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I am working on a Java assignment and I am absolutely stumped.

The question is:

Write a function using Recursion to do the following: You have X different cards. You have only Y envelopes. Y is less than or equal to X. For any given values of X and Y,

  1. display all possible ways you can fill the Y envelopes when Order is not important and Repetition is not allowed. hint: X! / (( X-Y)! * Y!)

  2. display all possible ways you can fill the Y envelopes when Order is important and Repetition is allowed hint: X^Y

  3. display all possible ways you can fill the Y envelopes when Order is important and Repetition is not allowed hint: X! / (X – Y)!

  4. display all possible ways you can fill the Y envelopes when Order is not important and Repetition is allowed hint: (X + Y – 1)! / (Y! * (X – 1)!)

for example, under case (1), if X = {J, Q, K, A) and Y = 3, then the output should be: {J,Q,K} {J,Q,A} {J,K,A} {Q,K,A}.

I do not want anyone to post any code and I'm not looking for anyone to solve this for me! I am hoping that once I get the first part (question a) done that it'll unlock the flood gates. Can someone please offer some guidance in working out the pseudocode algorithm, this is as far as I can get:

Fill the Y envelopes in order with increasing cards (ex: X=5, Y=3) {1, 2, 3}. Replace in the highest envelope with the highest card {1, 2, 5}, decrementing until we find it's original value {1, 2, 4}. Do this for every envelope from highest to lowest (where the number is not already in use) {1, 5, 4} {1, 3, 4} {5, 3, 4} {2, 3, 4}.

That's as far as I get before it falls apart because this is missing 3 combinations {1, 5, 3} {3, 4, 5} {5, 3, 2}.

I would appreciate any help at all and as it's an assignment I'll re-iterate, I don't want the solution, I want help in coming to the solution on my own. Thank you!

EDIT: I've tried all 3 solutions outlined and I'm still not getting it. This is what I'm getting so far:

public static void comboNoRep(String[] a, int y, boolean[] used)
{

    if(y == 0) {
        // found a valid solution.
        System.out.println(result);
    }

    for(int i=0; i<a.length; i++) {
        if(!used[i]) {
            used[i] = true;
            result = result + a[i];
            comboNoRep(a, y - 1, used);
            result = result + " ";
            used[i] = false;
        }
        else {
        }
    }

}

Can anyone help point out my flaw?

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1  
You might want to try researching this before you post. This problem has been solved many times. –  rharrison33 Nov 4 '12 at 3:06
    
@rharrison33: I researched it before I posted and got nowhere, which is why I posted. –  dominicvautour Nov 4 '12 at 23:57
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4 Answers 4

Your teacher wants you to use recursion.

What is the answer, for a given X, if Y is zero? Solve this using your code.

What is the answer, for a given X, if I give you the solution for Y = some random whole number n for free, what is the solution for n + 1? In other words, if I tell you that the solution for X = 5, Y = 3 is { { ... }, { ... }, ... }, can you easily figure out the solution for X = 5, Y = 3 + 1 = 4?

Here is an example for a totally different problem:

Lets say you know the first previous two Fibonacci numbers are 1 and 1. Then finding the next one is easy, right? it's 2. Now lets say you know the previous two are 1 and 2, the next one is 3! If the previous two are 2 and 3, the next one is 5!

Some pseudocode:

public int fib(int stop) {
     if (stop < 2) return 1;
     return fibHelp(stop - 2, 1, 1);
}

public int fibHelp(int stop, int oneBelow, int twoBelow) {
   if (stop == 0) return oneBelow;

   return fibHelp(stop - 1, oneBelow + twoBelow, oneBelow);
}

See how fibHelp calls itself? That's recursion! Just make sure you have a stop condition (my if statement).

For your specific problem, don't return void, instead have comboNoRep return a Set<Set<Integer>>. When y=0, return a Set with one element (an empty Set). y=1, return a Set that builds a bunch of Sets by adding one element to each set in the larger set (in the case of y=1 that Set is empty, and so forth).

Use Set and not List because you want to make sure that you don't have duplicates.

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That's not just recursion, that's tail recursion. Fails if stop < 2 though (infinite recursion). –  Makoto Nov 4 '12 at 3:08
    
Makoto: it's pseudocode, he said he didn't want real code. I was just trying to show the idea. –  durron597 Nov 4 '12 at 3:09
    
Pseudocode has the fundamentals to make it translatable to actual code. Like I said, your example won't work if stop < 2. Otherwise, it's pretty spot-on. –  Makoto Nov 4 '12 at 3:10
    
Fine, I fixed it :) –  durron597 Nov 4 '12 at 3:11
    
I've added what I've gotten so far to my original question, help? –  dominicvautour Nov 4 '12 at 23:27
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You have to explore all the possible routes:

Create an empty list of "solutions"

For every card a, your first set of solutions start by having the card in each envelope - x*y solutions

For each card you picked: repeat, from the same set of cards removing the one you used until you run out of cards when you do your solution is completed and you put it in the array

print the array

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I've added what I've gotten so far to my original question, help? –  dominicvautour Nov 4 '12 at 23:27
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For problem one, imagine your cards are named card_1 to card_x. Observe that every possible way to fill Y envelopes either includes card_1 or doesn't. If it does, you've reduced the problem to filling Y-1 envelopes with cards 2 through X; if it doesn't you've reduced the problem to filling Y envelopes with cards 2 through X.

Hopefully that's enough of a hint to help you out without being too much. Good luck!

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I've added what I've gotten so far to my original question, help? –  dominicvautour Nov 4 '12 at 23:28
    
You're confusing yourself by trying to fall back on for loops. Do not use loops at all, process all your data using recursive calls only. (Note: you will need to add some extra arguments to your function to keep track of some bookkeep-ey type things, like which cards you're allowed to use in subsequent recursive calls and which cards have already been selected.) –  jacobm Nov 5 '12 at 3:47
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You can use the Exeter Algorithm for the first Part. Refer below link for more information:

Visit Here: http://www.bearcave.com/random_hacks/permute.html

I don't know how to do it in JAVA but a snippet from my old C code may serve the purpose.

#include <stdio.h>

//Print Function
void print(const int *arr, const int size)
{
    int i;

    if (arr != 0) 
    {
        for (i = 0; i < size; i++)
            printf("%d ", arr[i]);
        printf("\n");
    }
}

//Permute Function
void permute(int *arr, const int start, const int sets, const int len)
{  
    int i,tmp;

    if (start == sets-1)
        print(arr, sets);
    else
    {
        for (i = start; i < len; i++)
        {
            tmp = arr[i];

            arr[i] = arr[start];
            arr[start] = tmp;

            permute(arr, start+1, sets, len);   //<-- Recursion

            arr[start] = arr[i];
            arr[i] = tmp;
        }
    }
}

int main()
{
  int sets,arr[] = {1, 2, 3, 4, 5};

  //Accept Number Of Sets To Form
  printf("Enter Number Of Sets: ");
  scanf("%d",&sets);

  //Call Permute Function
  permute(arr, 0, sets, sizeof(arr)/sizeof(int));

  return 0;
}
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