# Sort an array by moving elements only to the beginning or the end

I am trying to solve a difficult problem, and I'm afraid I've hit a roadblock - I'm out of ideas how to solve it. I thought maybe someone on here has stumbled upon something similar and, if not, I'm sure that those that like making algorithms will enjoy trying to find a solution:

We are given an unsorted array. We are allowed to make one of two moves: take any element out of the array and move it either to the beginning or the end of the array. We are also given what the array should look like in the end. We are supposed to sort the array with the minimum number of steps.

Example:

`````` 5 1 4 3 2 - > starting array
3 1 2 5 4 - > target array

Steps: move 5 to the end 1 4 3 2 5
move 3 to the beginning  3 1 4 2 5
move 4 to the end  3 1 2 5 4
``````

The target array has been reached, the minimal number of steps is 3.

Does anyone have any idea on how to solve this?

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Step 1 - relabel the elements such that your target array always looks like `1,2,3,4,5`. This will tremendously ease your thinking and scribbling while you work out an answer. In this case your input array would be relabelled to read `4,2,5,1,3` and the problem is already much easier. –  High Performance Mark Jan 10 at 14:37
Mark this man's advice. –  Colonel Panic Jan 10 at 14:47

I believe the trick is to find the longest common subsequence between the two arrays (you can find this in O(n^2) time. This will give you the largest possible set of numbers that don't have to move, and conversely, the smallest possible set of numbers that do have to move. Once you have the set of numbers that must move, it should be fairly trivial to figure out how to move them.

The longest common subsequence between (5, 1, 4, 3, 2) and (3, 1, 2, 5, 4) is (1, 4), (1, 2), (3, 2), or (5, 4). Each subsequence tells you that the minimum number of moves is 3 (though the moves you pick will be different for each, obvisously).

EDIT

I think this is basically the right answer (with some changes from Vaughn).

First, we build our array of subsequence lengths as usual for the longest common subsequence problem (M[i][j] = length of the longest common subsequence ending at source[i] and target[j]).

Then, instead of picking a solution, we enumerate all possible longest common subsequences.

We then assign a score to each subsequence which is the length of the longest contiguous block in the target sequence.

In the example, we get:

(1, 2) - score 2 (1, 4) - score 1 (3, 2) - score 1 (5, 4) - score 2

We pick any sequence with the maximum score and generate the appropriate move instructions to move the remaining numbers before or after this sequence.

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I believe you don't want the longest common subsequence, but rather the longest subsequence of the the source that matches a range of the target. –  Vaughn Cato Jan 10 at 14:45
It isn't homework, I solve problems from programming competitions in my spare time, this was a problem from the national competition in Serbia 10 years ago, only one competitor solved it, so it's far too difficult to be homework. Thank you for your answer –  user1902590 Jan 10 at 14:51
@Vaughn Cato: Yes, I think you're right. The set of stable elements you pick must be contiguous in the target sequence since there's no way to insert an element between two others. For instance, picking (5, 4) or (1, 2) as your subsequence works fine. (1, 4) doesn't work at all since there's no way to get the 2 and 5 between them. Trouble is, once we add this constraint, I'm no longer confident that my algorithm yields the optimal solution. –  Peter Ruderman Jan 10 at 14:57
I think of it this way: you are going to pick certain numbers from the source and add them to the beginning or end. You'll never pick the same number twice, since you could get the same result by not picking that number the first time. This means you'll have a set of numbers that match the beginning of the target (in reverse order) and a set of numbers that match the end of the target (in order), and the only way to reduce the number of steps is to have the unchosen numbers match the middle range of the target. –  Vaughn Cato Jan 10 at 15:08
Thank you. I will code this and see how it does against the test examples. –  user1902590 Jan 10 at 16:55

If an O(n^2) solution is good enough there is a really simple algorithm.

Do n iterations, where n is the length of the array. On iteration i, find the element, among elements i through n, that has the highest position in the target arrangement, and move it to the start of the array.

Iteration 1 moves the element that should be last to the start. Iteration 2 moves the element that should be next to last to immediately before it. ... Iteration n moves the final element, the one that should be first, to the start of the array.

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It seems like this always uses n steps. –  Vaughn Cato Jan 10 at 15:13
The problem is that the entire difficulty of the task is in the fact that the algorithm is expected to produce the solution with the lowest possible number of steps. What you suggested would obviously work, but doesn't meet the requirements. Thanks for answering. –  user1902590 Jan 10 at 15:35

You can do that with A* / IDA* search algorithm. you already have the "Start" & "Goal" a heuristic function can be number of ordered sub arrays. the creation of new nodes cais the transition fo elements to the start/end ...and just let the algorithm do the magic

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You can do away with the ranking mechanism if you follow @High Performance Mark's advice. For your array the relabelling will be (4, 2, 5, 1, 3). In this, the LCS are (4, 5) and (2,3). So you can start from any of these directly and move the ones in the middle:

For 4,5: look at ones smaller than 4 in descending order and move them front. Then for ones larger than 5 in ascending order

• 4, 2, 5, 1, 3 (start) --> 3
• 3, 4, 2, 5, 1 --> 2
• 2, 3, 4, 5, 1 --> 1
• 1, 2, 3, 4, 5 (end)

For 2,3: look at ones smaller than 2 in descending order and move them front. Then for ones larger than 3 in ascending order

• 4, 2, 5, 1, 3 (start) --> 1
• 1, 4, 2, 5, 3 --> 4
• 1, 2, 5, 3, 4 --> 5
• 1, 2, 3. 4, 5 (end)

Each has three moves.

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I do agree with ArunMK but his description is quite lacking. Thus I propose an implementation in C.

``````#include <stdio.h>
int start[] = { 5, 1, 4, 3, 2 };
int target[] = { 3, 1, 2, 5, 4 };
const int length = sizeof(start) / sizeof(*start);
int canon[length];

void dump_canon()
{
int i;
for (i = 0; i < length; i++)
printf("%d ", target[canon[i]]);
printf("\n");
}

int main()
{
int i, j, k;

/* First "relabel" the array so that the problems becomes: sort the array. */
for (i = 0; i < length; i++) {
for (k = 0; start[i] != target[k]; k++)
/* NO-OP */;
canon[i] = k;
}
printf("Start ");
dump_canon();
/* Search for the longuest ascending sequence without holes */
int longuest_start;
int longuest_length = 0;
for (i = 0; i < length; i++) { /* Use i + longuest_length < length for optimisation */
k = 1;
for (j = i + 1; j < length; j++) { /* condition can be optimized */
if (canon[i] + k == canon[j])
k++;
}
if (k >= longuest_length) {
longuest_start = canon[i];
longuest_length = k;
}
}

/* Now longuest_start has longuest_length ordered values */
/* Increase this ordered values stride by picking a number to put just before or after it */
while (longuest_length < length) {
for (i = 0; i < length; i++) {
if (canon[i] + 1 == longuest_start) {
k = canon[i];
for (j = i; j > 0; j--)
canon[j] = canon[j - 1];
canon[0] = k;
longuest_start--;
longuest_length++;
printf("Take %d and move it to the beginning: ", target[k]);
dump_canon();
}
else if (canon[i] == longuest_start + longuest_length) {
k = canon[i];
for (j = i; j < length - 1; j++)
canon[j] = canon[j + 1];
canon[length - 1] = k;
longuest_length++;
/* XXX We just shifted a new value here, redo this index */
i--;
printf("Take %d and move it to the end: ", target[k]);
dump_canon();
}
}
}
}
``````

Output is:

``````Start 5 1 4 3 2
Take 5 and move it to the end: 1 4 3 2 5
Take 4 and move it to the end: 1 3 2 5 4
Take 3 and move it to the beginning: 3 1 2 5 4
``````
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