See @wamba's wonderful answer for solutions to the question in your title. They showcase a wide range of applicable Raku constructs.

This answer focuses on Raku's sequence operator (`...`

), and the details in the body of your question, explaining what went wrong in your attempts, and explaining some working sequences.

# TL;DR

The value of the `N`

th term is `1 / N`

.

```
# Generator ignoring prior terms, incrementing an N stored in the generator:
{ 1 / ++$ } ... * # idiomatic
{ state $N; $N++; 1 / $N } ... * # longhand
# Generator extracting denominator from prior term and adding 1 to get N:
1/1, 1/2, 1/3, 1/(*.denominator+1) ... * # idiomatic (@jjmerelo++)
1/1, 1/2, 1/3, {1/(.denominator+1)} ... * # longhand (@user0721090601++)
```

# What's wrong with `{1/$_}`

?

```
1, 1/2, 1/3, 1/4 ... *
```

What is the value of the `N`

th term? It's `1/N`

.

```
1, {1/$_} ...*
```

What is the value of the `N`

th term? It's `1/$_`

.

`$_`

is a generic *parameter/argument/operand* analogous to the English pronoun "it".

Is it set to `N`

?

No.

So your generator (lambda/function) doesn't encode the sequence you're trying to reproduce.

# What is `$_`

set to?

Within a function, `$_`

is bound either to `(Any)`

, or to an argument passed to the function.

If a function explicitly specifies its *parameters* (a "parameter" specifies an argument that a function *expects to receive*; this is distinct from the argument that a function actually ends up getting for any given call), then `$_`

is bound, or not bound, per that specification.

If a function does *not* explicitly specify its parameters -- and yours doesn't -- then `$_`

is bound to the argument, if any, that is passed as part of the call of the function.

For a *generator* function, any value(s) passed as arguments are *values of preceding terms in the sequence*.

Given that your generator doesn't explicitly specify its parameters, the immediately prior term, if any, is passed and bound to `$_`

.

In the *first* call of your generator, when `1/$_`

gets evaluated, the `$_`

is bound to the `1`

from the first term. So the second term is `1/1`

, i.e. `1`

.

Thus the *second* call, producing the third term, has the same result. So you get an infinite sequence of `1`

s.

# What's wrong with `{1/@list[$_+1]}`

?

For your last example you presumably meant:

```
my @list = 0 ... *;
(1, {1/@list[$_+1]} ...*)[0..5]
```

In this case the *first* call of the generator returns `1/@list[1+1]`

which is `1/2`

(`0.5`

).

So the *second* call is `1/@list[0.5+1]`

. This specifies a fractional index into `@list`

, asking for the `1.5`

th element. Indexes into standard `Positional`

s are rounded down to the nearest integer. So `1.5`

is rounded down to `1`

. And `@list[1]`

evaluates to `1`

. So the value returned by the second call of the generator is back to `1`

.

Thus the sequence alternates between `1`

and `0.5`

.

# What arguments are passed to a generator?

Raku passes the value of zero or more prior terms in the sequence as the arguments to the generator.

How many? Well, a generator is an ordinary Raku lambda/function. Raku uses the implicit or explicit declaration of parameters to determine how many arguments to pass.

For example, in:

```
{42} ... * # 42 42 42 ...
```

the lambda doesn't declare what parameters it has. For such functions Raku presumes a signature including `$_?`

, and thus passes the prior term, if any. (The above lambda ignores it.)

# Which arguments do you *need/want* your generator to be passed?

One could argue that, for the sequence you're aiming to generate, you don't need/want to pass *any* of the prior terms. Because, arguably, *none* of them really matter.

From this perspective all that matters is that the `N`

th term computes `1/N`

. That is, its value is independent of the values of prior terms and just dependent on *counting the number of calls*.

# State solutions such as `{1/++$}`

One way to compute this is something like:

```
{ state $N; $N++; 1/$N } ... *
```

The lambda ignores the previous term. The net result is just the desired `1 1/2 1/3 ...`

.

(Except that you'll have to fiddle with the stringification because by default it'll use `gist`

which will turn the `1/3`

into `0.333333`

or similar.)

Or, more succinctly/idiomatically:

```
{ 1 / ++$ } ... *
```

(An anonymous `$`

in a statement/expression is a simultaneous declaration and use of an anonymous state scalar variable.)

# Solutions using the prior term

As @user0721090601++ notes in a comment below, one can write a generator that makes use of the prior value:

```
1/1, 1/2, 1/3, {1/(.denominator+1)} ... *
```

For a generator that doesn't explicitly specify its parameters, Raku passes the value of the prior term in the sequence as the argument, binding it to the "it" argument `$_`

.

And given that there's no explicit invocant for `.denominator`

, Raku presumes you mean to call the method on `$_`

.

As @jjmerelo++ notes, an idiomatic way to express many lambdas is to use the explicit pronoun "whatever" instead of "it" (implicit or explicit) to form a `WhateverCode`

lambda:

```
1/1, 1/2, 1/3, 1/(*.denominator+1) ... *
```

You drop the braces for this form, which is one of its advantages. (You can also use multiple "whatevers" in a single expression rather than just one "it", another part of this construct's charm.)

This construct typically takes some getting used to; perhaps the biggest hurdle is that a `*`

must be combined with a "`WhateverCode`

able" operator/function for it to form a `WhateverCode`

lambda.