 31 = 35; 7|35 and 7|931

N = 665; x = 5; 5 + 65 = 70; 7|70 and 7|665

N = 341; x = 6; 6 + 41 = 47; 7ł47 and 7ł341

If N is formed by various periods the inverse additive of the result of one period must be added to the sum of the next period, this way:

N = 341.234

6 + 41 = 47; - 41 mod 7 ≡ 1; 1 + 4 + 34 = 39; 7ł39 and 7łN

N = 341.234.612.736.481

The result for 341.234 is 39. Continuing from this result we have:

-39 mod 7 ≡ 3; 3 + 5 + 6 + 1 + 2 + 1 = 18; - 18 mod 7 ≡ 3; 3 + 0 + 36 = 39; - 39 mod 7 ≡ 3; 3 + 1 + 81 = 85; 7ł85 and 7łN

This rule may be applied entirely through mental calculation and is very quick. It was derived from another rule that I created in 2.005. It works for numbers of any magnitude and for divisibility by 13.

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Here's a simple way to check for divisibility by 7:

Multiply each digit beginning on the right hand side of the given number by the corresponding digit in this pattern [1,3,2,6,4,5] (or [1,3,2,-1,-3,-2]). Repeat the pattern as necessary. If the sum of the products is divisible by 7, then so is the original number.

Example: 2016 (6*1+1*3+0*2+2*6=21) is divisible by 7 since 21 is divisible by 7.

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