I figured it out in two stages:

(defn unit [v s]
(fn [] [v s]))
(defn bind [mv f]
(let [[iv is] (mv)
[av as] (f iv)]
(unit av (str is " " as))))
(defn inc+ [mv]
(bind
mv
(fn [v]
[(inc v) (str " inc+(" (inc v) ")")])))
(defn double+ [mv]
(bind
mv
(fn [v]
[(inc v) (str " double+(" (inc v) ")")])))
(defn triple+ [mv]
(bind
mv
(fn [v]
[(inc v) (str " triple+(" (inc v) ")")])))

then:

(defn unit [v s]
(fn [] [v s]))
(defn bind [mv f]
(let [[v s] (mv)
r (f v)
xs (->> (str (type f))
(re-find #"\$([^\$]*)\$?")
second) ]
(unit r (str s " " (str xs "(" r ")")))))
(defn inc+ [mv]
(bind mv inc))
(defn double+ [mv]
(bind mv #(* 2 %)))
(defn triple+ [mv]
(bind mv #(* 3 %)))
((-> (unit 3 "3 ->") inc+ double+ inc+ triple+))
;;=> [27 "3 -> inc_PLUS_(4) double_PLUS_(8) inc_PLUS_(9) triple_PLUS_(27)"]

So looking at other Monad tutorials, especially http://channel9.msdn.com/Shows/Going+Deep/Brian-Beckman-Dont-fear-the-Monads, I think I understand the core principles now. 'Monads' really is all about being able to reuse the functions we have on hand. `unit`

and `bind`

have to be designed to work together. Then, its almost quite trivial to compose together functions.

Then one more abstraction to write the `do-m`

operator:

(defn unit [v s]
(fn [] [v s]))
(defn bind [mv f]
(let [[v s] (mv)
r (f v)
xs (->> (str (type f))
(re-find #"\$([^\$]*)\$?")
second) ]
(unit r (str s " " (str xs "(" r ")")))))
(defn double [v] (* 2 v))
(defn triple [v] (* 3 v))
(defn do-m [v & fs]
(let [fn-ms (map #(fn [mv] (bind mv %)) fs)]
(((apply comp (reverse fn-ms)) (unit v (str v "->"))))))
(do-m 3 inc double triple)
;;=> [24 "3 -> inc(4) double(8) triple(24)"]

This is another way to write achieve the same result, notice that the change was to take out the lambda function in `unit`

and the associated calls for `bind`

and `do-m`

.

(defn unit [v s] [v s])
(defn bind [mv f]
(let [[v s] mv
r (f v)
xs (->> (str (type f))
(re-find #"\$([^\$]*)\$?")
second) ]
(unit r (str s " " (str xs "(" r ")")))))
(defn double [v] (* 2 v))
(defn triple [v] (* 3 v))
(defn sqrt [v] (Math/sqrt v))
(defn do-m [v & fs]
(let [fn-ms (map #(fn [mv] (bind mv %)) fs)]
((apply comp (reverse fn-ms)) (unit v (str v " ->")))))
(do-m 3 inc double double triple triple sqrt)
;; => [12.0 "3 -> inc(4) double(8) double(16) triple(48) triple(144) sqrt(12.0)"]