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62 lines
1.9 KiB
Markdown
62 lines
1.9 KiB
Markdown
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# Backtracking
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This algorithm tries to construct a solution to a problem one piece at a time. Whenever the algorithm needs to decide between multiple alternatives to the part of the solution it *recursively* evaluates every option and chooses the best one.
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## How to Win
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To beat any *non-random perfect information* game you can define a Backtracking algorithm that only needs to know the following.
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- A game state is good if either the current player has already won or if the current player can move to a bad state for the opposing player.
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- A game state is bad if either the current player has already lost or if every available move leads to a good state for the opposing player.
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```
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PlayAnyGame(X, player)
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if player has already won in state X
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return GOOD
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if player has lost in state X
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return BAD
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for all legal moves X -> Y
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if PlayAnyGame(y, other player) = Bad
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return GOOD
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return BAD
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```
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In practice, most problems have an enormous number of states not making it possible to traverse the entire game tree.
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## Subset Sum
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For a given set, can you find a subset that sums to a certain value?
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```
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SubsetSum(X, T):
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if T = 0
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return True
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else if T < 0 or X is empty
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return False
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else
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x = any element of X
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with = SubsetSum(X \ {x}, T - x)
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without = SubsetSum(X \ {x}, T)
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return (with or without)
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```
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X \ {x} denotes set subtraction. It means X without x.
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```
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ConstructSubset(X, i, T):
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if T = 0
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return empty set
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if T < 0 or n = 0
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return None
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Y = ConstructSubset(X, i - 1, T)
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if Y does not equal None
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return Y
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Y = ConstructSubset(X, i - 1, T - X[i])
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if Y does not equal None
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return Y with X[i]
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return None
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```
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## Big Idea
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Backtracking algorithms are used to make a *sequence of decisions*.
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When we design a new recursive backtracking algorithm, we must figure out in advance what information we will need about past decisions in the middle of the algorithm.
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