# Appropriate representation of a 2D game board in Clojure

I'm working on a small game in Clojure as a learning exercise. I think I've settled on a representation of the game state at any particular time as a list of "movables" and a 2D vector-of-vectors for the "terrain" (board squares).

95% of the time I expect to be checking for a collision in a particular square for which the 2D vector seems appropriate. But in a few cases, I need to go the other direction -- find the (x,y) location of a cell that matches some criteria. First attempt was something like this:

(defn find-cell-row [fn row x y]
(if (empty? row) nil
(if (fn (first row)) [x y]
(find-cell-row fn (rest row) (inc x) y))))

(defn find-cell [fn grid y]
(if (empty? grid) nil
(or (find-cell-row fn (first grid) 0 y)
(find-cell (rest grid) (inc y)))))

(def sample [[\a \b \c][\d \e \f]])
(find-cell #(= % \c) sample 0) ;; => [2 0]


I tried something more concise with map-indexed, but it got ugly quickly and still didn't give me quite what I wanted. Is there a more idiomatic way to do this search, or perhaps I would be better served with a different data structure? Maybe a map { [x y] -> cell }? Using a map to represent a matrix feels so wrong to me :)

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You could use a Map however one of the advantages of using say an immutable data structure like cons-cell is that it makes it easy to do a MINI-MAX (en.wikipedia.org/wiki/Minimax) like algorithm since any operation will essentially clone the board. On the other hand I find car/consing through cells annoying and usually resort to some indexed structure (array or map). –  Adam Gent Apr 17 '12 at 21:28
It looks like Clojure has nice support for "editing" a cell (i.e., creating a new immutable structure with the value changed) with assoc-in. No AI in this game, but I do want to be able to "rewind" to a previous time so the immutable structs are really handy. –  kyle_wm Apr 17 '12 at 21:58
not sure what you mean about assoc-in, but "ordinary" maps in clojure are implemented as functional (immutable) trees, so when you modify a map you get a new instance that shares much structure with previous instances. i used map {[x y] -> cell} for a structure in a dfs and it worked fine. however, it felt very "odd" so i am bookmarking this question to see if there is anything better... –  andrew cooke Apr 17 '12 at 22:23
clojuredocs.org/clojure_core/clojure.core/assoc-in. so I can call (assoc-in sample [0 2] \z) to create a copy of sample with the \c changed to a \z. Thanks both of you for the feedback. –  kyle_wm Apr 17 '12 at 22:48
assoc-in allows a path into a nested data structure. It will create missing intermediate nodes on the fly, so (assoc-in {} [:a :b :c] 3) => {:a {:b {:c 3}}} –  sw1nn Apr 17 '12 at 23:49

A nested vector is pretty normal for this sort of thing, and it's neither hard nor ugly to scan through one if you use a for comprehension:

(let [h 5, w 10]
(first
(for [y (range h), x (range w)
:let [coords [y x]]
:when (f (get-in board coords))]
coords)))

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Brilliant, thank you. Playing with that just a little I think I've got a solution I'm really happy with (defn find-cell [pred s] (first (for [[y row] (map-indexed vector s) [x cell] (map-indexed vector row) :when (pred cell)] [x y]))) This language is so dang fun –  kyle_wm Apr 18 '12 at 1:03
I assume you're doing these map-indexed things for efficiency or something? I really recommend you profile or benchmark before you make your code more complicated in order to gain speed - I'm pretty sure newing up all those temporary collections costs a lot more than indexing into a vector. –  amalloy Apr 18 '12 at 1:29
Not at all... Just personal preference. I use Iterables instead of for(int i = 0...) in Java too. –  kyle_wm Apr 18 '12 at 4:34

How about using a plain vector then all the 'usual' functions are available to you and you can extract [x y] as necessary.

(def height 3)
(def width 3)

(def s [\a \b \c \d \e \f \g \h \i])

(defn ->xy [i]
[(mod i height) (int (/ i height))])

(defn find-cell
"returns a vector of the [x y] co-ords of cell when
pred is true"
[pred s]
(let [i (first (keep-indexed #(when (pred %2) %1) s))]
(->xy i)))

(find-cell #(= \h %) s)
;=> [1 2]

(defn update-cells
"returns an updated sequence s where value at index i
is replaced with v. Allows multiple [i v] pairs"
[s i v & ivs]
(apply assoc s i v ivs))

(update-cells s 1 \z)
;=> [\a \z \c \d \e \f \g \h \i]

(update-cells s 1 \p 3 \w)
;=> [\a \p \c \w \e \f \g \h \i]

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any idea how this compares to maps for data sharing with copies? if you're making lots of small changes in a process that might backtrack which is more memory-efficient? i suspect both chunk things in groups of 32, but don't have any numbers. –  andrew cooke Apr 17 '12 at 23:44
structural sharing applies across all the persistent data structures AFAIK, not sure about low-level details for vector vs map. Other benefit is that indexed access to vector is optimized –  sw1nn Apr 17 '12 at 23:47
Thanks! That makes a lot of sense, and I've learned a couple additional things looking at your example :) –  kyle_wm Apr 18 '12 at 0:07
No problem. See stackoverflow.com/questions/6016271/… for further rationale about using the simple data structures... –  sw1nn Apr 18 '12 at 0:17