3

We are given an arbitrary string. Now, we can perform some operations on this string. Any letter can be transformed to any other letter. Now, we can choose any letter from the string and transform it into any other letter. This would be called as one single operation.

How can we convert a string into a string whose letters are in sorted order using minimum number of operations as described above?

All solutions, including the out-of-the-box ones are welcome!

P.S.: Here's an example-

Given string: dcba
We can convert this string into a sorted using at least 3 operations. The generated string can be any of the following:
dddd (3 operations)
aaaa (3 operations)
cccc (3 operations)
..
etc.

P.P.S.: As asked by some people, I am providing my own solution here-

One of the brute force solution is to exploit recursion. When we are at a certain character index of the string, we could either not change it or change it to some other character and recursively call the function with index incremented by one. If we change the character, increment the no. of operations by 1 else just pass it as is. At each step of the recursion, we can check whether the string sorted - if yes, then update the overall minimum with current count, if it's lesser than the current count.

  • 3
    This is not "sorting" by any conventional definition... – Oliver Charlesworth Apr 6 '15 at 9:02
  • Sure. Updated the title! – Sankalp Apr 6 '15 at 9:04
  • 1
    @Mohammad This is wrong, becasue the question asks for "minimal number of such moves". It's like saying we can sort an array by returning it as we got it - there is a case that it is already sorted, and then it's right - but that's about it. The question is not how to make it sorted, the question is how to make it sorted with minimal number of moves, the important output here is not the sorted string, but the number of swaps. – amit Apr 6 '15 at 9:12
  • 1
    So the computational complexity to arrive at the minimum is irrelevant? – Captain Giraffe Apr 6 '15 at 9:35
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    What would be the practical application of such algorithm? – bobah Apr 6 '15 at 9:36
7

This problem is equivalent to the longest increasing subsequence of your string: Clearly it is optimal to leave a maximum number of letters unchanged, and those have to form an increasing subsequence. The other direction works similarly.

While LIS can be solved in O(n log n) on general sequences, you don't even need that because you have an easier special case at hand with a small alphabet size a = 26. You can use dynamic programming to solve the problem in O(n · a):

Let f(i, j) be the optimal solution for the prefix s[0..(i-1)] that ends with letter j. We have the recurrence

f(0, j) = 0  for j = 0..25
f(i + 1, j) = [j != s[i]] + MIN(k = 0..j, f(i, k))

Where [k != j] is 1 if k != j and 0 otherwise. By computing each row of the table sequentially (with increasing j), you can compute the minimum in O(1).

The final solution is MIN(j = 0..25, f(n, j)). You can construct the corresponding string by recursively following the DP states that lead to the optimal solution:

const int a = 'z' - 'a' + 1;
vector<array<int, a>> f;
string s = "azbzc";

void reconstruct(int i, int j) {
  if (i == 0)
    return;
  int prev_j = min_element(begin(f[i-1]), begin(f[i-1]) + j + 1) - begin(f[i-1]);
  reconstruct(i - 1, prev_j);
  cout << (char)('a' + j);
}

int main() {
  f.resize(s.size() + 1);
  int n = s.size();
  for (int i = 0; i < n; ++i) {
    int sol = f[i][0];
    for (int j = 0; j < a; ++j) {
      sol = min(sol, f[i][j]);
      f[i+1][j] = (j != s[i] - 'a') + sol;
    }
  }
  int j = min_element(begin(f[n]), end(f[n])) - begin(f[n]);
  cout << "solution: " << f[n][j] << endl;
  reconstruct(n, j);
  cout << endl;
}

Output:

solution: 2
aabbc
  • Your proposed solution will not return a correct answer, I'm afraid. The return value will always be 0 since min(k = 0...j, f(i-1, k) + k!=j) will always be 0. – Sankalp Apr 6 '15 at 11:47
  • @Sankalp Yep you're right, the base case was bogus. Should be fixed now – Niklas B. Apr 6 '15 at 13:16
  • I still doubt that it would work correctly. How are you handling the case where the LIS can start not from index 0 and instead from some other index, say 4 for instance? You do realize that maintaining a minimum in the for loop will not help since you are maintaining it from the starting index only.. – Sankalp Apr 6 '15 at 14:58
  • @Sankalp My code doesn't compute the LIS, it computes the solution to your problem. I.e. for input "zzzaaaaa", you get "aaaaaaaa". The start position is not explicitly encoded in the recurrence because that's not necessary. Also please note the one-based indexing I'm using for the DP state, in case that is a source of confusion. The correctness proof for the recurrence is not too hard, you can use induction on i. – Niklas B. Apr 6 '15 at 15:03
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    @Vishnu begin(f[n]) is an iterator that points to the first element of f[n]. min_element also returns an iterator, pointing to the minimal element in f[n]. We subtract the two to get the index of the minimal element in f[n]. – Niklas B. Apr 10 '15 at 13:48
0
// One way is to find the max length of a pattern conforming and then total length - pattern length is the min count of changes.
// 
// Here is the code to find max length of entries as sorted.
#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>
#include <string.h>
#include <stdbool.h>


struct data_entry {
    int v;
    int w;
};

typedef struct data_entry data_t;

int
find_max_weight(const data_t *l, int cnt, int v)
{
    int ret = 0;
    int min = -1;

    l += cnt-1;

    while(cnt-- >= 0) {
        if ((l->v > min) && (l->v <= v)) {
            if (ret < l->w) {
                ret = l->w;
                min = l->v;
            }
        }
        --l;
    }
    return ret;
}

int
max_pattern_len(const char *s, int len)
{
    int i, max_len = 0;
    data_t l[len];

    for(i = 0; i < len; ++i) {
        data_t *p = l + i;

        p->v = *s++;

        p->w = find_max_weight(l, i, p->v) + 1; // +1 for self

        if (max_len < p->w) {
            max_len = p->w;
        }
    }
    for(i=0; i < len; ++i) {
        printf("{%d, %d}\n", l[i].v, l[i].w);
    }

    return max_len;
}

int
main(int argc, const char **argv)
{
    char buff[100];
    int i;

    if ((argc > 1) && (argc < sizeof(buff))) {
        int max;

        for(i = 1; i < argc; ++i) {
            buff[i-1] = atoi(argv[i]);
        }
        max = max_pattern_len(buff, argc-1);
        printf("max_pattern_len=%d min_changes=%d\n", max, argc-1-max);
    }
    return 0;
}

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