# finding if two words are anagrams of each other

I am looking for a method to find if two strings are anagrams of one another.

``````Ex: string1 - abcde
string2 - abced
Ans = true
Ex: string1 - abcde
string2 - abcfed
Ans = false
``````

the solution i came up with so for is to sort both the strings and compare each character from both strings till the end of either strings.It would be O(logn).I am looking for some other efficient method which doesn't change the 2 strings being compared

Count the frequency of each character in the two strings. Check if the two histograms match. O(n) time, O(1) space (assuming ASCII) (Of course it is still O(1) space for Unicode but the table will become very large).

• +1 simple yet effective. Space can easily be halved by incrementing for one and decrementing for the other string and checking for 0. For unicode the Hashmap approach seems appropriate.
– Eiko
Commented Nov 21, 2010 at 7:52
• Having an initial string length check would help eliminate a lot of candidate strings. Commented Dec 7, 2012 at 23:03
• as @Eiko mentioned I felt its right, but remember even If you think hashmap initial get created with some default value like 16 in JAVA as soon as table get increased it does rehashing which is overhead. Now for avoiding this you can create hashmap with initial capacity which is like creating array of that capacity, since underneath hashmap is array. Even setting initial capacity I would feel direct indexing based on character is better than calculating hash while putting char everytime in hashmap ....Let me know if I am wrong. Commented May 27, 2013 at 16:22
• Hi can you explain a bit more about "counting the frequency" and "histogram" in terms of code? Commented Mar 25, 2014 at 19:56
• @ToussaintLouverture Because there are only 95 ASCII characters. Commented Apr 13, 2017 at 16:48

Get table of prime numbers, enough to map each prime to every character. So start from 1, going through line, multiply the number by the prime representing current character. Number you'll get is only depend on characters in string but not on their order, and every unique set of characters correspond to unique number, as any number may be factored in only one way. So you can just compare two numbers to say if a strings are anagrams of each other.

Unfortunately you have to use multiple precision (arbitrary-precision) integer arithmetic to do this, or you will get overflow or rounding exceptions when using this method.
For this you may use libraries like `BigInteger`, `GMP`, `MPIR` or `IntX`.

Pseudocode:

``````prime[] = {2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97, 101}

primehash(string)
Y = 1;
foreach character in string
Y = Y * prime[character-'a']

return Y

isanagram(str1, str2)
return primehash(str1)==primehash(str2)
``````
• I don't think this will work. For instance 2 + 5 = 7 so if a = 2, b = 3, c = 5 and d = 7 if one string had a and c and the other had d then there would be a collision in your "sum". Perhaps this would hold true if you first checked that the length of each string was identical? Commented May 16, 2013 at 18:13
• Primes multiplied, not added. primehash("ac") = 2*5 = 10, primehash("d") = 7, so they're not equal. There will be NO collisions because of one-to-one relation between number and its prime factors. Commented Jun 1, 2013 at 12:47
• Lovely - Fundamental Theorem of Arithmetic! en.wikipedia.org/wiki/Fundamental_theorem_of_arithmetic Commented Jul 29, 2015 at 12:48
• The only issue here is that you might endup with a huge integer. Maybe bigger than the max int of the system. E.g. primehash("zzzzzzzzzz") is 101^10 that is greater than 2^64! Commented Nov 3, 2015 at 19:33
• This solution really provides the time O(n) and there is no need to create an additional datastructure, as the most voted solution requires. Commented Dec 24, 2015 at 15:42
1. Create a Hashmap where key - letter and value - frequencey of letter,
2. for first string populate the hashmap (O(n))
3. for second string decrement count and remove element from hashmap O(n)
4. if hashmap is empty, the string is anagram otherwise not.
• nice idea to increment in the first run and decrement in the second. However, a hashmap is not needed here as the keys are known in advance and can be used as array indices. This will result in a faster implementation. Commented Nov 21, 2010 at 7:50
• @Philipp That might be a very large array if we are dealing with a unicode string. Commented Nov 21, 2010 at 7:58
• Isn't this rather wasteful if you're generally comparing small strings? If the strings are on average small (like most words are) then simply turning the words into a character arrays, sorting the arrays, then comparing them for equality will likely be faster than the overhead of creating a hashmap, doing the increments & decrements & then examining the hashmap for being empty. Commented May 24, 2013 at 5:01
• @AdamParkin it's only "wasteful" memory-wise. Nowadays, memory is very cheap. The most important part (to most people) is runtime. Your way would take `O(n log n)` time due to sorting, the provided answer takes just `O(n)`. Besides creating two character arrays as you say will also take `O(n)` space.
– ugo
Commented Jul 13, 2014 at 17:07
• Yes, in terms of `O()` notation, I will grant you it's more efficient. However, that's discarding the constant factors, and oftentimes with algorithms that have better big-O runtimes have poor performance when n is small. All I was alluding to is that in this case n is probably small, so the overhead of allocating expensive collections like `HashMap`'s might be more expensive than sorting a small char array. Commented Jul 14, 2014 at 17:52

The steps are:

1. check the length of of both the words/strings if they are equal then only proceed to check for anagram else do nothing
2. sort both the words/strings and then compare

JAVA CODE TO THE SAME:

``````/*
* To change this template, choose Tools | Templates
* and open the template in the editor.
*/
package anagram;

import java.io.IOException;
import java.util.Arrays;

/**
*
* @author Sunshine
*/
public class Anagram {

/**
* @param args the command line arguments
*/
public static void main(String[] args) throws IOException {
// TODO code application logic here
System.out.println("Enter the first string");
System.out.println("Enter the Second string");
char c1[] = null;
char c2[] = null;
if (s1.length() == s2.length()) {

c1 = s1.toCharArray();
c2 = s2.toCharArray();

Arrays.sort(c1);
Arrays.sort(c2);

if (Arrays.equals(c1, c2)) {
System.out.println("Both strings are equal and hence they have anagram");
} else {
System.out.println("Sorry No anagram in the strings entred");
}

} else {
System.out.println("Sorry the string do not have anagram");
}
}
}
``````

C#

``````public static bool AreAnagrams(string s1, string s2)
{
if (s1 == null) throw new ArgumentNullException("s1");
if (s2 == null) throw new ArgumentNullException("s2");

var chars = new Dictionary<char, int>();
foreach (char c in s1)
{
if (!chars.ContainsKey(c))
chars[c] = 0;
chars[c]++;
}
foreach (char c in s2)
{
if (!chars.ContainsKey(c))
return false;
chars[c]--;
}

return chars.Values.All(i => i == 0);
}
``````

Some tests:

``````[TestMethod]
public void TestAnagrams()
{
Assert.IsTrue(StringUtil.AreAnagrams("anagramm", "nagaramm"));
Assert.IsTrue(StringUtil.AreAnagrams("anzagramm", "nagarzamm"));
Assert.IsTrue(StringUtil.AreAnagrams("anz121agramm", "nag12arz1amm"));
Assert.IsFalse(StringUtil.AreAnagrams("anagram", "nagaramm"));
Assert.IsFalse(StringUtil.AreAnagrams("nzagramm", "nagarzamm"));
Assert.IsFalse(StringUtil.AreAnagrams("anzagramm", "nag12arz1amm"));
}
``````

Code to find whether two words are anagrams:

Logic explained already in few answers and few asking for the code. This solution produce the result in O(n) time.

This approach counts the no of occurrences of each character and store it in the respective ASCII location for each string. And then compare the two array counts. If it is not equal the given strings are not anagrams.

``````public boolean isAnagram(String str1, String str2)
{
//To get the no of occurrences of each character and store it in their ASCII location
int[] strCountArr1=getASCIICountArr(str1);
int[] strCountArr2=getASCIICountArr(str2);

//To Test whether the two arrays have the same count of characters. Array size 256 since ASCII 256 unique values
for(int i=0;i<256;i++)
{
if(strCountArr1[i]!=strCountArr2[i])
return false;
}
return true;
}

public int[] getASCIICountArr(String str)
{
char c;
//Array size 256 for ASCII
int[] strCountArr=new int[256];
for(int i=0;i<str.length();i++)
{
c=str.charAt(i);
c=Character.toUpperCase(c);// If both the cases are considered to be the same
strCountArr[(int)c]++; //To increment the count in the character's ASCII location
}
return strCountArr;
}
``````
• OH!!! This is what "histogram" means in this particular case. Thank you for that. But one question tho, this solution is O(N) space complexity how come the top comment says it's O(1)??? Commented Apr 30, 2014 at 23:18
• @S.H.- Array size is 256 for all strings. If you give one million characters in a string, still it will store in a array of size 256 which is a constant. So the complexity is O(1) space.
– Dany
Commented May 1, 2014 at 0:25
• yes you are correct, O(256) is asymptotically O(1). Thank you! Commented May 2, 2014 at 1:37

Using an ASCII hash-map that allows O(1) look-up for each char.

The java example listed above is converting to lower-case that seems incomplete. I have an example in C that simply initializes a hash-map array for ASCII values to '-1'

If string2 is different in length than string 1, no anagrams

Else, we update the appropriate hash-map values to 0 for each char in string1 and string2

Then for each char in string1, we update the count in hash-map. Similarily, we decrement the value of the count for each char in string2.

The result should have values set to 0 for each char if they are anagrams. if not, some positive value set by string1 remains

``````#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#define ARRAYMAX 128

#define True        1
#define False       0

int isAnagram(const char *string1,
const char *string2) {

int str1len = strlen(string1);
int str2len = strlen(string2);

if (str1len != str2len) /* Simple string length test */
return False;

int * ascii_hashtbl = (int * ) malloc((sizeof(int) * ARRAYMAX));
if (ascii_hashtbl == NULL) {
fprintf(stderr, "Memory allocation failed\n");
return -1;
}
memset((void *)ascii_hashtbl, -1, sizeof(int) * ARRAYMAX);
int index = 0;
while (index < str1len) { /* Populate hash_table for each ASCII value
in string1*/
ascii_hashtbl[(int)string1[index]] = 0;
ascii_hashtbl[(int)string2[index]] = 0;
index++;
}
index = index - 1;
while (index >= 0) {
ascii_hashtbl[(int)string1[index]]++; /* Increment something */
ascii_hashtbl[(int)string2[index]]--; /* Decrement something */
index--;
}
/* Use hash_table to compare string2 */
index = 0;
while (index < str1len) {
if (ascii_hashtbl[(int)string1[index]] != 0) {
/* some char is missing in string2 from string1 */
free(ascii_hashtbl);
ascii_hashtbl = NULL;
return False;
}
index++;
}
free(ascii_hashtbl);
ascii_hashtbl = NULL;
return True;
}

int main () {
char array1[ARRAYMAX], array2[ARRAYMAX];
int flag;

printf("Enter the string\n");
fgets(array1, ARRAYMAX, stdin);
printf("Enter another string\n");
fgets(array2, ARRAYMAX, stdin);

array1[strcspn(array1, "\r\n")] = 0;
array2[strcspn(array2, "\r\n")] = 0;
flag = isAnagram(array1, array2);
if (flag == 1)
printf("%s and %s are anagrams.\n", array1, array2);
else if (flag == 0)
printf("%s and %s are not anagrams.\n", array1, array2);

return 0;
}
``````

let's take a question: Given two strings s and t, write a function to determine if t is an anagram of s.

For example, s = "anagram", t = "nagaram", return true. s = "rat", t = "car", return false.

Method 1(Using HashMap ):

``````public class Method1 {

public static void main(String[] args) {
String a = "protijayi";
String b = "jayiproti";
System.out.println(isAnagram(a, b ));// output => true

}

private static boolean isAnagram(String a, String b) {
Map<Character ,Integer> map = new HashMap<>();
for( char c : a.toCharArray()) {
map.put(c,    map.getOrDefault(c, 0 ) + 1 );
}
for(char c : b.toCharArray()) {
int count = map.getOrDefault(c, 0);
if(count  == 0 ) {return false ; }
else {map.put(c, count - 1 ) ; }
}

return true;
}

}
``````

Method 2 :

``````public class Method2 {
public static void main(String[] args) {
String a = "protijayi";
String b = "jayiproti";

System.out.println(isAnagram(a, b));// output=> true
}

private static boolean isAnagram(String a, String b) {

int[] alphabet = new int[26];
for(int i = 0 ; i < a.length() ;i++) {
alphabet[a.charAt(i) - 'a']++ ;
}
for (int i = 0; i < b.length(); i++) {
alphabet[b.charAt(i) - 'a']-- ;
}

for(  int w :  alphabet ) {
if(w != 0 ) {return false;}
}
return true;

}
}
``````

Method 3 :

``````public class Method3 {
public static void main(String[] args) {
String a = "protijayi";
String b = "jayiproti";

System.out.println(isAnagram(a, b ));// output => true
}

private static boolean isAnagram(String a, String b) {
char[] ca = a.toCharArray() ;
char[] cb = b.toCharArray();
Arrays.sort(   ca     );

Arrays.sort(   cb        );
return Arrays.equals(ca , cb );
}
}
``````

Method 4 :

``````public class AnagramsOrNot {
public static void main(String[] args) {
String a = "Protijayi";
String b = "jayiProti";
isAnagram(a, b);
}

private static void isAnagram(String a, String b) {
Map<Integer, Integer> map = new LinkedHashMap<>();

a.codePoints().forEach(code -> map.put(code, map.getOrDefault(code, 0) + 1));
System.out.println(map);
b.codePoints().forEach(code -> map.put(code, map.getOrDefault(code, 0) - 1));
System.out.println(map);
if (map.values().contains(0)) {
System.out.println("Anagrams");
} else {
System.out.println("Not Anagrams");
}
}
}
``````

In Python:

``````def areAnagram(a, b):
if len(a) != len(b): return False
count1 = [0] * 256
count2 = [0] * 256
for i in a:count1[ord(i)] += 1
for i in b:count2[ord(i)] += 1

for i in range(256):
if(count1[i] != count2[i]):return False

return True

str1 = "Giniiii"
str2 = "Protijayi"
print(areAnagram(str1, str2))
``````

Let's take another famous Interview Question: Group the Anagrams from a given String:

``````public class GroupAnagrams {
public static void main(String[] args) {
String a = "Gini Gina Protijayi iGin aGin jayiProti Soudipta";
Map<String, List<String>> map = Arrays.stream(a.split(" ")).collect(Collectors.groupingBy(GroupAnagrams::sortedString));
System.out.println("MAP => " + map);
map.forEach((k,v) -> System.out.println(k +" and the anagrams are =>" + v ));
/*
Look at the Map output:
MAP => {Giin=[Gini, iGin], Paiijorty=[Protijayi, jayiProti], Sadioptu=[Soudipta], Gain=[Gina, aGin]}
As we can see, there are multiple Lists. Hence, we have to use a flatMap(List::stream)
Now, Look at the output:
Paiijorty and the anagrams are =>[Protijayi, jayiProti]

Now, look at this output:
Sadioptu and the anagrams are =>[Soudipta]
List contains only word. No anagrams.
That means we have to work with map.values(). List contains all the anagrams.

*/
String stringFromMapHavingListofLists = map.values().stream().flatMap(List::stream).collect(Collectors.joining(" "));
System.out.println(stringFromMapHavingListofLists);
}

public static String sortedString(String a) {
String sortedString = a.chars().sorted()
.collect(StringBuilder::new, StringBuilder::appendCodePoint, StringBuilder::append).toString();

return sortedString;

}

/*
* The output : Gini iGin Protijayi jayiProti Soudipta Gina aGin
* All the anagrams are side by side.
*/
}
``````

Now to Group Anagrams in Python is again easy.We have to : Sort the lists. Then, Create a dictionary. Now dictionary will tell us where are those anagrams are( Indices of Dictionary). Then values of the dictionary is the actual indices of the anagrams.

``````def groupAnagrams(words):

# sort each word in the list
A = [''.join(sorted(word)) for word in words]
dict = {}
for indexofsamewords, names in enumerate(A):
dict.setdefault(names, []).append(indexofsamewords)
print(dict)
#{'AOOPR': [0, 2, 5, 11, 13], 'ABTU': [1, 3, 4], 'Sorry': [6], 'adnopr': [7], 'Sadioptu': [8, 16], ' KPaaehiklry': [9], 'Taeggllnouy': [10], 'Leov': [12], 'Paiijorty': [14, 18], 'Paaaikpr': [15], 'Saaaabhmryz': [17], ' CNaachlortttu': [19], 'Saaaaborvz': [20]}

for index in dict.values():
print([words[i] for i in index])

if __name__ == '__main__':

# list of words
words = ["ROOPA","TABU","OOPAR","BUTA","BUAT" , "PAROO","Soudipta",
"Kheyali Park", "Tollygaunge", "AROOP","Love","AOORP", "Protijayi","Paikpara","dipSouta","Shyambazaar",
"jayiProti", "North Calcutta", "Sovabazaar"]

groupAnagrams(words)

``````

The Output :

``````['ROOPA', 'OOPAR', 'PAROO', 'AROOP', 'AOORP']
['TABU', 'BUTA', 'BUAT']
['Soudipta', 'dipSouta']
['Kheyali Park']
['Tollygaunge']
['Love']
['Protijayi', 'jayiProti']
['Paikpara']
['Shyambazaar']
['North Calcutta']
['Sovabazaar']
``````

Another Important Anagram Question : Find the Anagram occuring Max. number of times. In the Example, ROOPA is the word which has occured maximum number of times. Hence, ['ROOPA' 'OOPAR' 'PAROO' 'AROOP' 'AOORP'] will be the final output.

``````from sqlite3 import collections
from statistics import mode, mean

import numpy as np

# list of words
words = ["ROOPA","TABU","OOPAR","BUTA","BUAT" , "PAROO","Soudipta",
"Kheyali Park", "Tollygaunge", "AROOP","Love","AOORP",
"Protijayi","Paikpara","dipSouta","Shyambazaar",
"jayiProti", "North Calcutta", "Sovabazaar"]

print(".....Method 1....... ")

sortedwords = [''.join(sorted(word)) for word in words]
print(sortedwords)
print("...........")
LongestAnagram = np.array(words)[np.array(sortedwords) == mode(sortedwords)]
# Longest anagram
print("Longest anagram by Method 1:")
print(LongestAnagram)

print(".....................................................")

print(".....Method 2....... ")

A = [''.join(sorted(word)) for word in words]

dict = {}

for indexofsamewords,samewords in  enumerate(A):
dict.setdefault(samewords,[]).append(samewords)
#print(dict)
#{'AOOPR': ['AOOPR', 'AOOPR', 'AOOPR', 'AOOPR', 'AOOPR'], 'ABTU': ['ABTU', 'ABTU', 'ABTU'], 'Sadioptu': ['Sadioptu', 'Sadioptu'], ' KPaaehiklry': [' KPaaehiklry'], 'Taeggllnouy': ['Taeggllnouy'], 'Leov': ['Leov'], 'Paiijorty': ['Paiijorty', 'Paiijorty'], 'Paaaikpr': ['Paaaikpr'], 'Saaaabhmryz': ['Saaaabhmryz'], ' CNaachlortttu': [' CNaachlortttu'], 'Saaaaborvz': ['Saaaaborvz']}

aa =  max(dict.items() , key = lambda x : len(x[1]))
print("aa => " , aa)
word, anagrams = aa
print("Longest anagram by Method 2:")
print(" ".join(anagrams))
``````

The Output :

``````.....Method 1.......
['AOOPR', 'ABTU', 'AOOPR', 'ABTU', 'ABTU', 'AOOPR', 'Sadioptu', ' KPaaehiklry', 'Taeggllnouy', 'AOOPR', 'Leov', 'AOOPR', 'Paiijorty', 'Paaaikpr', 'Sadioptu', 'Saaaabhmryz', 'Paiijorty', ' CNaachlortttu', 'Saaaaborvz']
...........
Longest anagram by Method 1:
['ROOPA' 'OOPAR' 'PAROO' 'AROOP' 'AOORP']
.....................................................
.....Method 2.......
aa =>  ('AOOPR', ['AOOPR', 'AOOPR', 'AOOPR', 'AOOPR', 'AOOPR'])
Longest anagram by Method 2:
AOOPR AOOPR AOOPR AOOPR AOOPR

``````

Well you can probably improve the best case and average case substantially just by checking the length first, then a quick checksum on the digits (not something complex, as that will probably be worse order than the sort, just a summation of ordinal values), then sort, then compare.

If the strings are very short the checksum expense will be not greatly dissimilar to the sort in many languages.

```a = "lai d"
b = "di al"
sorteda = []
sortedb = []
for i in a:
if i != " ":
sorteda.append(i)
if c == len(b):
for x in b:
c -= 1
if x != " ":
sortedb.append(x)
sorteda.sort(key = str.lower)
sortedb.sort(key = str.lower)

print sortedb
print sorteda

print sortedb == sorteda
```
• Your choices in strings might earn you enough offensive flags that your answer is removed. Please consider revising. I do, however understand why they are convenient for your example.
– user50049
Commented Apr 30, 2011 at 6:01
• ok I changed my anagram just for the sake of it deeming to be offensive!
– AAF
Commented Apr 30, 2011 at 9:40

How about Xor'ing both the strings??? This will definitely be of O(n)

``````char* arr1="ab cde";
int n1=strlen(arr1);
char* arr2="edcb a";
int n2=strlen(arr2);
// to check for anagram;
int c=0;
int i=0, j=0;
if(n1!=n2)
printf("\nNot anagram");
else {
while(i<n1 || j<n2)
{
c^= ((int)arr1[i] ^ (int)arr2[j]);
i++;
j++;
}
}

if(c==0) {
printf("\nAnagram");
}
else printf("\nNot anagram");
``````

}

• I think this approach will not work always. Consider an example below: str1="aa" and str2="bb" then a^b^a^b (xor of strings) will be zero but these are not anagrams !! Commented Jan 12, 2013 at 18:01
• this is not a solution Commented Jul 16, 2013 at 9:41
``````static bool IsAnagram(string s1, string s2)
{

if (s1.Length != s2.Length)
return false;
else
{
int sum1 = 0;
for (int i = 0; i < s1.Length; i++)
sum1 += (int)s1[i]-(int)s2[i];
if (sum1 == 0)
return true;
else
return false;
}
}
``````
• Best Solution to check whether 2 strings are Anagram or not. :) Commented Mar 16, 2014 at 17:44
• Lets `str1 = "az"` and `str2 = "by"`. This approach will then fail. Commented Oct 4, 2014 at 7:11
• Downvoted because algorithm doesn't work for all inputs. Please make sure you properly check all solutions before posting as answers. Commented Feb 11, 2015 at 14:10
• @user2605539 Old post... but this could be best solution if we make something like s1 = s1.toUpperCase() and same for s2 this way we make sure it work in all cases. Commented May 27, 2016 at 18:45

For known (and small) sets of valid letters (e.g. ASCII) use a table with counts associated with each valid letter. First string increments counts, second string decrements counts. Finally iterate through the table to see if all counts are zero (strings are anagrams) or there are non-zero values (strings are not anagrams). Make sure to convert all characters to uppercase (or lowercase, all the same) and to ignore white space.

For a large set of valid letters, such as Unicode, do not use table but rather use a hash table. It has O(1) time to add, query and remove and O(n) space. Letters from first string increment count, letters from second string decrement count. Count that becomes zero is removed form the hash table. Strings are anagrams if at the end hash table is empty. Alternatively, search terminates with negative result as soon as any count becomes negative.

Here is the detailed explanation and implementation in C#: Testing If Two Strings are Anagrams

If strings have only ASCII characters:

1. create an array of 256 length
2. traverse the first string and increment counter in the array at index = ascii value of the character. also keep counting characters to find length when you reach end of string
3. traverse the second string and decrement counter in the array at index = ascii value of the character. If the value is ever 0 before decrementing, return false since the strings are not anagrams. also, keep track of the length of this second string.
4. at the end of the string traversal, if lengths of the two are equal, return true, else, return false.

If string can have unicode characters, then use a hash map instead of an array to keep track of the frequency. Rest of the algorithm remains same.

Notes:

1. calculating length while adding characters to array ensures that we traverse each string only once.
2. Using array in case of an ASCII only string optimizes space based on the requirement.

I guess your sorting algorithm is not really O(log n), is it?

The best you can get is O(n) for your algorithm, because you have to check every character.

You might use two tables to store the counts of each letter in every word, fill it with O(n) and compare it with O(1).

It seems that the following implementation works too, can you check?

``````int histogram[256] = {0};
for (int i = 0; i < strlen(str1); ++i) {
/* Just inc and dec every char count and
* check the histogram against 0 in the 2nd loop */
++histo[str1[i]];
--histo[str2[i]];
}

for (int i = 0; i < 256; ++i) {
if (histo[i] != 0)
return 0; /* not an anagram */
}

return 1; /* an anagram */
``````
• Doesn't this presume ASCII encoding (isn't that why the array is 256 elements wide)? Commented May 23, 2013 at 21:14
``````/* Program to find the strings are anagram or not*/
/* Author Senthilkumar M*/

Eg.
Anagram:
str1 = stackoverflow
str2 = overflowstack

Not anagram:`enter code here`
str1 = stackforflow
str2 = stacknotflow

int is_anagram(char *str1, char *str2)
{
int l1 = strlen(str1);
int l2 = strlen(str2);
int s1 = 0, s2 = 0;
int i = 0;

/* if both the string are not equal it is not anagram*/
if(l1 != l2) {
return 0;
}
/* sum up the character in the strings
if the total sum of the two strings is not equal
it is not anagram */
for( i = 0; i < l1; i++) {
s1 += str1[i];
s2 += str2[i];
}
if(s1 != s2) {
return 0;
}
return 1;
}
``````

If both strings are of equal length proceed, if not then the strings are not anagrams.

Iterate each string while summing the ordinals of each character. If the sums are equal then the strings are anagrams.

Example:

``````    public Boolean AreAnagrams(String inOne, String inTwo) {

bool result = false;

if(inOne.Length == inTwo.Length) {

int sumOne = 0;
int sumTwo = 0;

for(int i = 0; i < inOne.Length; i++) {

sumOne += (int)inOne[i];
sumTwo += (int)inTwo[i];
}

result = sumOne == sumTwo;
}

return result;
}
``````
• Generally, white space is ignored in anagrams. This means that length is not the criterion. One famous anagram: "William Shakespeare" is anagram with "I am a weakish speller". I suppose that spaces should be allowed if problem statement doesn't say the opposite. Commented Dec 18, 2013 at 21:47

implementation in Swift 3:

``````func areAnagrams(_ str1: String, _ str2: String) -> Bool {
return dictionaryMap(forString: str1) == dictionaryMap(forString: str2)
}

func dictionaryMap(forString str: String) -> [String : Int] {
var dict : [String : Int] = [:]
for var i in 0..<str.characters.count {
if let count = dict[str[i]] {
dict[str[i]] = count + 1
}else {
dict[str[i]] = 1
}
}
return dict
}
//To easily subscript characters
extension String {
subscript(i: Int) -> String {
return String(self[index(startIndex, offsetBy: i)])
}
}
``````
``````import java.util.ArrayList;
import java.util.Arrays;
import java.util.Map;
import java.util.Scanner;

/**
* --------------------------------------------------------------------------
* Finding Anagrams in the given dictionary. Anagrams are words that can be
* formed from other words Ex :The word "words" can be formed using the word
* "sword"
* --------------------------------------------------------------------------
* Input : if choose option 2 first enter no of word want to compare second
* enter word ex:
*
* Enter choice : 1:To use Test Cases 2: To give input 2 Enter the number of
* words in dictionary
* 6
* viq
* khan
* zee
* khan
* am
*
* Dictionary : [ viq khan zee khan am]
* Anagrams 1:[khan, khan]
*
*/
public class Anagrams {

public static void main(String args[]) {
// User Input or just use the testCases
int choice;
@SuppressWarnings("resource")
Scanner scan = new Scanner(System.in);
System.out.println("Enter choice : \n1:To use Test Cases 2: To give input");
choice = scan.nextInt();
switch (choice) {
case 1:
testCaseRunner();
break;
case 2:
userInput();
default:
break;
}
}

private static void userInput() {
@SuppressWarnings("resource")
Scanner scan = new Scanner(System.in);
System.out.println("Enter the number of words in dictionary");
int number = scan.nextInt();
String dictionary[] = new String[number];
//
for (int i = 0; i < number; i++) {
dictionary[i] = scan.nextLine();
}
printAnagramsIn(dictionary);

}

/**
* provides a some number of dictionary of words
*/
private static void testCaseRunner() {

String dictionary[][] = { { "abc", "cde", "asfs", "cba", "edcs", "name" },
{ "name", "mane", "string", "trings", "embe" } };
for (int i = 0; i < dictionary.length; i++) {
printAnagramsIn(dictionary[i]);
}
}

/**
* Prints the set of anagrams found the give dictionary
*
* logic is sorting the characters in the given word and hashing them to the
* word. Data Structure: Hash[sortedChars] = word
*/
private static void printAnagramsIn(String[] dictionary) {
System.out.print("Dictionary : [");// + dictionary);
for (String each : dictionary) {
System.out.print(each + " ");
}
System.out.println("]");
//

Map<String, ArrayList<String>> map = new LinkedHashMap<String, ArrayList<String>>();
// review comment: naming convention: dictionary contains 'word' not
// 'each'
for (String each : dictionary) {
char[] sortedWord = each.toCharArray();
// sort dic value
Arrays.sort(sortedWord);
//input word
String sortedString = new String(sortedWord);
//
ArrayList<String> list = new ArrayList<String>();
if (map.keySet().contains(sortedString)) {
list = map.get(sortedString);
}
map.put(sortedString, list);
}
// print anagram
int i = 1;
for (String each : map.keySet()) {
if (map.get(each).size() != 1) {
System.out.println("Anagrams " + i + ":" + map.get(each));
i++;
}
}
}
}
``````

I just had an interview and 'SolutionA' was basically my solution.

Seems to hold.

It might also work to sum all characters, or the hashCodes of each character, but it would still be at least O(n).

``````/**
* Using HashMap
*
* O(a + b + b + b) = O(a + 3*b) = O( 4n ) if a and b are equal. Meaning O(n) in total.
*/
public static final class SolutionA {
//
private static boolean isAnagram(String a, String b) {
if ( a.length() != b.length() ) return false;

HashMap<Character, Integer> aa = toHistogram(a);
HashMap<Character, Integer> bb = toHistogram(b);

return isHistogramsEqual(aa, bb);
}

private static HashMap<Character, Integer> toHistogram(String characters) {
HashMap<Character, Integer> histogram = new HashMap<>();
int i = -1; while ( ++i < characters.length() ) {
histogram.compute(characters.charAt(i), (k, v) -> {
if ( v == null ) v = 0;
return v+1;
});
}

return histogram;
}

private static boolean isHistogramsEqual(HashMap<Character, Integer> a, HashMap<Character, Integer> b) {
for ( Map.Entry<Character, Integer> entry : b.entrySet() ) {
Integer aa = a.get(entry.getKey());
Integer bb = entry.getValue();

if ( !Objects.equals(aa, bb) ) {
return false;
}
}

return true;
}

public static void main(String[] args) {
System.out.println(isAnagram("abc", "cba"));
System.out.println(isAnagram("abc", "cbaa"));
System.out.println(isAnagram("abcc", "cba"));
System.out.println(isAnagram("abcd", "cba"));
System.out.println(isAnagram("twelve plus one", "eleven plus two"));
}
}
``````

I've provided a hashCode() based implementation as well. Seems to hold as well.

``````/**
* Using hashCode()
*
* O(a + b) minimum + character.hashCode() calculation, the latter might be cheap though. Native implementation.
*
* Risk for collision albeit small.
*/
public static final class SolutionB {

public static void main(String[] args) {
System.out.println(isAnagram("abc", "cba"));
System.out.println(isAnagram("abc", "cbaa"));
System.out.println(isAnagram("abcc", "cba"));
System.out.println(isAnagram("abcd", "cba"));
System.out.println(isAnagram("twelve plus one", "eleven plus two"));
}

private static boolean isAnagram(String a, String b) {
if ( a.length() != b.length() ) return false;

}

private static long toHashcode(String str) {
long sum = 0; int i = -1; while ( ++i < str.length() ) {
sum += Objects.hashCode( str.charAt(i) );
}

return sum;
}
}
``````

in java we can also do it like this and its very simple logic

``````import java.util.*;

class Anagram
{
public static void main(String args[]) throws Exception
{
Boolean FLAG=true;

Scanner sc= new Scanner(System.in);

System.out.println("Enter 1st string");

String s1=sc.nextLine();

System.out.println("Enter 2nd string");

String s2=sc.nextLine();

int i,j;
i=s1.length();
j=s2.length();

if(i==j)
{
for(int k=0;k<i;k++)
{
for(int l=0;l<i;l++)
{
if(s1.charAt(k)==s2.charAt(l))
{
FLAG=true;
break;
}
else
FLAG=false;
}
}
}
else
FLAG=false;
if(FLAG)
System.out.println("Given Strings are anagrams");
else
System.out.println("Given Strings are not anagrams");
}
}
``````
• This code has a bug. It says that 12343 and 12344 are anagrams, but they are not. The inner loop should account for the fact a specific character has already been counted in comparison against the first string. Commented Jul 4, 2013 at 15:50

How about converting into the int value of the character and sum up :

If the value of sum are equals then they are anagram to each other.

``````def are_anagram1(s1, s2):
return [False, True][sum([ord(x) for x in s1]) == sum([ord(x) for x in s2])]

s1 = 'james'
s2 = 'amesj'
print are_anagram1(s1,s2)
``````

This solution works only for 'A' to 'Z' and 'a' to 'z'.

• This doesn't work. It returns `True` for the strings `'ac'` and `'bb'`. Commented Sep 6, 2014 at 17:27