Say I have the following Haskell tree type, where "State" is a simple wrapper:

``````data Tree a = Branch (State a) [Tree a]
| Leaf   (State a)
deriving (Eq, Show)
``````

I also have a function "expand :: Tree a -> Tree a" which takes a leaf node, and expands it into a branch, or takes a branch and returns it unaltered. This tree type represents an N-ary search-tree.

Searching depth-first is a waste, as the search-space is obviously infinite, as I can easily keep on expanding the search-space with the use of expand on all the tree's leaf nodes, and the chances of accidentally missing the goal-state is huge... thus the only solution is a breadth-first search, implemented pretty decent over here, which will find the solution if it's there.

What I want to generate, though, is the tree traversed up to finding the solution. This is a problem because I only know how to do this depth-first, which could be done by simply called the "expand" function again and again upon the first child node... until a goal-state is found. (This would really not generate anything other then a really uncomfortable list.)

Could anyone give me any hints on how to do this (or an entire algorithm), or a verdict on whether or not it's possible with a decent complexity? (Or any sources on this, because I found rather few.)

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As an aside, you might want to use something other than `State` there, since that name is used in the standard libraries for the State monad, which is liable to confuse people. –  C. A. McCann May 15 '10 at 4:38
I realized that just now as I was using the State monad to implement my algorithm, based on the advice given here. –  pepijn May 15 '10 at 23:31

Have you looked at Chris Okasaki's "Breadth-First Numbering: Lessons from a Small Exercise in Algorithm Design"? The `Data.Tree` module includes a monadic tree builder named `unfoldTreeM_BF` that uses an algorithm adapted from that paper.

Here's an example that I think corresponds to what you're doing:

Suppose I want to search an infinite binary tree of strings where all the left children are the parent string plus "a", and the right children are the parent plus "bb". I could use `unfoldTreeM_BF` to search the tree breadth-first and return the searched tree up to the solution:

``````import Control.Monad.State
import Data.Tree

children :: String -> [String]
children x = [x ++ "a", x ++ "bb"]

expand query x = do
found <- get
if found
then return (x, [])
else do
let (before, after) = break (==query) \$ children x
if null after
then return (x, before)
else do
put True
return (x, before ++ [head after])

searchBF query = (evalState \$ unfoldTreeM_BF (expand query) []) False

printSearchBF = drawTree . searchBF
``````

This isn't terribly pretty, but it works. If I search for "aabb" I get exactly what I want:

``````|
+- a
|  |
|  +- aa
|  |  |
|  |  +- aaa
|  |  |
|  |  `- aabb
|  |
|  `- abb
|
`- bb
|
+- bba
|
`- bbbb
``````

If this is the kind of thing you're describing, it shouldn't be hard to adapt for your tree type.

UPDATE: Here's a do-free version of `expand`, in case you're into this kind of thing:

``````expand q x = liftM ((,) x) \$ get >>= expandChildren
where
checkChildren (before, [])  = return before
checkChildren (before, t:_) = put True >> return (before ++ [t])

expandChildren True  = return []
expandChildren _     = checkChildren \$ break (==q) \$ children x
``````

(Thanks to camccann for prodding me away from old control structure habits. I hope this version is more acceptable.)

-
Dear god, that code, it... I... but... what are you doing to that poor State monad? You monster! –  C. A. McCann May 15 '10 at 4:28
Yeah, it's ugly, but it was off the top of my head. How would you do it? I'll admit that I'm a beginner, but I don't see a way to tell unfoldTreeM_BF to stop expanding children without State. –  Travis Brown May 15 '10 at 4:34
Okay I fixed the silly thing I was doing with the query in State, but I still think I need it for knowing when to stop. Isn't this exactly why the tree builder is monadic in the first place? –  Travis Brown May 15 '10 at 4:42
Yeah, I think that's pretty much how `unfoldTreeM_BF` is designed to work--it's more that this is a case where using `State` is actually less readable than explicit state parameters would be, to my eye. I'd probably trim out some of the superfluous `do` cruft and move things around a bit, but without fundamentally changing the algorithm that'd be about all. –  C. A. McCann May 15 '10 at 4:48
Thank you, this was exactly what I was looking for! For the record, yes, what I wanted was "the examined tree up to the point that the solution is found" -- the reason being that I implemented breadth-first, best-first and A*-search, and wanted a simple method for examining the paths the algorithms examine. I was also, and still am, slightly frustrated at not being able to come up with this myself. –  pepijn May 15 '10 at 23:30

I'm curious why you need the `expand` function at all--why not simply construct the entire tree recursively and perform whatever search you want?

If you're using `expand` in order to track which nodes are examined by the search, building a list as you go seems simpler, or even a second tree structure.

Here's a quick example that just returns the first result it finds, with the spurious `Leaf` constructor removed:

``````data State a = State { getState :: a } deriving (Eq, Show)

data Tree a = Branch {
state :: State a,
children :: [Tree a]
} deriving (Eq, Show)

breadth ts = map (getState . state) ts ++ breadth (concatMap children ts)

mkTree n = Branch (State n) (map mkTree [n, 2*n .. n*n])

testTree = mkTree 2
``````

Trying it out in GHCi:

``````> search (== 24) testTree
24
``````

For contrast, here's a naive depth-first search:

``````depth (Branch (State x) ts) = x : (concatMap depth ts)
dSearch f t = head \$ filter f (depth t)
``````

...which of course fails to terminate when searching with `(== 24)`, because the left-most branches are an endless series of 2s.

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Just to spell it out: The "trick" to doing breadth-first search functionally is to iterate over a list of trees, not a single tree. It might be useful to add type annotations to the top level functions breadth and search here. –  MtnViewMark May 15 '10 at 16:13
I understand how this level-oriented solution works for BF traversal, but what Dennetik wants is the examined tree up to the point that the solution is found. This seems roughly equivalent to BF numbering, and it's my understanding that level-oriented approaches aren't easy to extend to numbering, while Okasaki's queue-based approach is. That's why I used `unfoldTreeM_BF` in my answer. Am I missing something? Can you expand on how to recover the examined tree with your approach? –  Travis Brown May 15 '10 at 16:52
I was using the "expand" function because I have been working with Java for way too long now, and forgot that I could count on lazy evaluation for working on infinite trees. Thanks for reminding me -- as this is what I gather your code does? (Or I'm being plain silly.) –  pepijn May 15 '10 at 23:34
@Travis Brown: No, you're correct--extending my simplistic traversal to extract the examined tree would complicate it substantially, likely involving a state parameter threaded through each call, i.e., the State monad or something like it. Far be it from me to argue with Okasaki! –  C. A. McCann May 15 '10 at 23:59
@Dennetik: Yep, my code defines an infinite lazy tree, then traverses it. Only nodes that are visited get evaluated. This is Haskell, might as well make laziness work for you! Try playing with it if you like; though it seems that Travis Brown's answer does what you actually needed. –  C. A. McCann May 16 '10 at 0:03