I have been trying to think how to implement an algorithm to compute the winding number of a polygon with respect to a point. Currently the implementation is as follows: (note updated so code works)

```
(defn winding-num
"Return winding number of polygon
see Alciatore "
[poly point]
; translate poly such that point is at origin
(let [translated-poly (map #(vec-f - % point) poly)]
; w is wind-num
(loop [vertices translated-poly w 0]
(cond
(= (count vertices) 1)
w
:else
(let [x1 (first (first vertices))
x2 (first (second vertices))
y1 (second (first vertices))
y2 (second (second vertices))]
(cond
(and (< (* y1 y2) 0)
(> (+ x1 (/ (* y1 (- x2 x1))
(- y1 y2)))
0))
(if (< y1 0)
(recur (rest vertices) (inc w))
(recur (rest vertices) (dec w)))
(and (zero? y1)
(> x1 0))
(if (> y2 0)
(recur (rest vertices) (+ w 0.5))
(recur (rest vertices) (- w 0.5)))
(and (zero? y2)
(> x2 0))
(if (< y1 0)
(recur (rest vertices) (+ w 0.5))
(recur (rest vertices) (- w 0.5)))
:else
(recur (rest vertices) w)))))))
```

My problems with this are

- People say it's preferable when possible to use looping constructs which operate at a higher level than explicit recursion; for instance
`map`

,`for`

,`reduce`

, etc. - The rest function converts the vector into a list

I could think of an implementation using `for`

and indices, but I also hear it is preferable to not use indices.

Is there an idiomatic way for dealing with vector algorithms which in each iteration need access to consecutive values?

`vec-f`

? – Francis Avila Apr 30 '13 at 3:17