Is there a better way to compute Cartesian product. Since Cartesian product is a special case that differs on each case. I think, I need to explain what I need to achieve and why I end up doing Cartesian product. Please help me if Cartesian product is the only solution for my problem. If so, how to improve the performance.
Background:
We are trying to help customers to buy products cheaper.
Let say customer ordered 5 products (prod1, prod2, prod3, prod4, prod5).
Each ordered product has been offered by different vendors.
Representation Format 1:
 Vendor 1  offers prod1, prod2, prod4
 vendor 2  offers prod1, prod5
 vendor 3  offers prod1, prod2, prod5
 vendor 4  offers prod1
 vendor 5  offers prod2
 vendor 6  offers prod3, prod4
In other words
Representation Format 2:
 Prod 1  offered by vendor1, vendor2, vendor3, vendor4
 Prod 2  offered by vendor5, vendor3, vendor1
 prod 3  offered by vendor6
 prod 4  offered by vendor1, vendor6
 prod 5  offered by vendor3, vendor2
Now to choose the best vendor based on the price. We can sort the products by price and take the first one.
In that case we choose
 prod 1 from vendor 1
 prod 2 from vendor 5
 prod 3 from vendor 6
 prod 4 from vendor 1
 prod 5 from vendor 3
Complexity:
Since we chose 4 unique vendors, we need to pay 4 shipping prices.
Also each vendor has a minimum purchase order. If we don't meet it, then we end up paying that charge as well.
In order to choose the best combination of products, we have to do Cartesian product of offered products to compute the total price.
total price computation algorithm:
foreach unique vendor
if (sum (product price offered by specific vendor * quantity) < minimum purchase order limit specified by specific vendor)
totalprice += sum (product price * quantity) + minimum purchase charge + shipping price
else
totalprice += sum (product price * quantity) + shipping price
end foreach
In our case
 {vendor1, vendor2, vendor3, vendor4}
 {vendor1, vendor3, vendor5}
 {vendor6}
 {vendor1, vendor6}
 {vendor2, vendor3}
4 * 3 * 1 * 2 * 2 = 48 combination needs to be computed to find the best combination.
 {vendor1,vendor1, vendor6, vendor1, vendor2} = totalprice1,
 {vendor1, vendor3, vendor6, vendor1, vendor2} = totalprice2,


*
 {vendor4, vendor5, vendor6, vendor6, vendor3} = totalprice48
Now sort the computed total price to find the best combination.
Actual Problem:
If the customer orders more than 15 products, and assume, each product has been offered by 8 unique vendors, then we end up computing 8^15=35184372088832 combinations, which takes more than couple of hours. If the customer orders more than 20 products then it takes more than couple of days.
Is there a solution to approach this problem in a different angle.
Thanks, Esen