# Comparing anagrams using prime numbers

There is the problem of trying to see if two unique strings are anagrams of each other. The first solution that I had considered would be to sort both strings and see if they were equal to each other.

I have been considering another solution and I would like to discuss if the same would be feasible.

The idea would be to assign a numerical value to each character and sum it up such that a unique set of characters would produce a unique value. As we are testing for anagrams, we do not mind if the checksum of "asdf" and "adsf" are the same -- in fact, we require it to be that way. However the checksum of strings "aa" and "b" shouldn't be equal.

I was considering assigning the first 52 prime numbers to alphabets "a" through "z" and then "A" through "Z"(assume we only have alphabets).

The above scheme would break if the sum of any two or more primes in the set of 52 primes could result in another prime existing in the set.

My doubts are :-

1. Is there any numbering scheme that would satify my requirements?
2. I'm unsure about the math involved ; is it possible to prove/is there any proof that suggests that the sum of two or more primes in the set of the first 52 primes has at least one value that exists in the same set?

Thanks.

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right... factorisation is unique! –  thedayofcondor Nov 4 '12 at 3:39
Be careful, your number can get very large very quickly... the 26th prime is around 100, so zzzzzzzzzz would be 100^10 –  thedayofcondor Nov 4 '12 at 3:46
Great answer and perfectly correct. What you can do to stop the worry of numbers getting to large is use a buffer on each string. Take numbers from the left side of one string into one buffer and numbers from the right side of the other string into the other buffer. in th Enter `n` numbers into the buffer such that `101^n` (where `^` denotes exponentation) is less than the maximum number representable by the integer type you are using. –  Zéychin Nov 4 '12 at 6:13

A slightly more clunky way to do it would require the length of your longest string max_len (or the largest number of any specific character for slightly better performance). Given that, your hash could look like

``````number_of_a*max_len^51 + number_of_b*max_len^50 + ... + number_of_Z*max_len^0
``````

If you preferred to use primes, multiplication will work better, as previously mentioned.

Of course, you could achieve the same effect by having an array of 52 values instead.

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Don't use prime numbers - prime numbers properties are related to division, not sums. However, the idea is good, you could use bit sets but you would hit another problem - duplicate letters (same problem with primes, 1+1+1=3). So, you can use an integer sets, an array 1...26 of frequency of letters.

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You are trying to compare two sorted strings for equality by comparing two n-bit numbers for equality. As soon as your strings are long enough that there are more than 2^n possible sorted strings you will definitely have two different sorted strings that produce the same n-bit number. It is likely, by the http://en.wikipedia.org/wiki/Birthday_problem, that you will hit problems before this, unless (as with multiplication of primes) there is some theorem saying that you cannot have two different strings from the same number.

In some cases you might save time by using this idea as a quick first check for equality, so that you only need to compare sorted strings if their numbers match.

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Here is an implementation in c# using the prime numbers way:

``````    using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace Anag
{
class Program
{
private static int[] primes100 = new int[]
{
3, 7, 11, 17, 23, 29, 37,
47, 59, 71, 89, 107, 131,
163, 197, 239, 293, 353,
431, 521, 631, 761, 919,
1103, 1327, 1597, 1931,
2333, 2801, 3371, 4049,
4861, 5839, 7013, 8419,
10103, 12143, 14591, 17519,
21023, 25229, 30293, 36353,
43627, 52361, 62851, 75431,
90523, 108631, 130363,
156437, 187751, 225307,
270371, 324449, 389357,
467237, 560689, 672827,
807403, 968897, 1162687,
1395263, 1674319, 2009191,
2411033, 2893249, 3471899,
4166287, 4999559, 5999471,
7199369
};

private static int[] getNPrimes(int _n)
{
int[] _primes;

if (_n <= 100)
_primes = primes100.Take(_n).ToArray();
else
{
_primes = new int[_n];

int number = 0;
int i = 2;

while (number < _n)
{

var isPrime = true;
for (int j = 2; j <= Math.Sqrt(i); j++)
{
if (i % j == 0 && i != 2)
isPrime = false;
}
if (isPrime)
{
_primes[number] = i;
number++;
}
i++;
}

}

return _primes;
}

private static bool anaStrStr(string needle, string haystack)
{
bool _output = false;

var needleDistinct = needle.ToCharArray().Distinct();

int[] arrayOfPrimes = getNPrimes(needleDistinct.Count());

Dictionary<char, int> primeByChar = new Dictionary<char, int>();
int i = 0;
int needlePrimeSignature = 1;

foreach (var c in needleDistinct)
{
if (!primeByChar.ContainsKey(c))
{

i++;
}
}

foreach (var c in needle)
{
needlePrimeSignature *= primeByChar[c];
}

for (int j = 0; j <= (haystack.Length - needle.Length); j++)
{
var result = 1;
for (int k = j; k < needle.Length + j; k++)
{
var letter = haystack[k];
result *= primeByChar.ContainsKey(letter) ? primeByChar[haystack[k]] : 0;
}

_output = (result == needlePrimeSignature);
if (_output)
break;
}

return _output;
}

static void Main(string[] args)
{
Console.WriteLine("Enter needle");