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Here is my problem. Imagine I am buying 3 different items, and I have up to 5 coupons. The coupons are interchangeable, but worth different amounts when used on different items.

Here is the matrix which gives the result of spending different numbers of coupons on different items:

coupons:    1         2         3         4         5
item 1      $10 off   $15 off
item 2                $5 off    $15 off   $25 off   $35 off
item 3      $2 off

I have manually worked out the best actions for this example:

  • If I have 1 coupon, item 1 gets it for $10 off
  • If I have 2 coupons, item 1 gets them for $15 off
  • If I have 3 coupons, item 1 gets 2, and item 3 gets 1, for $17 off
  • If I have 4 coupons, then either:
    • Item 1 gets 1 and item 2 gets 3 for a total of $25 off, or
    • Item 2 gets all 4 for $25 off.
  • If I have 5 coupons, then item 2 gets all 5 for $35 off.

However, I need to develop a general algorithm which will handle different matrices and any number of items and coupons.

I suspect I will need to iterate through every possible combination to find the best price for n coupons. Does anyone here have any ideas?

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oops, thanks jimmy. –  Blorgbeard Jan 8 '09 at 22:05
1  
Also, if you have 5 coupons, item 1 gets 1 and item 2 gets 4 for a total of $35 off. –  Niko Nyman Jan 8 '09 at 22:46
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6 Answers 6

up vote 4 down vote accepted

This seems like a good candidate for dynamic programming:

//int[,] discountTable = new int[NumItems][NumCoupons+1]

// bestDiscount[i][c] means the best discount if you can spend c coupons on items 0..i
int[,] bestDiscount = new int[NumItems][NumCoupons+1];

// the best discount for a set of one item is just use the all of the coupons on it
for (int c=1; c<=MaxNumCoupons; c++)
    bestDiscount[0, c] = discountTable[0, c];

// the best discount for [i, c] is spending x coupons on items 0..i-1, and c-x coupons on item i
for (int i=1; i<NumItems; i++)
    for (int c=1; c<=NumCoupons; c++)
        for (int x=0; x<c; x++)
            bestDiscount[i, c] = Math.Max(bestDiscount[i, c], bestDiscount[i-1, x] + discountTable[i, c-x]);

At the end of this, the best discount will be the highest value of bestDiscount[NumItems][x]. To rebuild the tree, follow the graph backwards:

edit to add algorithm:

//int couponsLeft;

for (int i=NumItems-1; i>=0; i++)
{
    int bestSpend = 0;
    for (int c=1; c<=couponsLeft; c++)
        if (bestDiscount[i, couponsLeft - c] > bestDiscount[i, couponsLeft - bestSpend])
            bestSpend = c;

    if (i == NumItems - 1)
        Console.WriteLine("Had {0} coupons left over", bestSpend);
    else
        Console.WriteLine("Spent {0} coupons on item {1}", bestSpend, i+1);

    couponsLeft -= bestSpend;
}
Console.WriteLine("Spent {0} coupons on item 0", couponsLeft);

Storing the graph in your data structure is also a good way, but that was the way I had thought of.

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Can you expand on "To rebuild the tree, follow the graph backwards"? I like the look of your approach, but I'm having trouble figuring out how best to save the actual distribution of coupons for the best discount value. –  Blorgbeard Jan 9 '09 at 2:28
    
Hmm. Also, shouldn't that last term be "discountTable[i, c-x]" ? –  Blorgbeard Jan 9 '09 at 2:45
    
I went with this approach, changing bestDiscount from a simple int to a class which holds the value and the coupon distribution used to get to it. –  Blorgbeard Jan 9 '09 at 9:51
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It's the Knapsack problem, or rather a variation of it. Doing some research on algorithms related to this problem will point you in the best direction.

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I agree. This smells like some kind of dynamic programming problem... –  Mr. Brownstone Jan 8 '09 at 22:15
    
This can be written as a knapsack problem, but it has such a simple structure that there are much easier ways to solve it. –  David Norman Jan 8 '09 at 22:21
    
Just out of curiousity, does anyone have a sketch of a reduction to the Knapsack problem? –  Jimmy Jan 8 '09 at 22:43
    
Thanks, I suspected it was close to a common problem of some kind. –  Blorgbeard Jan 9 '09 at 9:52
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I think dynamic programming should do this. Basically, you keep track of an array A[n, c] whose values mean the optimal discount while buying the n first items having spent c coupons. The values for a[n, 0] should be 0 for all values of n, so that is a good start. Also, A[0, c] is 0 for all c.

When you evaluate A[n,c], you loop over all discount offers for item n, and add the discount for that particular offer to A[n-1,c-p] where p is the price in coupons for this particular discount. A[n-1, c-p] must of course be calculated (in the same way) prior to this. Keep the best combination and store in the array.

A recursive implementation would probably give the cleanest implementation. In that case, you should find the answer in A[N,C] where N is the total number of items and C is the total number of available coupons.

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isn't it O(n*c^2)? See my implementation below. –  FryGuy Jan 8 '09 at 22:40
    
Yes, if the matrix is dense, it will be O(n*c^2). If you represent the available discount offers in lists, one list for each item, you can get better performance for sparse arrays. With an average list length of L, the total complexity should be O(n*c*L) –  norheim.se Jan 9 '09 at 8:27
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This can be written as a linear programming problem. For most 'typical' problems, the simplex method is a fast, relatively simple way to solve such problems, or there are open source LP solvers available.

For your example:

Let 0 <= xi <= 1

  • x1 = One if one coupon is spent on item 1, zero otherwise
  • x2 = One if two coupons are spent on item 1, zero otherwise
  • x3 = One if one coupon is spent on item 2, zero otherwise
  • x4 = One if two coupons are spent on item 2, zero otherwise
  • x5 = One if three coupons are spent on item 3, zero otherwise
  • ...

Assume that if I spend two coupons on item 1, then both x1 and x2 are one. This implies the constraint

  • x1 >= x2

With similar constraints for the other items, e.g.,

  • x3 >= x4
  • x4 >= x5

The amount saved is

  • Saved = 10 x1 + 5 x2 + 0 x3 + 5 x4 + 10 x5 + ...

If you want to find the most money saved with a fixed number of coupons, then you want to minimize Saved subject to the constraints above and the additional constraint:

  • coupon count = x1 + x2 + x3 + ...

This works for any matrix and number of items. Changing notation (and feeling sad that I can't do subscripts), let *0 <= y_ij <= 1* be one if j coupons are spent on item number i. The we have the constraints

  • *y_i(j-1) >= y_ij*

If the amount saved from spending j coupons on item i is *M_ij*, where we define *M_i0 = 0*, then maximize

  • *Saved = Sum_ij (M_ij - M_i(j-1)) y_ij*

subject to the above constraints and

  • *coupon count = Sum_ij y_ij*

(The italics formatting doesn't seem to be working here)

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I'd agree with you had he not included the following statement: "I need to develop a general algorithm which will handle different matrices and any number of items and coupons." –  Gavin Miller Jan 8 '09 at 22:26
    
So you have a program take the matrices and such and set up the LP problem. No big deal. LP solvers are designed so you can feed them different problems easily. –  David Thornley Jan 8 '09 at 22:33
    
Ahh very cool, I was not familiar with LP solvers. –  Gavin Miller Jan 8 '09 at 22:39
    
This seems pretty complicated, when there are simpler solutions available. –  FryGuy Jan 8 '09 at 22:47
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I suspect some kind of sorted list for memoizing each coupon-count can help here.

for example, if you have 4 coupons, the optimum is possibly:

  1. using all 4 on something. You have to check all these new prices.
  2. using 3 and 1. either the 3-item is the optimal solution for 3 coupons, or that item overlaps with the three top choices for 1-coupon items, in which case you need to find the best combination of one of the three best 1-coupon and 3-coupon items.
  3. using 2 and 2. find top 3 2-items. if #1 and #2 overlap, #1 and #3 , unless they also overlap, in which case #2 and #3 don't.

this answer is pretty vague.. I need to put more thought into it.

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This wouldn't work very well to memoize it in this manner, as you'd have to do a lot of rechecking when things overlap. –  FryGuy Jan 8 '09 at 22:52
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This problem is similar in concept to the Traveling Salesman problem where O(n!) is the best for finding the optimal solution. There are several shortcuts that can be taken but they required lots and lots of time to discover, which I doubt you have.

Checking each possible combination is going to be the best use of your time, assuming we are dealing with small numbers of coupons. Make the client wait a bit instead of you spending years on it.

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TSP is not O(n!). And this is not a TSP problem. Dynamic programming gets you a pseudo-P solution to Knapsack problem. –  segfault Mar 5 '13 at 16:34
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