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Design an efficient algorithm to sort 5 distinct - very large - keys less than 8 comparisons in the worst case. You can't use radix sort.

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7  
If this is homework, and it sounds like it, please tell us what you have done and where you are stuck. –  dmckee Oct 7 '09 at 23:22
    
it s not a homework question. Yes i m taking algorithm class but it s just a question i m curious. I asked a similar question before I was curious if there s a better worst case. –  DarthVader Oct 7 '09 at 23:23
    
I find the median in 6 comparisons and i did two more comparisons, which is 8 again. I m curious if there s a better solution to this. –  DarthVader Oct 7 '09 at 23:24
    
I m sure 8 is the worst case, using merge sort. –  DarthVader Oct 7 '09 at 23:28
    
quicksort is also 8. Cant use insertion sort, selection sort, heapsort, bubble sort, and the linear time sorting algorithms, such as radix sort. –  DarthVader Oct 7 '09 at 23:30

9 Answers 9

up vote 15 down vote accepted

Compare A to B and C to D. WLOG, suppose A>B and C>D. Compare A to C. WLOG, suppose A>C. Sort E into A-C-D. This can be done with two comparisons. Sort B into {E,C,D}. This can be done with two comparisons, for a total of seven.

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1  
@unknown: Actually this does work. –  Artelius Oct 8 '09 at 0:23
    
(a,b=> 1), (c,d=>1), (a,c=>1),(e, (a,c,d) => can be 3), (b, (e,c,d)=> can also be 3) Am i missing a point? –  DarthVader Oct 8 '09 at 0:30
2  
Yes. The ones you say can be 3 can always be done in 2. –  recursive Oct 8 '09 at 0:33
    
See my new answer. –  Artelius Oct 8 '09 at 0:37
1  
@unknown, to sort E into A-C-D, first compare E to C. Then if E>C compare E to A, otherwise compare E to D. Sorting B into {E,C,D} is the same. –  Beta Oct 8 '09 at 0:44

This is pseudocode based on Beta's answer. Might have some mistakes as I did this in a hurry.

if (A > B)
    swap A, B
if (C > D)
    swap C, D
if (A > C)
    swap A, C
    swap B, D  # Thanks Deqing!

if (E > C)
    if (E > D) %A C D E
        if (B > D)
            if (B > E)
                return (A, C, D, E, B)
            else
                return (A, C, D, B, E)
         else
            if (B < C)
                return (A, B, C, D, E)
            else
                return (A, C, B, D, E)

    else %A C E D
        if (B > E)
            if (B > D)
                return (A, C, E, D, B)
            else
                return (A, C, E, B, D)
         else
            if (B < C)
                return (A, B, C, E, D)
            else
                return (A, C, B, E, D)
else
    if (E < A) % E A C D
        if (B > C)
            if (B > D)
                return (E, A, C, D, B)
            else
                return (E, A, C, B, D)
         else
             return (E, A, B, C, D)

    else %A E C D
        if (B > C)
            if (B > D)
                return (A, E, C, D, B)
            else
                return (A, E, C, B, D)
         else
            if (B < E)
                return (A, B, E, C, D)
            else
                return (A, E, B, C, D)
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i wish i could pick two right answers :) Thanks for the effort though. Appreciated. –  DarthVader Oct 8 '09 at 1:27
    
I don't understand, how the first 3 comparison gets A-C-D? E.g. for ABCD as 9,10,1,2 the first 3 comparison get A,C,D as 1-9-2, not we expected. I guess the 3rd comparison should be swap A, C; swap B, D; –  Deqing Jun 16 '14 at 4:03
    
Well spotted! If (A > C) then A may also be greater than D, but we can't be sure without a comparison. But swapping (A,B) with (C,D) solves the problem; afterwards we know A>B, A>C, and C>D. Edited my answer. –  Artelius Jul 15 '14 at 2:47
    
this might fail for 1 1 2 2 1 –  Ray Tayek Feb 26 at 5:43
    
I have tested it and it works correctly for 1 1 2 2 1, returning 1 1 1 2 2. –  Artelius Mar 1 at 23:56

Five item can be sorted with seven comparisons in the worst cast because log2(5!) = 6.9. I suggest to check if any standard sort sort algorithm achieves this number - if not it should be quite easy to hard-code a comparison sequence because of the low number of required comparisons.

I suggest to write a program to find the comparison sequence. Create a list with all 120 permutations of the numbers one to five. Then try all ten possible comparisons and select that one, that splits the list as good as possible in two equal sized lists. Perform this split and apply the same procedure to two lists recursively.

I wrote a small program to do this and here is the result.

Comparison 1: 0-1 [60|60] // First comparison item 0 with item 1, splits case 60/60
Comparison 2: 2-3 [30|30] // Second comparison for the first half of the first comparison
Comparison 3: 0-2 [15|15] // Third comparison for the first half of the second comparison for the first half of first comparison
Comparison 4: 2-4 [8|7]
Comparison 5: 3-4 [4|4]
Comparison 6: 1-3 [2|2]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 6: 1-4 [2|2]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 5: 0-4 [4|3]
Comparison 6: 1-2 [2|2]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 6: 1-2 [1|2]
Comparison 7: 1-3 [1|1]
Comparison 4: 0-4 [8|7]
Comparison 5: 1-4 [4|4]
Comparison 6: 1-3 [2|2]
Comparison 7: 3-4 [1|1]
Comparison 7: 0-3 [1|1]
Comparison 6: 3-4 [2|2]
Comparison 7: 0-3 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 5: 0-3 [4|3]
Comparison 6: 1-3 [2|2]
Comparison 7: 2-4 [1|1]
Comparison 7: 2-4 [1|1]
Comparison 6: 2-4 [2|1]
Comparison 7: 3-4 [1|1]
Comparison 3: 0-3 [15|15] // Third comparison for the second half of the second comparison for the first half of first comparison
Comparison 4: 3-4 [8|7]
Comparison 5: 2-4 [4|4]
Comparison 6: 1-2 [2|2]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 6: 1-4 [2|2]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 5: 0-4 [4|3]
Comparison 6: 1-3 [2|2]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 6: 1-2 [2|1]
Comparison 7: 1-3 [1|1]
Comparison 4: 0-4 [8|7]
Comparison 5: 1-4 [4|4]
Comparison 6: 1-2 [2|2]
Comparison 7: 2-4 [1|1]
Comparison 7: 0-2 [1|1]
Comparison 6: 2-4 [2|2]
Comparison 7: 0-2 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 5: 0-2 [4|3]
Comparison 6: 1-2 [2|2]
Comparison 7: 3-4 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 6: 2-4 [1|2]
Comparison 7: 3-4 [1|1]
Comparison 2: 2-3 [30|30] // Second comparison for the second half of the first comparison
Comparison 3: 0-3 [15|15]
Comparison 4: 0-4 [7|8]
Comparison 5: 0-2 [3|4]
Comparison 6: 2-4 [2|1]
Comparison 7: 3-4 [1|1]
Comparison 6: 1-2 [2|2]
Comparison 7: 3-4 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 5: 1-4 [4|4]
Comparison 6: 2-4 [2|2]
Comparison 7: 1-2 [1|1]
Comparison 7: 0-2 [1|1]
Comparison 6: 1-2 [2|2]
Comparison 7: 0-2 [1|1]
Comparison 7: 2-4 [1|1]
Comparison 4: 3-4 [7|8]
Comparison 5: 0-4 [3|4]
Comparison 6: 1-2 [1|2]
Comparison 7: 1-3 [1|1]
Comparison 6: 1-3 [2|2]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 5: 2-4 [4|4]
Comparison 6: 1-4 [2|2]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 6: 1-2 [2|2]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 3: 0-2 [15|15]
Comparison 4: 0-4 [7|8]
Comparison 5: 0-3 [3|4]
Comparison 6: 2-4 [1|2]
Comparison 7: 3-4 [1|1]
Comparison 6: 1-3 [2|2]
Comparison 7: 2-4 [1|1]
Comparison 7: 2-4 [1|1]
Comparison 5: 1-4 [4|4]
Comparison 6: 3-4 [2|2]
Comparison 7: 1-3 [1|1]
Comparison 7: 0-3 [1|1]
Comparison 6: 1-3 [2|2]
Comparison 7: 0-3 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 4: 2-4 [7|8]
Comparison 5: 0-4 [3|4]
Comparison 6: 1-2 [2|1]
Comparison 7: 1-3 [1|1]
Comparison 6: 1-2 [2|2]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 5: 3-4 [4|4]
Comparison 6: 1-4 [2|2]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 6: 1-3 [2|2]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-2 [1|1]

But now the question is how to implement this in an efficient way. Maybe one could use a look-up table to store the comparison sequence. I am also not sure how to derive the ordered output from this comparison sequence in an efficient way.

Sorting the result from above by the comparison reveals an obvious structure for the first comparisons, but it becomes harder with increasing comparison number. All blocks are symmetric around the middle indicated by -----.

Comparison 1: 0-1 [60|60]

Comparison 2: 2-3 [30|30]
Comparison 2: 2-3 [30|30]

Comparison 3: 0-2 [15|15]
Comparison 3: 0-3 [15|15]
-----
Comparison 3: 0-3 [15|15]
Comparison 3: 0-2 [15|15]

Comparison 4: 2-4 [8|7]
Comparison 4: 0-4 [8|7]
Comparison 4: 3-4 [8|7]
Comparison 4: 0-4 [8|7]
-----
Comparison 4: 0-4 [7|8]
Comparison 4: 3-4 [7|8]
Comparison 4: 0-4 [7|8]
Comparison 4: 2-4 [7|8]

Comparison 5: 3-4 [4|4]
Comparison 5: 0-4 [4|3]
Comparison 5: 1-4 [4|4]
Comparison 5: 0-3 [4|3]
Comparison 5: 2-4 [4|4]
Comparison 5: 0-4 [4|3]
Comparison 5: 1-4 [4|4]
Comparison 5: 0-2 [4|3]
-----
Comparison 5: 0-2 [3|4]
Comparison 5: 1-4 [4|4]
Comparison 5: 0-4 [3|4]
Comparison 5: 2-4 [4|4]
Comparison 5: 0-3 [3|4]
Comparison 5: 1-4 [4|4]
Comparison 5: 0-4 [3|4]
Comparison 5: 3-4 [4|4]

Comparison 6: 1-3 [2|2]
Comparison 6: 1-4 [2|2]
Comparison 6: 1-2 [2|2]
Comparison 6: 1-2 [1|2]
Comparison 6: 1-3 [2|2]
Comparison 6: 3-4 [2|2]
Comparison 6: 1-3 [2|2]
Comparison 6: 2-4 [2|1]
Comparison 6: 1-2 [2|2]
Comparison 6: 1-4 [2|2]
Comparison 6: 1-3 [2|2]
Comparison 6: 1-2 [2|1]
Comparison 6: 1-2 [2|2]
Comparison 6: 2-4 [2|2]
Comparison 6: 1-2 [2|2]
Comparison 6: 2-4 [1|2]
-----
Comparison 6: 2-4 [2|1]
Comparison 6: 1-2 [2|2]
Comparison 6: 2-4 [2|2]
Comparison 6: 1-2 [2|2]
Comparison 6: 1-2 [1|2]
Comparison 6: 1-3 [2|2]
Comparison 6: 1-2 [2|2]
Comparison 6: 1-4 [2|2]
Comparison 6: 2-4 [1|2]
Comparison 6: 1-3 [2|2]
Comparison 6: 3-4 [2|2]
Comparison 6: 1-3 [2|2]
Comparison 6: 1-2 [2|1]
Comparison 6: 1-2 [2|2]
Comparison 6: 1-4 [2|2]
Comparison 6: 1-3 [2|2]

Comparison 7: 1-2 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 7: 0-3 [1|1]
Comparison 7: 0-3 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 2-4 [1|1]
Comparison 7: 2-4 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 2-4 [1|1]
Comparison 7: 0-2 [1|1]
Comparison 7: 0-2 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 7: 3-4 [1|1]
-----
Comparison 7: 3-4 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 7: 0-2 [1|1]
Comparison 7: 0-2 [1|1]
Comparison 7: 2-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 7: 2-4 [1|1]
Comparison 7: 2-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 0-3 [1|1]
Comparison 7: 0-3 [1|1]
Comparison 7: 3-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-3 [1|1]
Comparison 7: 1-2 [1|1]
Comparison 7: 1-4 [1|1]
Comparison 7: 1-2 [1|1]
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Nice answer, I know that. Using comparison tree. There are 5! possible answer which is log120. But which algorithm to find this route? –  DarthVader Oct 7 '09 at 23:42

It has to be 7 or more comparisons.

There are 120 (5 factorial) ways for 5 objects to be arranged. An algorithm using 6 comparisons can only tell apart 2^6 = 64 different initial arrangements, so algorithms using 6 or less comparisons cannot sort all possible inputs.

There may be a way to sort using only 7 comparisons. If you only want to sort 5 elements, such an algorithm could be found (or proved not to exist) by brute force.

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Nice answer too, I already commented that I know It can be found with 7 Comparisons, but dont know how :) –  DarthVader Oct 7 '09 at 23:45

Sorting networks have a restricted structure, so don't answer the original question; but they're fun.
List of Sorting Networks generates nice diagrams or lists of SWAPs for up to 32 inputs. For 5, it gives

There are 9 comparators in this network, grouped into 6 parallel operations.  
[[0,1],[3,4]]  
[[2,4]]  
[[2,3],[1,4]]  
[[0,3]]  
[[0,2],[1,3]]  
[[1,2]]
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Sample sequence of operations, using mergesort (the merge function below will merge two sorted sublists into a single sorted combined list):

elements[1..2] <- merge(elements[1..1], elements[2..2]) # 1 comparison
elements[3..4] <- merge(elements[3..3], elements[4..4]) # 1 comparison
elements[3..5] <- merge(elements[3..4], elements[5..5]) # 1-2 comparisons
elements[1..5] <- merge(elements[1..2], elements[3..5]) # 2-4 comparisons
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According to Wikipedia:

Determining the exact number of comparisons needed to sort a given number of entries is a computationally hard problem even for small n, and no simple formula for the solution is known."

Presumably this means there is no known tractable (efficient) algorithm for determining an exactly optimal comparison sort.

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1  
He doesn't need a formula, just the answer for n=5. The quote says that it's a hard problem even for small n, but it doesn't mean that small. There's a hard lower limit of 7 on the worst case, and a known solution that gets it in 7 at worst. Who cares how hard it is for n=6? –  Steve Jessop Oct 8 '09 at 10:37

Others have stated that there are 5! = 120 arrangements (permutations) to handle, so you need 7 comparisons. To identify the permutation, in principle, you can construct a big nested if statement 7 comparisons deep. Having identified the permutation, a precalculated swap/rotation sequence can be applied.

The first problem is that the choice of second comparison depends on the result of the first comparison and so on. The trick at each stage is to choose a good comparison to divide the current set of possible permutations into two equal subsets. Simplest approach - evaluate the split that each comparison would achieve until you find a suitably balanced one. Exit early if you find a perfect balance, but be aware that perfect balance won't always be possible as we don't have exactly 2^7=128 permutations - in some (I assume 8) cases, we only need six comparisons.

The second problem is designing the swap/rotation sequences for each of the 120 possible permutations, and that's probably a dynamic programming thing. Probably requires recursive search of an if-I-do-this, the next result is that, then recurse "game tree", and you should really cache intermediate results IOW. Too tired to figure out the details ATM, sorry.

You might put all the steps into a digraph that fans out (identifying the permutation), then fans back in (applying each reordering step). Then, probably run it through a digraph minimisation algorithm.

Wrap this up in a code generator and you're done - your own algorithmically near-perfect 5 item sorter. The digraph stuff kind of implies gotos in the generated code (esp. if you minimise), but people tend to turn a blind eye to that in generated code.

Of course all this is a bit brute force, but why bother with elegance and efficiency - odds are you'll only run the working generator once anyway, and the problem size is small enough to be achievable (though probably not if you do independent naive "game tree" searches for each permutation).

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A B C D E

A
| C D E     - 1 Comparison
B

A C
| | E       - 1 Comparison
B D

  A
 / \
B   C   E   - 1 Comparison
     \
      D

E needs 3 comparisons. It should be compared to A, C, D

Try A-C-D-E in that order.

Overall there will be nine comparisons -- not very performant.

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yes it s true :) It can be done with 7 :) –  DarthVader Oct 8 '09 at 1:15
1  
Huh?! Who posts a screenshot of their Word document on a programming site? –  Sinan Ünür Oct 8 '09 at 1:15
    
Ben. What s the big deal ? How am i supposed to draw that using SO thingies. –  DarthVader Oct 8 '09 at 1:18
    
I actually like this. Change of scenery is not bad every once in a while. –  ldigas Oct 8 '09 at 1:44
    
Use the <pre> tags to get fixed-width text without formatting. –  Artelius Oct 8 '09 at 22:23

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