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I have a problem I'm supposed to solve using recursion:

Hamming distance. The Hamming distance between two bit strings of length n is equal to the number of bits in which the two strings differ. Write a program that reads in an integer k and a bit string s from the command line, and prints out all bit strings that have Hamming distance at most k from s. For example if k is 2 and s is 0000 then your program should print out:

0011 0101 0110 1001 1010 1100

Hint: choose k of the N bits in s to flip.

I have no idea where to begin could someone point me in the right direction?

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closed as not a real question by Ashwini Chaudhary, inspectorG4dget, Martijn Pieters, UmNyobe, Jean-François Corbett Oct 23 '12 at 8:51

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

5  
what have you tried? –  Ashwini Chaudhary Oct 22 '12 at 21:21
    
A naive way to do it would be to generate all possible n-bit strings and test their hamming distance from s, returning only the ones where hamming() <= k. What have you tried? –  Joel Cornett Oct 22 '12 at 21:22
3  
This looks fun! You should try it! –  kreativitea Oct 22 '12 at 21:22
    
see en.wikipedia.org/wiki/Hamming_distance, they even have a python based solution there. –  Ashwini Chaudhary Oct 22 '12 at 21:24
    
@Ashiwini that algorithm is only for calculating the Hamming distance of two strings?! –  gefei Oct 22 '12 at 21:26

3 Answers 3

To solve a problem recursively, you need to do some small amount of work that lets you break it down into a similar -- but smaller -- problem.

In your case, you have a string i.e. a sequence of characters. The set of strings that differ from S in k places consists of some strings which either agree with S in the first place or disagree. Does that help?

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Code is as follows. The basic idea is just to consider the string t = s[:-1]. You concatenate all strings with Hamming distance less than k-1 for t with a flip of s[-1], plus you concatenate all strings with Hamming distance equal k for t with s[-1].

def flip(c): return str(1-int(c))

def flip_s(s, i):
   t =  s[:i]+flip(s[i])+s[i+1:]
   return t

def hamming(s, k):
 if k>1:
      c = s[-1]
      s1 = [y+c for y in hamming(s[:-1], k)] if len(s) > k else []
      s2 = [y+flip(c) for y in hamming(s[:-1], k-1)]
      r = []
      r.extend(s1)
      r.extend(s2)
      return r
 else:
   return [flip_s(s,i) for i in range(len(s))]


>>> print hamming("0000", 2)
>>> ['1100', '1010', '0110', '1001', '0101', '0011']
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Let H(s, k) be a set of bit strings of length len(s) that have Hamming distance k from s then we could compute it easily using smaller sets H(s[:-1], k-1) and H(s[:-1], k), where s[:-1] is s without the last character:

def H(s, k):
    # invariant: H yields `len(s)`-bit strings that have k-bits flipped
    if len(s) < k:
        return  # produce nothing; can't flip k bits
    if k == 0:
        yield s  # only one n-bit string has Hamming distance 0 from s (itself)
    else:
        for s_k_minus_one_flipped in H(s[:-1], k - 1):
            yield s_k_minus_one_flipped + flip(s[-1])  # flip last bit
        for s_k_flipped in H(s[:-1], k):
            yield s_k_flipped + s[-1]  # don't flip last bit

def flip(bit):
    assert bit == "0" or bit == "1"
    return "0" if bit == "1" else "1"

print(" ".join(H("0000", 2)))
# -> 0011 0101 1001 0110 1010 1100

demo

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