## A Complete Catalog

@Michael Berry's answer is very clear and concise. A sterling example of the J idiom *table* (`f"0/~`

). I love it because it demonstrates how the subtle design of J has permitted us to generalize and extend a concept familiar to anyone from 3rd grade: arithmetic tables (addition tables, `+/~ i. 10`

and multiplication tables `*/~ i.12`

¹), which even in APL were relatively clunky.

In addition to that fine answer, it's also worth noting that there is a primitive built into J to calculate the Cartesian product, the monad `{`

.

For example:

```
> { 2 # <1 0 _1 NB. Or i:_1 instead of 1 0 _1
1 1
1 0
1 _1
0 1
0 0
0 _1
_1 1
_1 0
_1 _1
```

## Taking Inventory

Note that the input to monad `{`

is a list of boxes, and the number of boxes in that list determines the number of elements in each combination. A list of two boxes produces an array of 2-tuples, a list of 3 boxes produces an array of 3-tuples, and so on.

## A Tad Excessive

Given that full outer products (Cartesian products) are so expensive (`O(n^m)`

), it occurs to one to ask: why does J have a primitive for this?

A similar misgiving arises when we inspect monad `{`

's output: why is it boxed? Boxes are used in J when, and only when, we want to consolidate arrays of incompatible types and shapes. But all the results of `{ y`

will have identical types and shapes, by the very definition of `{`

.

So, what gives? Well, it turns out these two issues are related, and justified, once we understand why the monad `{`

was introduced in the first place.

## I'm Feeling Ambivalent About This

We must recall that all verbs in J are ambivalent perforce. J's grammar does not admit a verb which is only a monad, or only a dyad. Certainly, one valence or another might have an empty domain (i.e. no valid inputs, like monad `E.`

or dyad `~.`

or either valence of `[:`

), but it still *exists*.

An valence with an empty domain is "real", but its range of valid inputs is empty (an extension of the idea that the range of valid inputs to e.g. `+`

is numbers, and anything else, like characters, produces a "domain error").

Ok, fine, so all verbs have two valences, so what?

## A Selected History

Well, one of the primary design goals Ken Iverson had for J, after long experience with APL, was ditching the bracket notation for array indexing (e.g. `A[3 4;5 6;2]`

), and recognizing that *selection from an array is a function*.

This was an enormous insight, with a serious impact on both the design and use of the language, which unfortunately I don't have space to get into here.

And since all functions need a name, we had to give one to the selection function. All primitive verbs in J are spelled with either a glyph, an inflected glyph (in my head, the `.`

, `:`

, `.:`

etc suffixes are diacritics), or an inflected alphanumeric.

Now, because selection is *so* common and fundamental to array-oriented programming, it was given some prime real estate (a mark of distinction in J's orthography), a single-character glyph: `{`

².

So, since `{`

was defined to be selection, and selection is of course dyadic (i.e having two arguments: the indices and the array), that accounts for the dyad `{`

. And now we see why it's important to note that all verbs are ambivalent.

## I Think I'm Picking Up On A Theme

When designing the language, it would be nice to give the *monad* `{`

some thematic relationship to "selection"; having the two valences of a verb be thematically linked is a common pattern in J, for elegance and mnemonic purposes.

That broad pattern is also a topic worthy of a separate discussion, but for now let's focus on why catalog / Cartesian product was chosen for monad `{`

. What's the connection? And what accounts for the other quirk, that its results are always boxed?

## Bracketectomy

Well, remember that `{`

was introduced to replace -- replace completely -- the old bracketing subscript syntax of APL and (and many other programming languages and notations). This at once made selection easier, more useful, and also simplified J's syntax: in APL, the grammar, and consequently parser, had to have special rules for indexing like:

```
A[3 4;5 6;2]
```

The syntax was an anomaly. But boy, wasn't it useful and expressive from the programmer's perspective, huh?

But why is that? What accounts for the multi-dimensional bracketing notation's economy? How is it that we can say so much in such little space?

Well, let's look at what we're saying. In the expression above `A[3 4;5 6;2]`

, we're asking for the 3^{rd} and 4^{th} rows, the 5^{th} and 6^{th} columns, and the 2^{nd} plane.

That is, we want

- plane 2, row 3, column 5, and
plane 2, row 3, column 6, and

plane 2, row 4, column 5 and

- plane 2, row 4, column 6

Think about that a second. I'll wait.

## The Moment Ken Blew Your Mind

*Boom*, right?

*Indexing is a Cartesian product*.

Always has been. But Ken *saw* it.

So, now, instead of saying `A[3 4;5 6;2]`

in APL (with some hand-waving about whether `[]IO`

is `1`

or `0`

), in J we say:

```
(3 4;5 6;2) { A
```

which is, of course, just shorthand, or syntactic sugar, for:

```
idx =. { 3 4;5 6;2 NB. Monad {
idx { A NB. Dyad {
```

So we retained the familiar, convenient, and suggestive semicolon syntax (what do you want to bet link being spelled `;`

is *also* not a coincidence?) while getting all the benefits of turning `{`

into a first-class function, as it always should have been³.

## Opening The Mystery Box

Which brings us back to that other, final, quibble. *Why the heck are monad *`{`

's results boxed, if they're all regular in type and shape? Isn't that superfluous and inconvenient?

Well, yes, but remember that an unboxed, i.e. numeric, LHA in `x { y`

only selects *items* from `y`

.

This is convenient because it's a frequent need to select the same item multiple times (e.g. in replacing `'abc'`

with `'ABC'`

and defaulting any non-abc character to `'?'`

, we'd typically say `('abc' i. y) { 'ABC','?'`

, but that only works because we're allowed to select index 4, which is `'?'`

, multiple times).

But that convenience precludes using straight numeric arrays to *also* do multidimensional indexing. That is, the convenience of unboxed numbers to select items (most common use case) interferes with *also* using unboxed numeric arrays to express, e.g. `A[17;3;8]`

by `17 3 8 { A`

. We can't have it both ways.

So we needed some other notation to express multi-dimensional selections, and since dyad `{`

has left-rank 0 (precisely *because* of the foregoing), and a single, atomic box can encapsulate an arbitrary structure, boxes were the perfect candidate.

So, to express `A[17;3;8]`

, instead of `17 3 8 { A`

, we simply say `(< 17;3;8) { A`

, which again is straighforward, convenient, and familiar, and allows us to do any number of multi-dimensional selections simultaneously e.g. `( (< 17;3;8) , (<42; 7; 2) { A`

), which is what you'd want and expect in an array-oriented language.

Which means, of course, that in order to produce the kinds of outputs that dyad `{`

expects as inputs, monad `{`

*must produce boxes*⁴. QED.

Oh, and PS: since, as I said, boxing permits *arbitrary* structure in a single atom, what happens if we don't box a box, or even a list of a boxes, but box a boxed box? Well, have you ever wanted a way to say "I want every index *except* the last" or 3rd, or 42nd and 55th? Well...

_{Footnotes:}

¹ _{Note that in the arithmetic tables +/~ i.10 and */~ i.12, we can elide the explicit "0 (present in ,"0/~ _1 0 1) because arithmetic verbs are already scalar (obviously)}

² _{But why was selection given that specific glyph, {?}

_{Well, Ken intentionally never disclosed the specific mnemonic choices used in J's orthography, because he didn't want to dictate such a personal choice for his users, but to me, Dan, { looks like a little funnel pointing right-to-left. That is, a big stream of data on the right, and a much smaller stream coming out the left, like a faucet dripping.}

_{Similarly, I've always seen dyad |: like a little coffee table or Stonehenge trilithon kicked over on its side, i.e. transposed.}

_{And monad # is clearly mnemonic (count, tally, number of items), but the dyad was always suggestive to me because it looked like a little net, keeping the items of interest and letting everything else "fall through".}

_{But, of course, YMMV. Which is precisely why Ken never spelled this out for us.}

³ _{Did you also notice that while in APL the indices, which are control data, are listed to the right of the array, whereas in J they're now on the left, where control data belong?}

⁴ _{Though this Jer would still like to see monad { produce unboxed results, at the cost of some additional complexity within the J engine, i.e. at the expense of the single implementer, and to the benefit of every single user of the language}

^{n} _{There is a lot of interesting literature which goes into this material in more detail, but unfortunately I do not have time now to dig it up. If there's enough interest, I may come back and edit the answer with references later. For now, it's worth reading Mastering J, an early paper on J by one of the luminaries of J, Donald McIntyre, which makes mention of the eschewing of the "anomalous bracket notation" of APL, and perhaps a tl;dr version of this answer I personally posted to the J forums in 2014.}