Given a positive integer (in the form of an array of digits). We are allowed to swap one pair of digits in the given number. We need to return the smallest possible integer that can be obtained. Note, it should be a valid integer, i.e, should not contain leading 0's.

For example:-

  1. 93561 returns 13569
  2. 596 returns 569
  3. 10234 returns 10234
  4. 120 returns 102
  5. 10091 returns 10019
  6. 98761111 returns 18761119

Is there an O(n) algorithm for this problem. I have thought of few ways for this :-

  1. Find the min. digit (minDIgit) in the given integer (except 0) and swap it with the MSB, if MSB != minDigit. If MSB==minDigit, then find the next min. digit and swap it with the most significant but 1 digit and so on. This could be O(n^2) in worst case.
  2. Make an array/vector of std::pair of digit and index and sort it in increasing order (according to digit values; keep lower indices first for matching digit values). Iterate through the sorted array. Swap the MSB with the first digit. If the least digit has corresponding index as MSB, then swap the MSB but 1 place with the next min digit. If the next min digit has corresponding index of MSB but 1 place, then swap the MSB but 2 place with this next min. digit and so on. This should be O(nlog(n)).

Can someone suggest a better algorithm.

UPDATE 1: After thinking a bit, second algo which I proposed would work perfectly fine (probably except few corner cases, which can be handled separately). Moreover, I can sort the pair(digit, index) using counting sort (according to digit values), which is a stable sort in O(n) time. Is there a flaw in my argument?

UPDATE 2: My 2nd algo would work (although with more checks for corner cases and 0's) and that too in O(n) time with counting sort. But solution given by @GaborSch is much simpler, so I won't really bother giving a proper code for my algo.

  • If I'm thinking about this correctly, don't you just need to swap the first digit with the smallest digit? If the first digit is the smallest, move to the second digit and so on. – Blender Jun 18 '13 at 16:26
  • @Blender This would be O(n^2) worst case because that is basically selection sort. – Triclops200 Jun 18 '13 at 16:28
  • @Blender This is what my first algo is. And its worst case complexity would be O(n^2). I am asking for a better algorithm, if any exists; probably something in O(n). – Shobhit Jun 18 '13 at 16:28
  • @SrikarAppal examples added. – Shobhit Jun 18 '13 at 16:33
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    Is the input bounded (for example, a 32-bit integer), or some kind of arbitrary precision integer, like BigInteger? – mbeckish Jun 18 '13 at 16:37

As a preparation, we loop through the digits, and mark the last positions of the digits in an array[10] (call it last) (including 0s). That is O(n).

Next, we start to iterate through digits from left to right. For each position we try to find the smallest digit whose last position is greater than our current position (position constraint). Also that digit must be smaller than the current digit.

If we are in the first position we start the loop on last from 1 (otherwise from 0), just until the value of the current digit (not including).

If we find such a digit (concerning the position constraint), we swap (and break the loop). If we don't, we go forward to the next digit. The cost is at most O(n*9), which is O(n).

The total cost is O(n) + O(n)*O(9) = O(n).

How does the algorithm work on the examples:

93561 ->   it can swap in the first cycle

596   ->   skipping the first cycle, 
           then finds '6' because of the position constraint 
           (comparing position '1' with last[5] = 0, last[6] = 2)

10234 ->   does not find anything because of the position constraint

93218910471211292416 -> finds the last occurrence of '1' to replace '9'

98761111 -> it can swap in the first cycle
            (last[1] = 7, so it will change the last occurrence)

555555555555555555596 -> iterates until the '9', then you skip last[5]
            but finds last[6] as a good swap

120 ->      at pos 0 (1) cannot find a non-zero element less than 1, so skip
            at pos 1 (2) can find 0 on position 2, so we swap

Once again, here we do one iteration on the digits (for pre-parsing the data), then one iteration for finding the MSB. In the second iteration we iterate on last, which is constant size (at most 9).

You can further optimize the algorithm by adding keeping track of the minimum value when it is worth to start the loop on last, but that's an optimization already. The prevoius version contained that, check the history if you're interested :)

  • Will this work on 120? Correct answer is 102. – Aaron Dufour Jun 18 '13 at 19:58
  • @AaronDufour Very good point, corrected the algorithm. Another beautiful test case we have to check :) – gaborsch Jun 18 '13 at 20:07
  • @GaborSch Thanks for the simple solution and also for pointing out some very sneaky test cases – Shobhit Jun 18 '13 at 20:53
  • @Shobhit It was my pleasure :) It was a challenging question, just look at the number of trials... – gaborsch Jun 18 '13 at 21:01

First count each digit, store it in an array (counts[10]).

Going from the left, check the digits (following is the description of the loop):

Check that there's a digit in counts which is smaller than it. Pick the smallest one. Exception: 0 is not allowed for the very first digit.

  • If there's one, swap, you're done (exit the loop!).
  • Otherwise decrement the digit in counts, and go for the next digit.

For each digit you do O(1) work. So the whole algo is O(n).

For swapping you want to use the least significant digits (furthers to the right). You can either store these locations on the initial lookup, or just before swapping you can search for the first matching digit starting from the end.

  • Not only that, you are checking each digit across the entire array, which is o(n^2) worst case. – Triclops200 Jun 18 '13 at 16:43
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    @SlaterTyranus: I only do one swap: "If there's one, swap, you're done". sigh. how did this correct answer get a downvote and 3 upvotes for a wrong comment? – Karoly Horvath Jun 18 '13 at 16:54
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    i take that back - it's a fixed size array +1 – im so confused Jun 18 '13 at 17:01
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    @AK4749 He omitted that you can just keep track of the min digit and update it when you decrement. edit Your comment is also true. – rliu Jun 18 '13 at 17:01
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    "If there's one, swap, you're done" - How do you know the position of the smaller digit, in order to perform the swap? – mbeckish Jun 18 '13 at 17:08

I would iterate over the array starting on the right end. Store the digit on the right as the smallest digit and max digit and start moving left, if you hit a new smaller number, call it potential smallest. If you keep moving left and you find a smaller number, make the smaller one the potential. If you find a bigger number, make potential smaller the smallest int and store the bigger one as max digit. Every time you hit a bigger digit than your smallest one, make it the new max digit. If you hit the end, swap max digit and smallest digit. In python (This works and is O(n))

def swap_max(digits):
    i = len(digits) - 1
    while i > 0:
        if digits[i] == 0:
            i-= 1
    max_i = i
    min_i = i
    pot_i = i
    z_i   = -1
    nz_i  = i
    i = len(digits) - 1
    while i >= 0:
        if digits[i] > digits[pot_i]:
            max_i = i
            min_i = pot_i
        if digits[i] < digits[min_i] and digits[i] != 0:
            pot_i = i
        if digits[i] == 0 and z_i == -1:
            z_i = i
        if digits[i] != 0 and i > 0:
            nz_i = i
        i -= 1
    if z_i != -1 and max_i != 0 and max_i < z_i:
        min_i = z_i
        i = nz_i
        max_i = i
    elif max_i == min_i and z_i != -1:
        i = nz_i
        if i < z_i:
            min_i = z_i
            max_i = i

    v = digits[min_i]
    digits[min_i] = digits[max_i]
    digits[max_i] = v
    return digits

tests =   [93561,596,10234,120,10091,98761111,1001,1010,1103,120,93218910471211292416]
results = [13569,569,10234,102,10019,18761119,1001,1001,1013,102,13218910471211292496]
tests = map(list,map(str,tests))
results = map(list,map(str,results))
for i in range(len(tests)):
    res ="".join(map(str,swap_max(map(int,tests[i]))))
    print res,"".join(results[i])
    if res=="".join(results[i]):
        print "PASSED\n"
        print "FAILED\n"

This ended up working for all the examples. It also has the advantage of being O(1) memory usage.

  • "591" - Wouldn't your solution result in "519"? – mbeckish Jun 18 '13 at 17:16
  • @mbeckish no, it'd result in 195. – Triclops200 Jun 18 '13 at 17:50
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    After "9" becomes "max digit", how would "5" then become "max digit", so that it can be part of the swap? – mbeckish Jun 18 '13 at 17:53
  • @mbeckish "every time you hit a bigger digit" should have been "every time you hit a bigger digit than your current smallest one" – Triclops200 Jun 18 '13 at 17:59
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    @GaborSch and because I wanted to try, I moved it all back to one loop and it still passes all test cases. So it's pure O(n) time complexity again. – Triclops200 Jun 19 '13 at 12:20

Here's a simple O(n) algorithm:

- Record 'false' for each of ten digit values, 0 through 9
- Work through the number's digits, left-to-right
    - If the digit value is associated with 'true' go to the next digit and continue
    - Record 'true' for this digit
    - Search all the digits to the right for the right-most, smallest digit
      (except zero for the first digit in the number)
      and swap if the lowest digit found (if any) is less than the current digit
    - If swapped, report success and stop
    - If not swapped, go to the next digit and continue
- If we reach the end of the digit list, report a lack of success and stop

This may not appear to be O(n) on first inspection, however after realizing that the inner loop can be executed no more than ten times, it becomes evident that this is O(n) since O(n - 10 + 10*n) = O(11*n - 10) = O(n).

  • 1
    More precisely, this algo is O(n-10 + 10*n) = O(11*n-10) = O(n) – gaborsch Jun 18 '13 at 19:28
  • 1
    It may work if we presume that in the search you select the rightmost smallest digit. +1. – gaborsch Jun 18 '13 at 21:16
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    @GaborSch Good catch, I've updated 'last' to 'right-most' to be more clear. Also, I shamelessly stole your first comment and incorporated it into the post. – Kaganar Jun 18 '13 at 21:19

PseudoCode : O(n)

1) Split the number into individual digits, say digit[10] (as said in another answer). Init incPos = -1.

2) Traverse from the right most digit , to find left most increasingPos (incPos). i.e while traversing compare k+1 element with kth element. For, every digit[k] ≠ 0, If digit[k] >= digit[k+1] then mark incPos as k. Traverse till left most and find the least incPos.

4) If incPos == -1 return num, else traverse form incPos to n to find the Right-Most-Minimum digit ( as described in BLOCK below), swap with the Right-Most-Minimum digit and return. (surely there will be atleast 1 digit.)

93561 ->                IncPos = 0,  Right most minimum : 1 at pos 4 
596   ->                IncPos = 1,  Right most minimum : 6 at pos 2 
10234 ->                IncPos = -1, return 10234  
93218910471211292416 -> IncPos = 0,  Right most minimum : 1 at pos 18 
98761111 ->             IncPos = 0,  Right most minimum : 1 at pos 7 

5) Form the number with new digits. Return number.

  • 1
    Does not work on 596, it should be 569 ... – Camouflage Jun 18 '13 at 19:18
  • @Camouflage Updated my answer. – Muthu Ganapathy Nathan Jun 18 '13 at 19:34
  • The updated solution is O(n*n)... – Camouflage Jun 18 '13 at 19:36
  • @Camouflage Updated my answer. If you are free, check it. – Muthu Ganapathy Nathan Jun 18 '13 at 19:58
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    So, with 596, you swap positions 1 (incPos) and 0 (RMM)? the result is 956 for me... – Camouflage Jun 18 '13 at 20:15

Slight variation of Karoly Horvath's algorithm

You can radix sort the array of digits in O(n).

Now we have 2 lists: sorted and actual. Actual is our original array.

Iterate over actual from left to right,

for each value, Pop off elements from Sorted until we reach a value whose position in the original array is < position of actual[i]

If the head of the sorted list's value is < actual[i] then we swap and we're done. else continue.

Sorting was done in O(n) time. At most we pop off n elements of the sorted list total, and we iterate over the original list only once, so the whole algorithm should be O(n) in time and space.

Of course there's some special case checking for a swap of 0 with the leftmost element, but that doesn't affect complexity.


Here is the Java code for the above problem satisfying all the test cases mentioned.

public static String smallestNumber(String num) {
    int length = num.length();
    char[] c = num.toCharArray();
    Map<Character, Integer> map = new HashMap<>();
    for (int i = 0; i < length; i++) {
        map.put(c[i], i);
    int count = 0;
    boolean flag = true;
    int ind = -1;
    for (int i = 0; i < length; i++) {
        int min = c[i];
        for (int j = i + 1; j < length; j++) {
            if (flag) {
                if (min > c[j] && c[j] != '0') {
                    min = c[j];
                    ind = j;
            } else {
                if (min > c[j]) {
                    min = c[j];
                    ind = j;
        if (ind != -1) {
            char temp = c[i];
            int index = map.get(c[ind]);
            c[i] = c[ind];
            c[index] = temp;
        flag = false;
        if (count == 1)
    return String.valueOf(c);

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