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For example, input is

Array 1 = [2, 3, 4, 5]
Array 2 = [3, 2, 5, 4]

Minimum number of swaps needed are 2.

The swaps need not be with adjacent cells, any two elements can be swapped.

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Why do you need this? What problem are you trying to solve? Or is it homework? –  Mark Byers Jun 7 '10 at 7:03
I'm trying out spoj.pl/problems/YODANESS –  Dogbert Jun 7 '10 at 8:20
it seems to me like that problem asks you to count inversions, not what you're asking here. –  IVlad Jun 7 '10 at 9:15
Is asking for solutions to SPOJ problems the way to go? Shouldn't you try to figure it out yourself? Why don't you ask for hints instead of the answer? –  MAK Jun 7 '10 at 22:28

5 Answers 5

up vote 21 down vote accepted

As @IVlad noted in the comment to your question Yodaness problem asks you to count number of inversions and not minimal number of swaps.

For example:

L1 = [2,3,4,5]
L2 = [2,5,4,3]

The minimal number of swaps is one (swap 5 and 3 in L2 to get L1), but number of inversions is three: (5 4), (5 3), and (4 3) pairs are in the wrong order.

The simplest way to count number of inversions follows from the definition:

A pair of elements (pi,pj) is called an inversion in a permutation p if i < j and pi > pj.

In Python:

def count_inversions_brute_force(permutation):
    """Count number of inversions in the permutation in O(N**2)."""
    return sum(pi > permutation[j]
               for i, pi in enumerate(permutation)
               for j in xrange(i+1, len(permutation)))

You could count inversion in O(N*log(N)) using divide & conquer strategy (similar to how a merge sort algorithm works). Here's pseudo-code from Counting Inversions translated to Python code:

def merge_and_count(a, b):
    assert a == sorted(a) and b == sorted(b)
    c = []
    count = 0
    i, j = 0, 0
    while i < len(a) and j < len(b):
        c.append(min(b[j], a[i]))
        if b[j] < a[i]:
            count += len(a) - i # number of elements remaining in `a`
    # now we reached the end of one the lists
    c += a[i:] + b[j:] # append the remainder of the list to C
    return count, c

def sort_and_count(L):
    if len(L) == 1: return 0, L
    n = len(L) // 2 
    a, b = L[:n], L[n:]
    ra, a = sort_and_count(a)
    rb, b = sort_and_count(b)
    r, L = merge_and_count(a, b)
    return ra+rb+r, L


>>> sort_and_count([5, 4, 2, 3])
(5, [2, 3, 4, 5])

Here's solution in Python for the example from the problem:

yoda_words   = "in the force strong you are".split()
normal_words = "you are strong in the force".split()
perm = get_permutation(normal_words, yoda_words)
print "number of inversions:", sort_and_count(perm)[0]
print "number of swaps:", number_of_swaps(perm)


number of inversions: 11
number of swaps: 5

Definitions of get_permutation() and number_of_swaps() are:

def get_permutation(L1, L2):
    """Find permutation that converts L1 into L2.

    See http://en.wikipedia.org/wiki/Cycle_representation#Notation
    if sorted(L1) != sorted(L2):
        raise ValueError("L2 must be permutation of L1 (%s, %s)" % (L1,L2))

    permutation = map(dict((v, i) for i, v in enumerate(L1)).get, L2)
    assert [L1[p] for p in permutation] == L2
    return permutation

def number_of_swaps(permutation):
    """Find number of swaps required to convert the permutation into
    identity one.

    # decompose the permutation into disjoint cycles
    nswaps = 0
    seen = set()
    for i in xrange(len(permutation)):
        if i not in seen:           
           j = i # begin new cycle that starts with `i`
           while permutation[j] != i: # (i σ(i) σ(σ(i)) ...)
               j = permutation[j]
               nswaps += 1

    return nswaps
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What if there are duplicates in the input text? would they need a special index? –  Bob Templ May 14 '14 at 19:01
the problem is explicitly defined only for distinct words. As long as pre-/post- conditions are satisfied, you could define get_permutation however you like e.g., use ((v, L1.count(v)), i) (or a more efficient equivalent of it) instead of (v, i). –  J.F. Sebastian May 14 '14 at 19:55
That seems like it would result in the same thing. For instance, using either method on two inputs 'kamal' and 'amalk' would generate a permutation that looks like [3,2,3,4,0]; when ideally it would be [1,2,3,4,0]. I guess I should also note that even when manually passing in the permutation [1,2,3,4,0] I get 4 swaps when really the min is 3; kamal -> akmal -> almak -> amalk. –  Bob Templ May 14 '14 at 20:40
I meant "number of times v has been seen so far" instead of L1.count (i.e., list(<the dict>).count(v)) otherwise there are duplicates (add assert sorted(set(permutation)) == range(len(permutation)) to the post-conditions). Though as your example demonstrates, it is not enough. I think the extension for duplicates deserves its own question. –  J.F. Sebastian May 14 '14 at 21:04
Fair enough, thanks for your help. –  Bob Templ May 14 '14 at 21:21

As implied by Sebastian's solution, the algorithm you are looking for can be based on inspecting the permutation's cycles.

We should consider array #2 to be a permutation transformation on array #1. In your example, the permutation can be represented as P = [2,1,4,3].

Every permutation can be expressed as a set of disjoint cycles, representing cyclic position changes of the items. The permutation P for example has 2 cycles: (2,1) and (4,3). Therefore two swaps are enough. In the general case, you should simply subtract the number of cycles from the permutation length, and you get the minimum number of required swaps. This follows from the observation that in order to "fix" a cycle of N elements, N-1 swaps are enough.

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This problem has a clean, greedy, trivial solution:

  1. Find any swap operation which gets both swapped elements in Array1 closer to their destination in Array2. Perform the swap operation on Array1 if one exists.
  2. Repeat step1 until no more such swap operations exist.
  3. Find any swap operation which gets one swapped element in Array1 closer to its destination in Array2. If such an operation exist, perform it on Array1.
  4. Go back to step1 until Array1 == Array2.

The correctness of the algorithm can be proved by defining a potential for the problem as the sum of distances of all elements in array1 from their destination in array2.

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There is probably some smart dynamic programming solution but I can't figure it out right now. You could do a naive BFS traversal using something like this:

  • assert that it's possible (for instance by sorting and comparing)
  • Queue q = [ (0,L1) ]
  • While q is non-empty
    • extract some pair (i,L)
    • if L == L2, return i
    • for each 0 <= i,j <= L1.length
      • add (i+1, L.swap(i,j)) to q

UPDATE: implementation in Python (it is slow O((N3)n))

def bfs(L1, L2):
    assert sorted(L1) == sorted(L2)
    q = deque([ (0,L1) ])
    while q:
        n, L = q.popleft()
        if L == L2: return n
        for i, j in combinations(range(len(L1)), 2): # all N*(N-1)/2 pairs
            q.append((n+1, swap(L, i, j)))

from collections import deque
from itertools   import combinations    

def swap(L, i, j):
    a = list(L) # make copy
    a[i], a[j] = a[j], a[i] # swap
    return a
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I've added implementation in Python. –  J.F. Sebastian Jun 7 '10 at 19:49

This seems like an edit distance problem, except that only transpositions are allowed.

Check out Damerau–Levenshtein distance pseudo code. I believe you can adjust it to count only the transpositions.

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I don't really get wikipedia article for the Damerau-Levenshtein algorithm. It says the implementation provided doesn't really work as far as I can tell: In reality this algorithm calculates the cost of the so-called optimal string alignment, which does not always equal the edit distance. It is also easy to see that the cost of the optimal string alignment is the number of edit operations needed to make the strings equal under the condition that no substring is edited more than once. –  IVlad Jun 7 '10 at 7:42

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