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A circus is designing a tower routine consisting of people standing atop one another’s shoulders. For practical and aesthetic reasons, each person must be both shorter and lighter than the person below him or her. Given the heights and weights of each person in the circus, write a method to compute the largest possible number of people in such a tower.

EXAMPLE:
Input (ht, wt): (65, 100) (70, 150) (56, 90) (75, 190) (60, 95) (68, 110)
Output: The longest tower is length 6 and includes from top to bottom: (56, 90) (60,95) (65,100) (68,110) (70,150) (75,190)

Someone suggested me the following: It can be done as follows:

  1. Sort the input in decreasing order of weight and find the longest decreasing sequence of hight.
  2. Sort the input in decreasing order of hight and find the longest decreasing sequence of weight.

Take max of 1 and 2.

I dont understand why we need to do both steps 1 and 2. Cant we just do 1 and find the answer. IF not , please give example in which doing only step 1 does not give answer?

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The sort of problem is called longest path in a directed acyclic graph. –  QuentinUK Aug 1 '11 at 0:42
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5 Answers 5

up vote 3 down vote accepted

Result of 1 and 2 has to be same. It's not possible that one of them is shorter, because in a solution elements are descending both in height and weight so if it satisfies 1 or 2 it will satisfy the other as well, If it would be shorter it wouldn't be the longest.

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is the solution correct in the first place? –  Programmer Aug 1 '11 at 0:25
    
yes, it's correct. –  Karoly Horvath Aug 1 '11 at 8:16
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You're absolutely correct. Doing just one direction is enough.

A proof is easy by using the maximum property of the subsequence. We assume one side (say the left) of values is ordered, and take the longest descending subsequence of the right. We now perform the other operation, order the right and take the subsequence from the left.

If we arrive at a list that is either shorter or longer than the first one we found we have reached a contradiction, since that subsequence was ordered in the very same relative order in the first operation, and thus we could have found a longer descending subsequence, in contradiction to the assumption that the one we took was maximal. Similarly if it's shorter then the argument is symmetrical.

We conclude that finding the maximum on just one side will be the same as the maximum of the reverse ordered operation.

Worth noting that I haven't proven that this is a solution to the problem, just that the one-sided algorithm is equivalent to the two-sided version. Although the proof that this is correct is almost identical, assume that there exists a longer solution and it contradicts the maximalness of the subsequence. That proves that there is nothing longer, and it's trivial to see that every solution the algorithm produces is a valid solution. Which means the algorithm's result is both >= the solution and <= the solution, therefore it is the solution.

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You might need to say something about the weights & heights all being unique. Otherwise, if

A is (10, 10) // (w, h)
B is ( 9, 10)
C is ( 9,  8)

Then neither method gets the correct answer! C obviously can stand on A's shoulders.


Edit:

Neither method is good enough!

Example with all weights & heights unique:

A : (12, 12)
B : (11,  8)
C : (10,  9)
D : ( 9, 10)
E : ( 8, 11)
F : ( 7,  7)

Both methods give an answer of 2, however the tower can be at least of height 3 with several combinations:

  • A on the bottom,
  • then any of B, C, D, or E,
  • then F on top.

I think stricter rules on the input data are needed to make this problem solvable by the given methods.

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I was thinking the same thing. If this isn't guaranteed and the question really requires strictly lighter/shorter, how would you solve the problem? –  Patrick87 Jul 31 '11 at 23:51
    
I thought so as well, although it doesn't matter. The problem doesn't allow two people of the same height/weight to be in the tower so the order of same-height/same-weight entities is irrelevant. And if you do allow them to participate then you can build that into the comparator to break equality by the descending order of the second parameter, guaranteeing the longest subsequence. –  davin Jul 31 '11 at 23:52
    
Your second part is incorrect as well: both methods can find all the solutions you mentioned, since those are valid descending subsequences of the right-hand-side values. –  davin Aug 1 '11 at 0:19
    
@stomp: why cant c stand on a. c is both lighter and shorter –  Programmer Aug 1 '11 at 0:25
    
@davin are not subsequences contiquous by definition? The longest subsequence I see is of length = 2. –  Stomp Aug 1 '11 at 0:26
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It doesn't make any difference. And it is unnecessary to pre-sort as you end up with the same graph to search.

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The presort is just to make life easier anyways (longest increasing subsequence is usualy stated over arrays) –  hugomg Aug 1 '11 at 3:52
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As far as I can see, this is the same question as Box stacking problem:

Also: http://people.csail.mit.edu/bdean/6.046/dp/

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