## TL;DR

Per the comments, a short answer; the tacit equivalent to the original, explicit `newton_i`

and `newton`

are, respectively:

```
n_i =: d.0 1 (%/@:) (]`-`) (`:6)
newton =: n_i (^:_)
```

Some techniques for how such translations are obtained, in general, can be found on the J Forums.

## Construction

The key insights here are that (a) that a function is identical to its own "zeroeth derivative", and that (b) we can calculate the "zeroeth" and first derivative of a function in J simultaneously, thanks to the language's array-oriented nature. The rest is mere stamp-collecting.

In an ideal world, given a function `f`

, we'd like to produce a verb train like `(] - f % f d. 1)`

. The problem is that tacit adverbial programming in J constrains us to produce a verb which mentions the input function (`f`

) once and only once.

So, instead, we use a sneaky trick: we calculate *two* derivatives of `f`

at the same time: the "zeroth" derivative (which is an identity function) and the first derivative.

```
load 'trig'
sin NB. Sine function (special case of the "circle functions", o.)
1&o.
sin d. 1 f. NB. First derivative of sine, sin'.
2&o.
sin d. 0 f. NB. "Zeroeth" derivative of sine, i.e. sine.
1&o."0
sin d. 0 1 f. NB. Both, resulting in two outputs.
(1&o. , 2&o.)"0
znfd =: d. 0 1 NB. Packaged up as a re-usable name.
sin znfd f.
(1&o. , 2&o.)"0
```

Then we simply insert a division between them:

```
dh =: znfd (%/@) NB. Quotient of first-derivative over 0th-derivattive
sin dh
%/@(sin d.0 1)
sin dh f.
%/@((1&o. , 2&o.)"0)
sin dh 1p1 NB. 0
_1.22465e_16
sin 1p1 NB. sin(pi) = 0
1.22465e_16
sin d. 1 ] 1p1 NB. sin'(pi) = -1
_1
sin dh 1p1 NB. sin(pi)/sin'(pi) = 0/-1 = 0
_1.22465e_16
```

The `(%/@)`

comes to the right of the `znfd`

because tacit adverbial programming in J is LIFO (i.e. left-to-right, where as "normal" J is right-to-left).

## Stamp collecting

As I said, the remaining code is mere stamp collecting, using the standard tools to construct a verb-train which subtracts this quotient from the original input:

```
ssub =: (]`-`) (`:6) NB. x - f(x)
+: ssub NB. x - double(x)
] - +:
-: ssub NB. x - halve(x)
] - -:
-: ssub 16 NB. 16 - halve(16)
8
+: ssub 16 NB. 16 - double(16)
_16
*: ssub 16 NB. 16 - square(16)
_240
%: ssub 16 NB. 16 - sqrt(16)
12
```

Thus:

```
n_i =: znfd ssub NB. x - f'(x)/f(x)
```

And, finally, using "apply until fixed point" feature of `^:_`

, we have:

```
newton =: n_i (^:_)
```

Voila.

`d.`

prevents you from writing a tacit adverb in this case. – Eelvex Nov 1 '14 at 15:40`n_i =: d.0 1 (%/@:) (-`) (]`) (`:6)`

and`newton =: n_i (^:_)`

. I'll come back and explain why later (I'm on a phone right now). – Dan Bron Nov 3 '14 at 12:56`(-`) (]`) (`:6)`

not`(]`) (-`) (`:6)`

for building`] - f`

fork. – Dan Oak Nov 3 '14 at 16:35`f (d.0 1) (%/@:)`

as a black-box that builds up (effectively)`(f % f d.1)`

; well then you've got`black_box (`-) (`])`

, which, read inreverse(LIFO), reads`]`

,`-`

,`black_box`

, which then gets executed into the train`] - black_box`

. No, the real sneaky trick here was using`d.0 1`

:) . Does that clear it up, or would you still like me to post a formal answer? – Dan Bron Nov 3 '14 at 18:16`f (d.0 1) (%/@:)`

trick :) - it's cool indeed: we calculate zeroth and first derivatives of`f`

and then insert`%`

between them. I've understood the order in which you've written these three adverbs as well. Thank you very much! – Dan Oak Nov 3 '14 at 18:44