# NP-complete knapsack

I saw this ECLiPSe solution to the problem mentioned in this XKCD comic. I tried to convert this to pure Prolog.

``````go:-
Total = 1505,
Prices = [215, 275, 335, 355, 420, 580],
length(Prices, N),
length(Amounts, N),
totalCost(Prices, Amounts, 0, Total),
writeln(Total).

totalCost([], [], TotalSoFar, TotalSoFar).
totalCost([P|Prices], [A|Amounts], TotalSoFar, EndTotal):-
between(0, 10, A),
Cost is P*A,
TotalSoFar1 is TotalSoFar + Cost,
totalCost(Prices, Amounts, TotalSoFar1, EndTotal).
``````

I don't think that this is the best / most declarative solution that one can come up with. Does anyone have any suggestions for improvement? Thanks in advance!

-
It seems efficient to work backward from the most expensive items, as these permit smaller Amount multiples to be subtracted from the budget/knapsack (less branching). A simple modification to your existing code would be to check that TotalSoFar is less than or equal to EndTotal. With this in a pencil and paper attempt, I found a solution pretty quickly. – hardmath Jun 6 '11 at 15:10

Your generate-and-test approach should be intelligible to any Prolog programmer with more than a few days experience. Here are some minor tweaks:

``````go(Amounts) :-
Prices = [580, 420, 355, 335, 275, 215],
totalCost(Prices, Amounts, 0, 1505),
write(Amounts), nl.

totalCost([], [], Total, Total).
totalCost([P|Prices], [A|Amounts], SoFar, Total):-
Upper is (Total-SoFar)//P,
between(0,Upper,A),
SoNear is SoFar + P*A,
totalCost(Prices, Amounts, SoNear, Total).
``````

I changed go/0 to go/1 so that the Prolog engine will backtrack and produce all the solutions (there are two). The calls to length/2 could be omitted because totalCost/4 does the work of building list Amounts to have equal length with Prices. I used write/1 and nl/0 to make it a little more portable.

In totalCost/4 I shortened some of the variable/argument names and indulged in a slightly jokey name for the accumulator argument. The way I imposed the check that our accumulator doesn't exceed the desired Total uses your original call to between/3 but with a computed upper bound instead of a constant. On my machine it reduced the running time from minutes to seconds.

Added: I should mention here what was said in my comment above, that the menu items are now ordered from most expensive to least. Using SWI-Prolog's time/1 predicate shows this reduces the work from 1,923 inferences to 1,070 inferences. The main improvement (in speed) comes from using computed bounds on A rather than range 0 to 10 for every item.

``````time((go(A),false)).
``````

Note the extra parentheses around the compound goal, as otherwise SWI-Prolog thinks we are calling an undefined time/2 predicate.

-

Since you mention SWI-Prolog why not

``````?- use_module(library(clpfd)).
``````
``````?- Total = 1505, Prices = [215, 275, 335, 355, 420, 580],
maplist(\P^A^M^(P*A #= M, A #>=0),Prices,Amounts,Ms), sum(Ms, #=, Total).
``````

By stating this, all variables in the list `Amounts` are in a finite range. So there is no need to "do the math" for an upper bound (which often goes wrong anyway). To see concrete solutions, labeling/2 is needed:

``````?- Total = 1505, Prices = [215, 275, 335, 355, 420, 580],
maplist(\P^A^M^(P*A #= M, A #>=0),Prices,Amounts,Ms), sum(Ms, #=, Total),
labeling([], Amounts).
Total = 1505,
Prices = [215,275,335,355,420,580],
Amounts = [1,0,0,2,0,1],
Ms = [215,0,0,710,0,580] ;
Total = 1505,
Prices = [215,275,335,355,420,580],
Amounts = [7,0,0,0,0,0],
Ms = [1505,0,0,0,0,0].
``````
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