There is a big problem with this:

```
say reduce {is-prime}, @g;
```

You created a lambda:

```
{ }
```

The only thing it does is calls a function:

```
is-prime
```

You didn't give the function any arguments though.

Is it just supposed to guess what the arguments should be?

If you meant to pass in `is-prime`

as a reference, you should have used `&is-prime`

rather than `{is-prime}`

.
Of course that still wouldn't have worked.

The other problem is that `reduce`

operates by recursively combining values.

It can't do that if it operates on one argument at a time.

The bare block lambda `{}`

, takes zero or one argument, not two or more.

`reduce`

is often combined with `map`

.

It happens so often that there is a Wikipedia page about MapReduce.

```
say ( map &is-prime, @g ==> reduce { $^a and $^b } );
# False
say ( map &is-prime, 2,3,5 ==> reduce { $^a and $^b } );
# True
```

I wrote it that way so that `map`

would be in the line before `reduce`

, but perhaps it would be more clear this way:

```
say reduce {$^a and $^b}, map &is-prime, 2,3,5;
# True
```

`reduce`

with an infix operator is so common that there is a shorter way to write it.

```
say [and] map &is-prime, 2,3,5;
# True
```

Of course it would be better to just find the first value that isn't prime, and say the inverse.

Since if there is even a single value that isn't prime that would mean they can't all be primes.

You have to be careful though, as you may think something like this would always work:

```
not @g.first: !*.is-prime;
```

It does happen to work for the values you gave it, but may not always.

`first`

returns `Nil`

if it can't find the value.

```
not (2,3,5).first: !*.is-prime;
# not Nil === True
not (2,3,4).first: !*.is-prime;
# not 4 === False
not (2,3,0,4).first: !*.is-prime;
# not 0 === True
```

That last one returned `0`

which when combined with `not`

returns `True`

.

You could fix this with `defined`

.

```
not defined (2,3,0,4).first: !*.is-prime;
# False
```

This only works if `first`

wouldn't return an undefined element that happens to be in the list.

```
(Int,Any).first: Real
# Int
defined (Int,Any).first: Real
# False
```

You could fix that by asking for the index instead of the value.

You of course still need `defined`

.

```
(Int,Any).first: :k, Real
# 0
defined (Int,Any).first: :k, Real
# True
```

The other way to fix it is to just use `grep`

.

```
not (2,3,0,4).grep: !*.is-prime;
# not (0,4) === False
```

Since `grep`

always returns a `List`

, you don't have to worry about checking for `0`

or undefined elements.

(A `List`

is `True`

if it contains any elements, no matter what the values.)

`grep`

is smart enough to know that if you coerce to `Bool`

that it can stop upon finding the first value.
So it short-circuits the same as if you had used `first`

.

This results in some fairly funky code, with those two negating operators. So it should be put into a function.

```
sub all-prime ( +@_ ) {
# return False if we find any non-prime
not @_.grep: !*.is-prime
# grep short-circuits in Bool context, so this will stop early
}
```

This could still fail if you give it something weird

```
all-prime 2,3,5, Date.today;
# ERROR: No such method 'is-prime' for invocant of type 'Date'
```

If you care, add some error handling.

```
sub all-prime ( +@_ ) {
# return Nil if there was an error
CATCH { default { return Nil }}
# return False if we find any non-prime
not @_.grep: !*.is-prime
}
all-prime 2,3,5, Date.today;
# Nil
```

`so is-prime @g.all`

, although it makes most sense to me to write it as`so is-prime all @g`

or`?@g.all.is-prime`

– user0721090601 Jun 7 at 19:21