I'm starting out learning Clojure, and was trying to implement some basic numerical derivative functions for practice. I'm trying to create a `gradient`

function that accepts an n-variable function and the points at which to evaluate it. To do this in a "functional" style, I want to implement the gradient as a `map`

of a 1-variable derivatives.

The 1-variable derivative function is simple:

```
(defn derivative
"Numerical derivative of a univariate function."
[f x]
(let [eps 10e-6] ; Fix epsilon, just for starters.
; Centered derivative is [f(x+e) - f(x-e)] / (2e)
(/ (- (f (+ x eps)) (f (- x eps))) (* 2 eps))))
```

I'd like to design the gradient along these lines:

```
(defn gradient
"Numerical gradient of a multivariate function."
[f & x]
(let [varity-index (range (count x))
univariate-in-i (fn [i] (_?_))] ; Creates a univariate fn
; of x_i (other x's fixed)
;; For each i = 0, ... n-1:
;; (1) Get univariate function of x_i
;; (2) Take derivative of that function
;; Gradient is sequence of those univariate derivatives.
(map derivative (map univariate-in-i varity-index) x)))
```

So, `gradient`

has variable arity (can accept any # of x's), and the order of the x's counts. The function `univariate-in-i`

takes an index `i = 0, 1, ... n-1`

and returns a 1-variable function by partial-ing out all the variables except `x_i`

. E.g., you'd get:

```
#(f x_0 x_1 ... x_i-1 % x_i+1 ... x_n)
^
(x_i still variable)
```

`map`

-ping this function over `varity-index`

gets you a sequence of 1-variable functions in each `x_i`

, and then `map`

-ping `derivative`

over these gets you a sequence of derivatives in each `x_i`

which is the gradient we want.

My questions is: I'm not sure what a good way to implement `univariate-in-i`

is. I essentially need to fill in values for x's in `f`

except at some particular spot (i.e., place the `%`

above), but programmatically.

I'm more interested in technique than solution (i.e., I know how to compute gradients, I'm trying to learn functional programming and idiomatic Clojure). Therefore, I'd like to stay true to the strategy of treating the gradient as a map of 1-d derivatives over partialed-out functions. But if there's a better "functional" approach to this, please let me know. I'd rather not resort to macros if possible.

Thanks in advance!

**Update:**

Using Ankur's answer below, the gradient function I get is:

```
(defn gradient
"Numerical gradient of a multivariate function."
[f & x]
(let [varity-index (range (count x))
x-vec (vec x)
univariate-in-i
(fn [i] #(->> (assoc x-vec i %) (apply f)))]
(map derivative (map univariate-in-i varity-index) x)))
```

which does exactly what I'd hoped, and seems very concise and functional.