# How to handle multiple variables in a Clojure algorithm implementation?

I'm new to Clojure and trying to learn by implementing some algorithms in it. The algorithm I'm writing is for calculating the node `betweenness centrality` metric for a graph data structure.

The function in the algorithm (Brandes algorithm) I'm trying to implement goes like this:

Here, `V` are the vertex of the graph and `s` is the starting node from which we are trying to calculate and return the shortest path metrics `S, Pred and sigma`

This is what I have managed to come up by using loom to create the initial graph `g` for each starting node `start`:

`````` (defn ss-shortest-path
[g start]
(let [nodeset (disj (nodes g) start)
pred (apply assoc {} (interleave (nodes g) (repeat nil)))
dist (apply assoc {start 0} (interleave nodeset (repeat -1)))
sigma (apply assoc {start 1} (interleave nodeset (repeat 0)))
stack []]
(loop [queue (conj clojure.lang.PersistentQueue/EMPTY start)]
(if (empty? queue)
{:sigma sigma
:pred pred
:stack stack}
(let [v (peek queue)
stack (conj stack v)]
(doseq [w (successors g v)]
(when (= (dist w) -1)
(do
(conj queue w)
(assoc dist w (+ 1 (dist v)))))
(when (= (dist w) (+ 1 (dist v)))
(do
(assoc sigma w (+ (sigma w) (sigma v)))
(assoc pred w v))))
(recur (pop queue)))))))
``````

I know that Clojure data structures are immutable so each time I call `conj` or `assoc` in the variables `pred, sigma, stack, dist` a new copy is created and the original variables remain as they are.

But, I don't want to use mutable states like `atoms`, `refs`, as I have a feeling that'd be simply copying the imperative style that I already know.

So, I'm seeking the help of some experienced Clojurists to help me create this function in an idiomatic style.

There are two main things I would do: First, the algorithm has a state consisting of multiple "variables" (`queue`, `stack`, etc.). I would first construct a function that represents the algorithmic state using an immutable map, like

``````(defn initialize-state [g start]
(let [nodeset (disj (nodes g) start)]
{:g g
:nodeset nodeset
:pred (apply assoc {} (interleave (nodes g) (repeat nil)))
:dist (apply assoc {start 0} (interleave nodeset (repeat -1)))
:sigma (apply assoc {start 1} (interleave nodeset (repeat 0)))
:stack []
:queue (conj clojure.lang.PersistentQueue/EMPTY start)
:current-vertex nil}))
``````

I would then, in the REPL, test that this map is initialized properly for various choices of `g` and `start`.

Second, I would break down the algorithm into multiple small functions that take a state as input and returns a state as output, like this (this code will not work, you have to fill in the missing parts):

``````(defn next-vertex [state]
{:pre [(state? state)]
:post [(state? %)]}
(let [v (peek (:queue state))]
(-> state
(update :stack conj v)
(assoc :current-vertex v))))

(defn process-successor [state w]
(let [dist-w (dist w)]
(cond
;; fill in...
)))

(defn process-successors [state]
{:pre [(state? state)]
:post [(state? %)]}
(reduce
process-successor
state
(successors (:g state) (:current-vertex state))))

(defn pop-queue [state]
{:pre [(state? state)]
:post [(state? %)]}
(update state :queue pop))
``````

The maps with `:pre` and `:post` keys are so called pre- and post conditions, and the `state?`-function could be implemented, for instance, as `(defn state? [x] (and (map? x) (contains? x :queue)))`, just as a sanity check.

Note that for every function you write, you can test it in the REPL with some data to make sure that it works, before writing the next function. All these functions can now be wrapped together into a full state transition using `comp`:

``````(def next-state (comp pop-queue process-successors next-vertex))
``````

Now the final algorithm reads something like this:

``````(defn ss-shortest-path [g start]
(loop [state (initialize-state g start)]
(if (empty? (:queue state))
state
(recur (next-state state)))))
``````

So to sum up, implementing an algorithm is a lot easier if you break it down into smaller parts that can be developed and validated individually.

• this was pretty great. exactly what I was looking for. I was able to finish the code and it worked ! just one more question though about the ":pre" and ":post" maps. what are those used for and how do I define the function "state?". would appreciate that if you could explain that a bit. thanks again for the great answer. – sfactor Oct 31 '18 at 19:37
• Glad I could help! The "{:pre ... :post ...}" are so called pre- and post-conditions, explained here: clojure.org/reference/… . And "state?" is just a function that checks that the data corresponds to our chosen representation of a "state", for instance you could implement it as (defn state? [x] (and (map? x) (contains? x :queue)). You don't have to use pre- and post-conditions, many people don't. But I have found that using assertions and pre- and post-conditions helps detecting and localizing bugs. – Rulle Oct 31 '18 at 20:39

Neither of the other answers say this explicitly, so I thought I'd clear up the "dealing with immutability" part.

I'd say that `loop` is the correct construct to use here. The problem with your set up is the only accumulator your loop has is `queue`. Every bit of data that changes from one iteration to the next should be part of the accumulators of the loop.

In your case here, `dist`, `sigma`, `pred` and `stack` are all data that has the potential to change from one loop iteration to the next, so they should all be declared in the square brackets of the loop. Then, when you need to update one of the pieces of data, you update what's given to `recur`:

``````(loop [queue (conj clojure.lang.PersistentQueue/EMPTY start)
pred (apply assoc {} (interleave (nodes g) (repeat nil)))
dist (apply assoc {start 0} (interleave nodeset (repeat -1)))
sigma (apply assoc {start 1} (interleave nodeset (repeat 0)))
stack []]

(if (empty? queue)
(Return everything)
(recur (conj queue some-data)
(assoc pred :some-key some-data)
(assoc dist :another-key other-data)
(assoc sigma :key data)
(conj stack stack-data))))
``````

Everything given to `recur` (the updated immutable structures in this case) will be what's available to `loop` on the next iteration.

I agree with @Rulle here though that you have so many accumulators, it's much neater to package them all into their own structure instead of manually dealing with the all each iteration.

Background: here is a java version of the alg: https://github.com/jgrapht/jgrapht/blob/master/jgrapht-core/src/main/java/org/jgrapht/alg/scoring/BetweennessCentrality.java

First off, You need to define s, Pred, sigma. You should also define format for g, v, start, etc.

Secondly, I'm not sure this is the best learning exercise. You could replace Java `while`, `for`, etc with Clojure `loop/recur`, `doseq`, & others, but it still feels like a "force-fit". You could probably learn a lot more a lot faster (& a lot deeper!) by reading good books like "Clojure for the Brave & True", "Getting Clojure", etc.

The idea is that small, self-contained practice problems are enormously more efficient for learning than a single gargantuan problem.