# Find all possible combinations of a String representation of a number

Given a mapping:

``````A: 1
B: 2
C: 3
...
...
...
Z: 26
``````

Find all possible ways a number can be represented. E.g. For an input: "121", we can represent it as:

``````ABA [using: 1 2 1]
LA [using: 12 1]
AU [using: 1 21]
``````

I tried thinking about using some sort of a dynamic programming approach, but I am not sure how to proceed. I was asked this question in a technical interview.

Here is a solution I could think of, please let me know if this looks good:

``````A[i]: Total number of ways to represent the sub-array number[0..i-1] using the integer to alphabet mapping.
``````

Solution [am I missing something?]:

``````A[0] = 1 // there is only 1 way to represent the subarray consisting of only 1 number
for(i = 1:A.size):
A[i] = A[i-1]
if(input[i-1]*10 + input[i] < 26):
A[i] += 1
end
end
print A[A.size-1]
``````
• DO you have to print all possible combinations or number of possible combinations? – Fallen Jul 31 '13 at 5:58
• What if input is 101? Does it split into 10,1 and 1,01? – Jason L Jul 31 '13 at 6:29
• @Fallen: number of possible combinations – Darth.Vader Aug 4 '13 at 20:26
• Jason, you are right. – Darth.Vader Aug 4 '13 at 20:27

To just get the count, the dynamic programming approach is pretty straight-forward:

``````A[0] = 1
for i = 1:n
A[i] = 0
if input[i-1] > 0                            // avoid 0
A[i] += A[i-1];
if i > 1 &&                          // avoid index-out-of-bounds on i = 1
10 <= (10*input[i-2] + input[i-1]) <= 26 // check that number is 10-26
A[i] += A[i-2];
``````

If you instead want to list all representations, dynamic programming isn't particularly well-suited for this, you're better off with a simple recursive algorithm.

• Dukeling, your solution got me started thinking in the right direction. I do, have some objections in the main logic in your code. Why are you looking at the elements at [i-2] and [i-1]? Should you not be looking at input[i-1] and input[i] to check whether input[i-1...i] lies in [1,26]? I have updated my question to propose a solution that I could think of based on your code here. Can you please comment on that? – Darth.Vader Aug 4 '13 at 21:18
• `i-2` and `i-1` versus `i-1` and `i` are essentially the same. For my solution, `A[0]` is for an array with 0 elements, yours is for 1 element, both approaches are valid. For your solution - `A[i-1]*10 + A[i]` should be `input[i-1]*10 + input[i]`, `A` is you DP array, not the input. For `109`, you'll count `0` and `09`, but neither are valid - you need to include additional checks (as I did). `A[i] += 1` is not correct. You can't just increase by 1, e.g for `1912`, your `A` will be `[1,2,2,3]`, but it should be `[1,2,2,4]`, you need to add the number of representations using 2 less characters. – Dukeling Aug 4 '13 at 22:54
• great explanation. I have posted a java based solution to this question based on our discussion below. – Darth.Vader Aug 5 '13 at 2:20

First off, we need to find an intuitive way to enumerate all the possibilities. My simple construction, is given below.

`````` let us assume a simple way to represent your integer in string format.

a1 a2 a3 a4 ....an, for instance in 121 a1 -> 1 a2 -> 2, a3 -> 1
``````

Now,

We need to find out number of possibilities of placing a + sign in between two characters. + is to mean characters concatenation here.

``````a1 - a2 - a3 - .... - an, - shows the places where '+' can be placed. So, number of positions is n - 1, where n is the string length.
``````

Assume a position may or may not have a + symbol shall be represented as a bit. So, this boils down to how many different bit strings are possible with the length of n-1, which is clearly 2^(n-1). Now in order to enumerate the possibilities go through every bit string and place right + signs in respective positions to get every representations,

``````   Four bit strings are possible 00 01 10 11
1   2   1
1   2 + 1
1 + 2   1
1 + 2 + 1

And if you see a character followed by a +, just add the next char with the current one and do it sequentially to get the representation,

x + y z a + b + c d

would be (x+y) z (a+b+c) d
``````

Hope it helps.

And you will have to take care of edge cases where the size of some integer > 26, of course.

I think, recursive traverse through all possible combinations would do just fine:

``````mapping = {"1":"A", "2":"B", "3":"C", "4":"D", "5":"E", "6":"F", "7":"G",
"8":"H", "9":"I", "10":"J",
"11":"K", "12":"L", "13":"M", "14":"N", "15":"O", "16":"P",
"17":"Q", "18":"R", "19":"S", "20":"T", "21":"U", "22":"V", "23":"W",
"24":"A", "25":"Y", "26":"Z"}

def represent(A, B):
if A == B == '':
return [""]
ret = []
if A in mapping:
ret += [mapping[A] + r for r in represent(B, '')]
if len(A) > 1:
ret += represent(A[:-1], A[-1]+B)
return ret

print represent("121", "")
``````

Assuming you only need to count the number of combinations.

Assuming 0 followed by an integer in [1,9] is not a valid concatenation, then a brute-force strategy would be:

``````Count(s,n)
x=0
if (s[n-1] is valid)
x=Count(s,n-1)
y=0
if (s[n-2] concat s[n-1] is valid)
y=Count(s,n-2)
return x+y
``````

A better strategy would be to use divide-and-conquer:

``````Count(s,start,n)
if (len is even)
{
//split s into equal left and right part, total count is left count multiply right count
x=Count(s,start,n/2) + Count(s,start+n/2,n/2);
y=0;
if (s[start+len/2-1] concat s[start+len/2] is valid)
{
//if middle two charaters concatenation is valid
//count left of the middle two characters
//count right of the middle two characters
//multiply the two counts and add to existing count
y=Count(s,start,len/2-1)*Count(s,start+len/2+1,len/2-1);
}
return x+y;
}
else
{
//there are three cases here:

//case 1: if middle character is valid,
//then count everything to the left of the middle character,
//count everything to the right of the middle character,
//multiply the two, assign to x
x=...

//case 2: if middle character concatenates the one to the left is valid,
//then count everything to the left of these two characters
//count everything to the right of these two characters
//multiply the two, assign to y
y=...

//case 3: if middle character concatenates the one to the right is valid,
//then count everything to the left of these two characters
//count everything to the right of these two characters
//multiply the two, assign to z
z=...

return x+y+z;
}
``````

The brute-force solution has time complexity of `T(n)=T(n-1)+T(n-2)+O(1)` which is exponential.

The divide-and-conquer solution has time complexity of `T(n)=3T(n/2)+O(1)` which is O(n**lg3).

Hope this is correct.

Something like this?

``````import qualified Data.Map as M
import Data.Maybe (fromJust)

combs str = f str [] where
charMap = M.fromList \$ zip (map show [1..]) ['A'..'Z']
f []     result = [reverse result]
f (x:xs) result
| null xs =
case M.lookup [x] charMap of
Nothing -> ["The character " ++ [x] ++ " is not in the map."]
Just a  -> [reverse \$ a:result]
| otherwise =
case M.lookup [x,head xs] charMap of
Just a  -> f (tail xs) (a:result)
++ (f xs ((fromJust \$ M.lookup [x] charMap):result))
Nothing -> case M.lookup [x] charMap of
Nothing -> ["The character " ++ [x]
++ " is not in the map."]
Just a  -> f xs (a:result)
``````

Output:

``````*Main> combs "121"
["LA","AU","ABA"]
``````

for instance 121

Start from the first integer, consider 1 integer character first, map 1 to a, leave 21 then 2 integer character map 12 to L leave 1.

Here is the solution based on my discussion here:

``````private static int decoder2(int[] input) {
int[] A = new int[input.length + 1];
A[0] = 1;

for(int i=1; i<input.length+1; i++) {
A[i] = 0;
if(input[i-1] > 0) {
A[i] += A[i-1];
}
if (i > 1 && (10*input[i-2] + input[i-1]) <= 26) {
A[i] += A[i-2];
}
System.out.println(A[i]);
}
return A[input.length];
}
``````

This problem can be done in o(fib(n+2)) time with a standard DP algorithm. We have exactly n sub problems and button up we can solve each problem with size i in o(fib(i)) time. Summing the series gives fib (n+2).

If you consider the question carefully you see that it is a Fibonacci series. I took a standard Fibonacci code and just changed it to fit our conditions.

The space is obviously bound to the size of all solutions o(fib(n)).

Consider this pseudo code:

``````Map<Integer, String> mapping = new HashMap<Integer, String>();

List<String > iterative_fib_sequence(string input) {
int length = input.length;
if (length <= 1)
{
if (length==0)
{
return "";
}
else//input is a-j
{
return mapping.get(input);
}
}
List<String> b = new List<String>();
List<String> a = new List<String>(mapping.get(input.substring(0,0));
List<String> c = new List<String>();

for (int i = 1; i < length; ++i)
{
int dig2Prefix = input.substring(i-1, i); //Get a letter with 2 digit (k-z)
if (mapping.contains(dig2Prefix))
{
String word2Prefix = mapping.get(dig2Prefix);
foreach (String s in b)
{
}
}

int dig1Prefix = input.substring(i, i); //Get a letter with 1 digit (a-j)
String word1Prefix = mapping.get(dig1Prefix);
foreach (String s in a)
{
}

b = a;
a = c;
c = new List<String>();
}
return a;
}
``````

old question but adding an answer so that one can find help

It took me some time to understand the solution to this problem – I refer accepted answer and @Karthikeyan's answer and the solution from geeksforgeeks and written my own code as below:

To understand my code first understand below examples:

• we know, `decodings([1, 2])` are `"AB"` or `"L"` and so `decoding_counts([1, 2]) == 2`
• And, `decodings([1, 2, 1])` are `"ABA"`, `"AU"`, `"LA"` and so `decoding_counts([1, 2, 1]) == 3`

using the above two examples let's evaluate `decodings([1, 2, 1, 4])`:

• case:- "taking next digit as single digit"

taking `4` as single digit to decode to letter `'D'`, we get `decodings([1, 2, 1, 4])` == `decoding_counts([1, 2, 1])` because `[1, 2, 1, 4]` will be decode as `"ABAD"`, `"AUD"`, `"LAD"`

• case:- "combining next digit with the previous digit"

combining `4` with previous `1` as `14` as a single to decode to letter `N`, we get `decodings([1, 2, 1, 4])` == `decoding_counts([1, 2])` because `[1, 2, 1, 4]` will be decode as `"ABN"` or `"LN"`

``````def decoding_counts(digits):
# defininig count as, counts[i] -> decoding_counts(digits[: i+1])
counts = [0] * len(digits)

counts[0] = 1
for i in xrange(1, len(digits)):

# case:- "taking next digit as single digit"
if digits[i] != 0: # `0` do not have mapping to any letter
counts[i] = counts[i -1]

# case:- "combining next digit with the previous digit"
combine = 10 * digits[i - 1] + digits[i]
if 10 <= combine <= 26: # two digits mappings
counts[i] += (1 if i < 2 else counts[i-2])

return counts[-1]

for digits in "13", "121", "1214", "1234121":
print digits, "-->", decoding_counts(map(int, digits))
``````

outputs:

``````13 --> 2
121 --> 3
1214 --> 5
1234121 --> 9
``````

note: I assumed that input `digits` do not start with `0` and only consists of `0-9` and have a sufficent length

• note: `decoding_counts([1, 3, 0]) --> 0` !! that is a bug – Grijesh Chauhan May 1 at 17:17
• Let me know if someone wants a complete execution example for `"1214"` according to `decoding_counts()` – Grijesh Chauhan May 6 at 16:20

After research I stumbled on this video https://www.youtube.com/watch?v=qli-JCrSwuk, very well explained.

• Although the video answers the question. Its better to include the solution in the answer. Video may get deleted also in future – Mangaldeep Pannu Jun 20 at 7:47