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Consider a lock, made of a system of wheels. Each wheel has 26 letters of the alphabet, in order, and each wheel is initialized with 'a'. If you move one wheel up, the display for that wheel moves to the next letter of the alphabet; moving a wheel down, on the other hand, switches the display to the previous letter of the alphabet. For example:

['a'] ->  UP  -> ['b']
['b'] -> DOWN -> ['a']
...
['z'] ->  UP  -> ['a']
['a'] -> DOWN -> ['z']

One can move any contiguous subsequence of wheels in the same direction with just a flick. This has the same effect of moving all the wheels of the subsequence that way, with a single motion. For example, if the target string is 'zzzzzzzzz', a single movement, changing 'a' to 'z', will change the entire sequence of wheels from 'a' to 'z', thus reaching the target string -- opening the lock.

How can I determine the least number of moves to open a lock? Is there a dynamic solution for this problem? The algorithm must yield the following results:

           Target string         | # moves
   ______________________________ __________
1 | abcxyz                       |    5
2 | abcdefghijklmnopqrstuvwxyz   |   25
3 | aaaaaaaaa                    |    0
4 | zzzzzzzzz                    |    1
5 | zzzzbzzzz                    |    3

Case 1, target abcxyz:

aaa[aaa] -> DOWN -> aaazzz
aaa[zz]z -> DOWN -> aaayyz
aaa[y]yz -> DOWN -> aaaxyz
a[aa]xyz ->  UP  -> abbxyz
ab[b]xyz ->  UP  -> abcxyz

Case 5, target zzzzbzzzz:

[aaaaaaaaa] -> DOWN -> zzzzzzzzz
zzzz[z]zzzz ->  UP  -> zzzzazzzz
zzzz[a]zzzz ->  UP  -> zzzzbzzzz
share|improve this question
    
it's not clear what you want? Are you looking for an algorithm? –  BraveNewCurrency Jun 11 '13 at 20:58
1  
Why is zzzzbzzzz three moves? Can't you do aaaaaaaaa => zzzzzzzzz => zzzzbzzzz (2 moves)? –  Jan Dvorak Jun 11 '13 at 21:44
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@JanDvorak: I think that middle z goes back to a first. –  jxh Jun 11 '13 at 21:44
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@LeonardoApolinário In order to clarify your question, I've made some edits, and added some move examples, considering the comments above. Please, if something is incorrect, edit it. –  Rubens Jun 11 '13 at 22:08
4  
I think this question is constructive enough for being reopened. It is, yes, a programming question, properly tagged as algorithm, and, although its text was a bit confusing at the beginning, I do really think its current version is minimally well-stated to accept answers. –  Rubens Jun 11 '13 at 22:41

2 Answers 2

up vote 4 down vote accepted

This problem may be restated as:

What is the minimum number of moves to turn a string S, into a string that only contains 'a'?

Definition:

Consider a contiguous subsequence as a sequence of equal characters in the string. The smallest contiguous subsequence is, naturally, a single character. If you normalize small subsequences, you'll, naturally, end up with bigger subsequences, eventually reaching a single subsequence -- the entire string.

What to normalize to:

One can only move a character UP or DOWN, so, a character itself is a sequence of UP and DOWN moves. The worst case of representation of a character is the letter in the middle of the alphabet, which requires at least len(alphabet) / 2 moves to be described. In the alphabet {a..z}, the worst cases are 'm' and 'n'.

Since we want to minimize the number of moves, we need to pull DOWN letters C <= m, and pull UP those C >= n. Thus, to minimize the normalization process, we must find the greatest subsequences that requires equal normalization moves. For example, if we have a target zzzzbzzzz, we know the minimal directions are UUUUDUUUU -- U for UP, and D, DOWN.

Normalizing:

For each move, the counter is incremented, yielding the least number of moves required to transform a string. Considering the above example, we may take the following steps:

# = 0 | zzzzbzzzz | UUUUDUUUU  (choose the smallest subsequence to normalize)
# = 1 | zzzzazzzz | UUUUDUUUU  (since 'a' is the base character, we choose
                              the move that increases the largest subsequence;
                              if 'a' was the first or last character,
                              moving it would simply be overhead)
# = 2 | zzzzzzzzz | UUUUUUUUU  (choose the subsequence to normalize)
# = 3 | aaaaaaaaa | _________  (choose the subsequence to normalize)

Another example, with the target string abcxyz:

# = 0 | abcxyz | _DDUUU  (choose the smallest subsequence to normalize)
# = 1 | aabxyz | __DUUU  (choose the smallest subsequence to normalize)
# = 2 | aaaxyz | ___UUU  (choose the smallest subsequence to normalize)
# = 3 | aaayza | ___UU_  (choose the smallest subsequence to normalize)
# = 4 | aaazaa | ___U__  (choose the smallest subsequence to normalize)
# = 5 | aaaaaa | ______  (choose the smallest subsequence to normalize)

EDIT:

As pointed by @user1884905, this solution, as it is proposed, is not optimal. In the case of a target string mn, the algorithm does not lead to an optimal solution:

# = 0  | mn | DU  (choose the smallest subsequence to normalize)
# = 1  | ln | DU  (choose the smallest subsequence to normalize)
# = 2  | kn | DU  (choose the smallest subsequence to normalize)
...
# = 12 | an | _U  (choose the smallest subsequence to normalize)
# = 13 | ao | _U  (choose the smallest subsequence to normalize)
# = 14 | ap | _U  (choose the smallest subsequence to normalize)
...
# = 24 | aa | __  (choose the smallest subsequence to normalize)

And this is not optimal, as the following steps require less moves:

#0    #1    #2    ...    #12
mn -> mm -> ll -> ... -> aa

Maybe the optimal substructure to a greedy algorithm lies in reducing the global distance between the characters from the string, instead of focusing on the difference between such characters and the base case ('a').

share|improve this answer
    
Nice answer! I have a question: Is there any situation in which a wheel must be rotated to the opposite direction? for example: when a d should become an e to solve the problem with minimal steps. Or, I think this is the same question: if a wheel shows a, is there a situation when we should change it? Your first example can be solved in 3 steps when You rotate the zzzz sequences instead of rotating a to z. I try to make a tricky target string later and post it if You don't mind. –  gkovacs90 Jun 12 '13 at 9:59
    
@gkovacs90 I don't mind it at all; I'm actually trying to think of some corner case in which this approach fails. In the first example you pointed, both rotating a, and later all the z's, or rotating the two chunks of z's (two moves), and later b to a (one move), will take three steps. Since the result is the same, this is a situation when it's necessary to rotate a to something, to minimize the steps. Notice this is a O(n^2) greedy solution, that always tries to maximize inner subsequences, in order to minimize the number of moves employed. –  Rubens Jun 12 '13 at 10:14
    
@Rubens Thank You. I will try to implement it recursively and save the results in a table, to meet the requirements of dynamic programming. By the way, we studied in the same college. –  Leonardo Jun 12 '13 at 11:08
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In your zzzzbzzzz example I don't see why you moved zzzzazzzz to zzzzzzzzz. I understand that from there you can move the whole string to as in one move but that is more complicated logic. I thought that once a character is in the right place you shouldn't touch it which means zzzzbzzzz -> zzzzazzzz -> aaaaazzzz -> aaaaaaaaa would be the sequence of operations which also requires 3 moves. This logic is simpler and still gets you to the answer optimally (even if the z were something else, like w both methods would take the same number of moves - 9) –  GuyGreer Jun 12 '13 at 13:35
2  
@Rubens I like that you turned the problem around and considered the problem of turning a string into a's, it makes it easier to think about. However, dividing the alphabet into two parts and turning the lower part down and the upper part up will not always produce optimal solutions. Think of strings with letters close to the middle of the alphabet. As a simple example we might consider the string mn, here it is clear that we should not turn m upwards and n downwards, we should rather combine them using one move and then move them both together back to aa. –  user1884905 Jun 12 '13 at 14:10

Since this is just some additional info and maybe some optimization, this should be a comment to the answer of Rubens, but in an answer I can explain it better and it can be useful for the questioner too.

I also use the great reverse idea of Rubens.

So, I think there's no situation when it is necessary to rotate an a to something else. If this is correct (I have no counterexample), there is no situation where we should rotate something to the wrong direction ( I have no mathematican proof, but probably this is correct).

So, every subsequences of Us and Ds will be rotated each time with one motion. This algorithm won't take O(n^2) time. Here is the algorithm:

Let we call Rubens's string direction string

  1. set a counter to 0
  2. compute the direction string
  3. scan the direction string.
  4. if You find a contigous subsequence of U or D letters, rotate the target string at the positions towards a and increment the counter(once for each subsequence).
  5. if there was any operation, go back to step 2

This algorithm will rotate every wheel to a and it will be done after at most k/2 scanning, where k is the count of the elements of the alphabet, so this may be a solution that runs in linear time.


Maybe there is a solution with even less operation. It is just an idea, with finding increasing, decreasing or "hill-shape" sub-subsequences and extract the maximum value.For example: We can say without computing, that the cost of solving

  • abcde,
  • ecb,
  • abceeddcb

is equal to the cost of solving a single e

EDIT: I've seen user1884905's counterexample. So my algorithm will not find the optimal solution, but it can be usable to find the correct algorithm, so I don't delete it yet.

EDIT 2: Another idea that works with the sample target strings: There could be computed an average letter. It is the one for which the sum of the distances from the target string's letters is minimal. Every letter should be rotated here with the algorithm above, then the whole string can be rotated to aaaaaaaaaa. Since the alphabet is cyclic, there could be more than one average letter( like in the second example in the question), in this case we should chose the one with the minimal distance from a.

share|improve this answer
    
As from the comments in the answer I posted, there are corner cases in my approach (case mn), when following the steps I proposed does not lead to the optimal solution. Try to run this case, and some other example with your algorithm, so we may have a correct answer. As for the second part, I was actually trying to reach some of those overlapping cases with that normalization process, in order to make the solution dynamic. –  Rubens Jun 12 '13 at 14:48
    
@Rubens I'm thinking of turning as much as possible in a certain direction and calculate the number of turns of that piece. For example, abcxyz, bc I would turn up and then down xyz. I was thinking of using quicksort or other algorithm to sort the sequence that I have to turn up or down and store the calculated values ​​in a table. That would be dynamic programming? A subproblem would be trying to rotate as much as possible in one direction? –  Leonardo Jun 12 '13 at 23:02
    
@LeonardoApolinário In dynamic programming, a subproblem is usually some computation you have already performed, and that you don't need to perform again, as you already have its result. I didn't really get your idea: wouldn't you break the initial order restraint sorting the sequence? –  Rubens Jun 12 '13 at 23:54
    
I found this explanation about dynamic programming, http://community.topcoder.com/tc?module=Static&d1=tutorials&d2=dynProg. I'm thinking of solving by analogy. Instead of coins, I'm thinking the number of spins up or down. I do not know if it's right, but i will try. –  Leonardo Jun 13 '13 at 11:51
    
@gkovacs90 The greater rotation to UP or DOWN can be interpreted as a optimal substructure? –  Leonardo Jun 13 '13 at 12:56

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