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The question:

Given any string, add the least amount of characters possible to make it a palindrome in linear time.

I'm only able to come up with a O(N2) solution.

Can someone help me with an O(N) solution?

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Wouldn't you just have to change every letter in the other first half of the string to the letters in the other half? –  Smac89 Sep 11 '13 at 3:22
2  
Are we only allowed to append characters or are we allowed to add them in any position? –  Dukeling Sep 11 '13 at 8:12

6 Answers 6

up vote 2 down vote accepted
  1. Revert the string
  2. Use a modified Knuth-Morris-Pratt to find the latest match (simplest modification would be to just append the original string to the reverted string and ignore matches after len(string).
  3. Append the unmatched rest of the reverted string to the original.

1 and 3 are obviously linear and 2 is linear beacause Knut-Morris-Pratt is.

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If only appending is allowed

A Scala solution:

def isPalindrome(s: String) = s.view.reverse == s.view

def makePalindrome(s: String) = 
  s + s.take((0 to s.length).find(i => isPalindrome(s.substring(i))).get).reverse

If you're allowed to insert characters anywhere

Every palindrome can be viewed as a set of nested letter pairs.

a  n  n  a         b  o  b
|  |  |  |         |  *  |
|   --   |         |     |
---------           -----

If the palindrome length n is even, we'll have n/2 pairs. If it is odd, we'll have n/2 full pairs and one single letter in the middle (let's call it a degenerated pair).

Let's represent them by pairs of string indexes - the left index counted from the left end of the string, and the right index counted from the right end of the string, both ends starting with index 0.

Now let's write pairs starting from the outer to the inner. So in our example:

anna: (0, 0) (1, 1)
bob: (0, 0) (1, 1)

In order to make any string a palindrome, we will go from both ends of the string one character at a time, and with every step, we'll eventually add a character to produce a correct pair of identical characters.

Example: Assume the input word is "blob"

  1. Pair (0, 0) is (b, b) ok, nothing to do, this pair is fine. Let's increase the counter.
  2. Pair (1, 1) is (l, o). Doesn't match. So let's add "o" at position 1 from the left. Now our word became "bolob".
  3. Pair (2, 2). We don't need to look even at the characters, because we're pointing at the same index in the string. Done.

Wait a moment, but we have a problem here: in point 2. we arbitrarily chose to add a character on the left. But we could as well add a character "l" on the right. That would produce "blolb", also a valid palindrome. So does it matter? Unfortunately it does because the choice in earlier steps may affect how many pairs we'll have to fix and therefore how many characters we'll have to add in the future steps.

Easy algorithm: search all the possiblities. That would give us a O(2^n) algorithm. Better algorithm: use Dynamic Programming approach and prune the search space.

In order to keep things simpler, now we decouple inserting of new characters from just finding the right sequence of nested pairs (outer to inner) and fixing their alignment later. So for the word "blob" we have the following possibilities, both ending with a degenerated pair:

(0, 0) (1, 2)
(0, 0) (2, 1)

The more such pairs we find, the less characters we will have to add to fix the original string. Every full pair found gives us two characters we can reuse. Every degenerated pair gives us one character to reuse.

The main loop of the algorithm will iteratively evaluate pair sequences in such a way, that in step 1 all valid pair sequences of length 1 are found. The next step will evaluate sequences of length 2, the third sequences of length 3 etc. When at some step we find no possibilities, this means the previous step contains the solution with the highest number of pairs.

After each step, we will remove the pareto-suboptimal sequences. A sequence is suboptimal compared to another sequence of the same length, if its last pair is dominated by the last pair of the other sequence. E.g. sequence (0, 0)(1, 3) is worse than (0, 0)(1, 2). The latter gives us more room to find nested pairs and we're guaranteed to find at least all the pairs that we'd find for the former. However sequence (0, 0)(1, 2) is neither worse nor better than (0, 0)(2, 1). The one minor detail we have to beware of is that a sequence ending with a degenerated pair is always worse than a sequence ending with a full pair.

After bringing it all together:

def makePalindrome(str: String): String = {

  /** Finds the pareto-minimum subset of a set of points (here pair of indices).
    * Could be done in linear time, without sorting, but O(n log n) is not that bad ;) */
  def paretoMin(points: Iterable[(Int, Int)]): List[(Int, Int)] = {
    val sorted = points.toSeq.sortBy(identity)
    (List.empty[(Int, Int)] /: sorted) { (result, e) =>
      if (result.isEmpty || e._2 <= result.head._2)
        e :: result
      else
        result
    }
  }

  /** Find all pairs directly nested within a given pair.
    * For performance reasons tries to not include suboptimal pairs (pairs nested in any of the pairs also in the result)
    * although it wouldn't break anything as prune takes care of this. */
  def pairs(left: Int, right: Int): Iterable[(Int, Int)] = {
    val builder = List.newBuilder[(Int, Int)]
    var rightMax = str.length
    for (i <- left until (str.length - right)) {
      rightMax = math.min(str.length - left, rightMax)
      val subPairs =
        for (j <- right until rightMax if str(i) == str(str.length - j - 1)) yield (i, j)

      subPairs.headOption match {
        case Some((a, b)) => rightMax = b; builder += ((a, b))
        case None =>
      }
    }

    builder.result()
  }

  /** Builds sequences of size n+1 from sequence of size n */
  def extend(path: List[(Int, Int)]): Iterable[List[(Int, Int)]] =
    for (p <- pairs(path.head._1 + 1, path.head._2 + 1)) yield p :: path

  /** Whether full or degenerated. Full-pairs save us 2 characters, degenerated save us only 1. */
  def isFullPair(pair: (Int, Int)) =
    pair._1 + pair._2 < str.length - 1

  /** Removes pareto-suboptimal sequences */
  def prune(sequences: List[List[(Int, Int)]]): List[List[(Int, Int)]] = {
    val allowedHeads = paretoMin(sequences.map(_.head)).toSet
    val containsFullPair = allowedHeads.exists(isFullPair)
    sequences.filter(s => allowedHeads.contains(s.head) && (isFullPair(s.head) || !containsFullPair))
  }

  /** Dynamic-Programming step */
  @tailrec
  def search(sequences: List[List[(Int, Int)]]): List[List[(Int, Int)]] = {
    val nextStage = prune(sequences.flatMap(extend))
    nextStage match {
      case List() => sequences
      case x => search(nextStage)
    }
  }

  /** Converts a sequence of nested pairs to a palindrome */
  def sequenceToString(sequence: List[(Int, Int)]): String = {
    val lStr = str
    val rStr = str.reverse

    val half =
      (for (List(start, end) <- sequence.reverse.sliding(2)) yield
        lStr.substring(start._1 + 1, end._1) + rStr.substring(start._2 + 1, end._2) + lStr(end._1)).mkString

    if (isFullPair(sequence.head))
      half + half.reverse
    else
      half + half.reverse.substring(1)
  }

  sequenceToString(search(List(List((-1, -1)))).head)
}

Note: The code does not list all the palindromes, but gives only one example, and it is guaranteed it has the minimum length. There usually are more palindromes possible with the same minimum length (O(2^n) worst case, so you probably don't want to enumerate them all).

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I am assuming that you cannot replace or remove any existing characters?

A good start would be reversing one of the strings and finding the longest-common-substring (LCS) between the reversed string and the other string. Since it sounds like this is a homework or interview question, I'll leave the rest up to you.

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#include<iostream>
#include<string>

using std::cout;
using std::endl;
using std::cin;

int main() {

    std::string word, left("");
    cin >> word;
    size_t start, end;

    for (start = 0, end = word.length()-1; start < end; end--) {
        if (word[start] != word[end]) { 
            left.append(word.begin()+end, 1 + word.begin()+end);
            continue;
        }
        left.append(word.begin()+start, 1 + word.begin()+start), start++;
    }
    cout << left << ( start == end ? std::string(word.begin()+end, 1 + word.begin()+end) : "" ) 
        << std::string(left.rbegin(), left.rend()) << endl;
    return 0;
}

Don't know if it appends the minimum number, but it produces palindromes

Explained:

  • We will start at both ends of the given string and iterate inwards towards the center.
  • At each iteration, we check if each letter is the same, i.e. word[start] == word[end]?.

    • If they are the same, we append a copy of the variable word[start] to another string called left which as it name suggests will serve as the left hand side of the new palindrome string when iteration is complete. Then we increment both variables (start)++ and (end)-- towards the center
    • In the case that they are not the same, we append a copy of of the variable word[end] to the same string left
  • And this is the basics of the algorithm until the loop is done.

  • When the loop is finished, one last check is done to make sure that if we got an odd length palindrome, we append the middle character to the middle of the new palindrome formed.

Note that if you decide to append the oppoosite characters to the string left, the opposite about everything in the code becomes true; i.e. which index is incremented at each iteration and which is incremented when a match is found, order of printing the palindrome, etc. I don't want to have to go through it again but you can try it and see.

The running complexity of this code should be O(N) assuming that append method of the std::string class runs in constant time.

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Here the limit of 1000 characters in a string suggests that O(N^2) is an accepted solution: http://uva.onlinejudge.org/index.php?option=com_onlinejudge&Itemid=8&page=show_problem&problem=1394 I doubt that this problem can be solved in O(N).

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Welcome to SO! It would be better (and SO's policies states so) to post more information in answer itself, not just a link to some other website. –  Yaroslav Shabalin Feb 21 at 13:27

Here see this solution This is better than O(N^2)
Problem is sub divided in to many other sub problems
ex:
original "tostotor"
reversed "rototsot"
Here 2nd position is 'o' so dividing in to two problems by breaking in to "t" and "ostot" from the original string
For 't':solution is 1
For 'ostot':solution is 2 because LCS is "tot" and characters need to be added are "os"
so total is 2+1 = 3

def  shortPalin( S):
    k=0
    lis=len(S)
        for i in range(len(S)/2):
        if S[i]==S[lis-1-i]:
            k=k+1
        else :break
    S=S[k:lis-k]
    lis=len(S)
    prev=0
    w=len(S)
    tot=0
    for i in range(len(S)):
        if i>=w:
            break;
        elif S[i]==S[lis-1-i]:
             tot=tot+lcs(S[prev:i])
             prev=i
             w=lis-1-i
    tot=tot+lcs(S[prev:i])
    return tot

def  lcs( S):
    if (len(S)==1):
        return 1
    li=len(S)
    X=[0 for x in xrange(len(S)+1)]
    Y=[0 for l in xrange(len(S)+1)]
    for i in range(len(S)-1,-1,-1):
        for j in range(len(S)-1,-1,-1):
            if S[i]==S[li-1-j]:
                X[j]=1+Y[j+1]
            else:
                X[j]=max(Y[j],X[j+1])
        Y=X
    return li-X[0]
print shortPalin("tostotor")
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