Difference between revisions of "99 questions/Solutions/81"
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| otherwise = (paths1 x b g (current++[a])) ++ (paths2 a b g current xs) |
| otherwise = (paths1 x b g (current++[a])) ++ (paths2 a b g current xs) |
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</haskell> |
</haskell> |
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| + | |||
| ⚫ | |||
| − | paths start end zs = let (xs,ys) = partition (\(_,z) -> z == end ) zs |
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| − | in map (++ [ end] ) ( concat . map (\(e, _) -> if e == start then [[start]] else paths start e ys) $ xs ) |
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This solution uses a representation of a (directed) graph as a list of arcs (a,b). |
This solution uses a representation of a (directed) graph as a list of arcs (a,b). |
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| + | |||
| + | ---- |
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| + | |||
| + | Here is another implementation using List's monadic behavior |
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| + | |||
| + | <haskell> |
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| + | import Data.List (partition) |
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| + | |||
| + | pathsImpl :: Eq a => [a] -> a -> a -> [(a, a)] -> [[a]] |
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| + | pathsImpl trail src dest clauses |
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| + | | src == dest = [src:trail] |
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| + | | otherwise = do |
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| + | let (nexts, rest) = partition ((==src) . fst) clauses |
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| + | next <- nexts |
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| + | pathsImpl (src:trail) (snd next) dest rest |
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| + | |||
| ⚫ | |||
| + | paths src dest clauses = map reverse (pathsImpl [] src dest clauses) |
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| + | </haskell> |
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| + | |||
| + | ---- |
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| + | |||
| + | Here is another recursive implementation |
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| + | <haskell> |
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| + | paths :: Eq a =>a -> a -> [(a,a)] -> [[a]] |
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| + | paths source sink edges |
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| + | | source == sink = [[sink]] |
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| + | | otherwise = [ |
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| + | source:path | edge<-edges, (fst edge) == source, |
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| + | path<-(paths (snd edge) sink [e|e<-edges, e/=edge]) |
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| + | ]; |
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| + | </haskell> |
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Revision as of 17:41, 25 April 2016
(**) Path from one node to another one
Write a function that, given two nodes a and b in a graph, returns all the acyclic paths from a to b.
import List (elem)
paths :: Eq a => a -> a -> [(a,a)] -> [[a]]
paths a b g = paths1 a b g []
paths1 :: Eq a => a -> a -> [(a,a)] -> [a] -> [[a]]
paths1 a b g current = paths2 a b g current [ y | (x,y) <- g, x == a ]
paths2 :: Eq a => a -> a -> [(a,a)] -> [a] -> [a] -> [[a]]
paths2 a b g current [] | a == b = [current++[b]]
| otherwise = []
paths2 a b g current (x:xs) | a == b = [current++[b]]
| elem a current = []
| otherwise = (paths1 x b g (current++[a])) ++ (paths2 a b g current xs)
This solution uses a representation of a (directed) graph as a list of arcs (a,b).
Here is another implementation using List's monadic behavior
import Data.List (partition)
pathsImpl :: Eq a => [a] -> a -> a -> [(a, a)] -> [[a]]
pathsImpl trail src dest clauses
| src == dest = [src:trail]
| otherwise = do
let (nexts, rest) = partition ((==src) . fst) clauses
next <- nexts
pathsImpl (src:trail) (snd next) dest rest
paths :: Eq a => a -> a -> [(a, a)] -> [[a]]
paths src dest clauses = map reverse (pathsImpl [] src dest clauses)
Here is another recursive implementation
paths :: Eq a =>a -> a -> [(a,a)] -> [[a]]
paths source sink edges
| source == sink = [[sink]]
| otherwise = [
source:path | edge<-edges, (fst edge) == source,
path<-(paths (snd edge) sink [e|e<-edges, e/=edge])
];