# Dynamic Programming Algorithm?

I am confused about how best to design this algorithm. A ship has x pirates, where the age of the jth pirate is aj and the weight of the jth pirate is wj. I am thinking of a dynamic programming algorithm, which will find the oldest pirate whose weight is in between twenty-fifth and seventy-fifth percentile of all pirates. But I am clueless as to how to proceed.

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Whaaat? age of jth pirate as aj and wt of jth pirate as wj. ??? Can you please extend the words? It is not a chat. –  jpabluz Apr 22 '10 at 15:26
Its a(subscript j) and w(subscript j). Sorry about that. –  user323394 Apr 22 '10 at 15:28
homework? or you write software for Somali pirates? –  Andrey Apr 22 '10 at 15:29
Was asked in an interview..Could not solve it there. Was curious to find out solution. –  user323394 Apr 22 '10 at 15:31
a = age and w = weight –  user323394 Apr 22 '10 at 15:34
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Naive solution (probably not the most efficient but the first one that pops into my head, and is nice and simple):

Sort the list of pirates by weight. Then loop over the middle 50% of the list searching for the pirate with the maximum age.

Assuming you use an efficient sorting algorithm the runtime would be n*log(n) + n/2 -> O(n*log(n)).

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There is a possible O(n) solution.

The required condition is that weights must be treated as integral and bound by some upper limit. In the real world, this is true since we never really need more than one digit after the decimal point when describing someones weight. And you cant weigh more than say 10000 pounds.

Then you can use bucket sort (which is O(n)) to find out where the limits for the interesting percentile is and then simply look for the oldest pirate in there (which is also O(n)).

Edit, clarification:

The weights themselves must not be integral, but as long as the precision is limited (to a fixed and reasonable number of decimals) you can always multiply them all so that they become integral. For example, represent a weight of 167.8 as 1678.

Edit, explaining bucket sort:

Read the wikipedia article if you want a detailed description. I'll just make an example for your case here. Assume that there is a list called `pirates`. Then we can sort them into a new list `sortedPirates`. And as I explained before, a requirement for this to work is that 1) the pirate weights are integral (or can be represented as such) and 2) the number of distinct weights (or representation of weights) are bound by an upper limit. I've assumed integral weights and an upper bound of 10000 pounds here:

``````// Put the pirates into buckets (each bucket is a linked list, or null if empty)
var upperWeightBound = 10000;
foreach (var pirate in pirates)
{
if (buckets[pirate.weight] == null)
}

// Extract the bucketed pirates into a single, now sorted, linked list
foreach (var bucket in buckets)
if (bucket != null)
foreach (var pirate in bucket)
``````
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Ohh yes..This sounds like right direction. What do you mean by limits of interesting percentile though? –  user323394 Apr 22 '10 at 16:43
25th and 75th in your case. Or whatever other values that might be of interest :) –  Jakob Apr 22 '10 at 16:50
Wow! Awesome direction :) Kudos.. I will try to figure the methodology out –  user323394 Apr 22 '10 at 16:53
Hi, Could you clarify on the "bucket sorting" part? –  user323394 Apr 22 '10 at 17:31

Of the top of my head, I'd sort the data by weight, then choose minimum weight as the pirate at j = 1/4 * x and the maximum allowable weight as the pirate at j = 3/4 * x. Then I'd iterate through the set of pirates checking if their weight is greater than the minimum or greater than the maximum. If this check succeeds, then this pirate may be a candidate. If there is no current candidate, then select this pirate as the current candidate. If there is a current candidate, then select this pirate as the new current candidate only if his age is greater than the current candidate.

Sorting the candidates can be done in O(nlogn). Selecting the upper/lower weight, with a suitable data structure, is an O(1) operation. Finding the oldest qualifing candidate is O(n). So the total algorithm is O(nlogn).

Using Snippet Compiler for C#:

``````public class Pirate
{
public int ID { get; set; }
public int Age { get; set; }
public int Weight { get; set; }
}

var pirates = new List<Pirate>();
int max = 20;

Random rng = new Random();
for (int j = 0; j < max; ++j)
{
var pirate = new Pirate();
pirate.ID = j;
pirate.Age = rng.Next(45) + 15;
pirate.Weight = rng.Next(100) + 100;
}

pirates.Sort( (a,b) => a.Weight.CompareTo( b.Weight ) );

int lowWeight = pirates[max/4].Weight;
int highWeight = pirates[max*3/4].Weight;

Pirate chosen = null;
foreach (var pirate in pirates)
{
if (pirate.Weight >= lowWeight && pirate.Weight <= highWeight)
{
if (chosen == null || pirate.Age > chosen.Age)
{
chosen = pirate;
}
}
}

Console.WriteLine( "Chosen {0}: Age {1}, Height {2}", chosen.ID, chosen.Age, chosen.Weight );
``````
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Can it be done without sorting?? –  user323394 Apr 22 '10 at 16:17

You can solve it pretty efficiently in linear time.

1) Use linear time i-th order statistics "Selection algorithm" to find pirate whose weight is 25th percentile.

2) Again use the same algorithm to find pirate whose weight is 75th percentile.

3) Filter out the pirates that fall within these two bounds-- again in linear time.

4) For the qualifying pirates, compute MAX on the age criteria. -- again in linear time.

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Was going to write exactly same solution myself. Simple, nice, fast and the best! –  Nitin Garg Nov 5 '11 at 4:41