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I have an integer array int[] number = { 3,4,2,5,1};

The minimum number of steps to sort it should be 2. But I am getting 4.

static void Main(string[] args)
        {
            int[] number = { 3,4,2,5,1};

           int result =  get_order(number);

            Console.ReadKey();
        }

        public static int get_order(int[] input1)
        {
            input1 = input1.OrderByDescending(o => o).ToArray();
            bool flag = true;
            int temp;
            int numLength = input1.Length;
            int passes = 0;

            for (int i = 1; (i <= (numLength - 1)) && flag; i++)
            {
                flag = false;
                for (int j = 0; j < (numLength - 1); j++)
                {
                    if (input1[j + 1] > input1[j])
                    {
                        temp = input1[j];
                        input1[j] = input1[j + 1];
                        input1[j + 1] = temp;
                        flag = true;
                    }
                }
                passes++;
            }
            return passes+1;
        }

What is the problem and what changes i need to do in my code?

Edit

implement @Patashu, algorithm,

public static int get_order(int[] input1)
        {
            var sorterArray = input1.OrderByDescending(o => o).ToArray();
            var unsortedArray = input1;
            int temp1;
            int swap = 0;

            int arrayLength = sorterArray.Length;
            for (int i = 0; i < arrayLength; i++)
            {
                if (sorterArray[i] != unsortedArray[i])
                {
                    temp1 = unsortedArray[i];
                    unsortedArray[i] = sorterArray[i];
                    for (int j = i + 1; j < arrayLength; j++)
                    {
                        if (unsortedArray[j] == sorterArray[i])
                        {
                            unsortedArray[j] = temp1;
                            swap++;
                            break;
                        }
                    } 
                }
            }

            return swap;
        }
share|improve this question
2  
What do you define as a "step"? Also it's descending in this case? –  Zong Zheng Li Jun 13 '13 at 4:00
    
but i need to find out how many minimum steps it takes to sort...how will i do it using linq? –  priyanka.sarkar Jun 13 '13 at 4:01
3  
@HighCore I would downvote your comment if it were possible. Nevermind probably just a troll. And he deleted his comment. Classic. –  Zong Zheng Li Jun 13 '13 at 4:02

5 Answers 5

up vote 2 down vote accepted

The problem with your algorithm is that it only attempts swapping adjacent elements.

3,4,2,5,1 is best sorted by swapping 3 with 5, which is an unadjacent swap, and then 2 with 3.

So, I suggest that you will find a better algorithm by doing the following:

1) First, sort the array into descending order using the built in sorting function of C#.

2) Now, you can use this sorted array as a comparison - iterate through the array from left to right. Every time you see an element in the unsorted array that is != to the element in the same space in the sorted array, look deeper into the unsorted array for the value the sorted array has there, and do one swap.

e.g.

3,4,2,5,1

Sort using Sort -> 5,4,3,2,1 is our sorted array

3 is != 5 - look in unsorted array for 5 - found it, swap them.

Unsorted is now 5,4,2,3,1

4 == 4

2 is != 3 - look in unsorted array for 3 - found it, swap them.

Unsorted is now 5,4,3,2,1

2 == 2

1 == 1

We're at the end of the unsorted array and we did two swaps.

EDIT: In your algorithm implementation, it looks almost right except

instead of

unsortedArray[j] = sorterArray[i];
unsortedArray[i] = temp1;

you had it backwards, you want

unsortedArray[j] = temp1;
unsortedArray[i] = sorterArray[i];
share|improve this answer
    
This is what I was thinking as well. Somewhat similar to Levenshtein distance for strings? –  superEb Jun 13 '13 at 4:08
    
I'm not convinced by this method at all. Unless you brute force all possible swaps you are not going to arrive at the optimal solutions. It is extremely convenient that it even works out for this case. –  Zong Zheng Li Jun 13 '13 at 4:09
    
@ZongZhengLi You are saying it is not possible to write this algorithm faster than O(n^2)? –  Patashu Jun 13 '13 at 4:11
    
@Patashu No, I'm saying this method as it currently stands does not find the correct value. And brute forcing all swaps would be something like O(n!) I think anyways. I'm not sure what is possible since the OP has not rigorously defined the operations we are allowed to use. –  Zong Zheng Li Jun 13 '13 at 4:13
    
@ZongZhengLi Can you think of an example that foils the algorithm? –  Patashu Jun 13 '13 at 4:15

Since you're asking why you're getting 4 steps, and not how to calculate the passes, the correct way to do this is to simply step through your code. In your case the code is simple enough to step through on a piece of paper, in the debugger, or with added debug statements.

Original: 3, 4, 2, 5, 1

Pass: 1: 4, 3, 5, 2, 1
Pass: 2: 4, 5, 3, 2, 1
Pass: 3: 5, 4, 3, 2, 1
Pass: 4: 5, 4, 3, 2, 1

Basically what you see is that each iteration you sort one number into the correct position. At the end of pass one 2 is in the correct position. Then 3, 4, 5.

Ah! But this is only 3 passes you say. But you're actually incrementing passes regardless of flag, which shows you that you actually did one extra step where the array is sorted (in reverse order) but you didn't know this so you had to go through and double check (this was pass 4).

share|improve this answer

At the start:

{ 3,4,2,5,1}; // passes = 0

Round 1 reuslt:

{ 4,3,2,5,1};
{ 4,3,5,2,1}; // passes = 1

Round 2 reuslt:

{ 4,5,3,2,1}; // passes = 2

Round 3 reuslt:

{ 5,4,3,2,1}; // passes = 3 and flag is set to true

Round 4 reuslt:

{ 5,4,3,2,1}; // same result and passes is incremented to be 4 
share|improve this answer

Consider the problem of manipulating a list into a different state where you know the end state.

Find each 'enclosed subgraph' bigger than one (I'll explain this later on).
Find the sum of the lengths of the subgraphs and subtract the number of subgraphs.
There's your answer for the number of swaps.

An 'enclosed subgraph' is a minimal subset of the whole where each item in the initial list is also in the end list.

So if you construct a subgraph with the indices 4,5 and 9 from the initial state and they have the values 10, 20 and 30 then for it to be an 'enclosed subgraph', you should be able to find the values from the end state with the indices 4, 5 and 9 and those values should be 10, 20 and 30 (though not necessarily in that order).

Consider this:

a b c d f e | v b a d f c e

This would obviously take 3 swaps. (a <=> b, c <=> d, c <=> f)

Applying the algorithm above, it has:

3 'enclosed subgraphs', ([a,b], [c,d,f], [e])
2 subgraphs with more than one item ([a,b], [c,d,f])
There are 5 items in all those subgraphs
5 - 2 == the answer.

It becomes a little more difficult when you want to do the minimal number of swaps to get it into sorted order, however, it is not impossible.

Find the sorted order index of each item in the list, if you don't want to move any data, then this is n^2 time.
Find the 'enclosed subgraphs'.
Swap items in the list to get to the correct order, but only swap items within the same subgraph.

So, I hope you can see it's not impossible to do the minimal number of swaps to get to sorted order, but it's not worth it, because it requires a ridiculous number of comparisons. Just use heapsort.

share|improve this answer

You fail to mention that the array is supposed to be sorted in descending order, which is usually not the default expected behavior (at least in "C" / C++). To turn:

3, 4, 2, 5, 1

into:

1, 2, 3, 4, 5

one indeed needs 4 (non-adjacent) swaps. However, to turn it into:

5, 4, 3, 2, 1

only two swaps suffice. The following algorithm finds the number of swaps in O(m) of swap operations where m is number of swaps, which is always strictly less than the number of items in the array, n (alternately the complexity is O(m + n) of loop iterations):

int n = 5;
size_t P[] = {3, 4, 2, 5, 1};

for(int i = 0; i < n; ++ i)
    -- P[i];
// need zero-based indices (yours are 1-based)

for(int i = 0; i < n; ++ i)
    P[i] = 4 - P[i];
// reverse order?

size_t count = 0;
for(int i = 0; i < n; ++ i) {
    for(; P[i] != i; ++ count) // could be permuted multiple times
        std::swap(P[P[i]], P[i]); // look where the number at hand should be
}
// count number of permutations

This indeed finds two swaps. Note that the permutation is destroyed in the process. The test case for this algorithm can be found here (tested with Visual Studio 2008).

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