Please read JJ's answer first. It's breezy and led to this answer which is effectively an elaboration of it.

**TL;DR** `A(4,3)`

is a *very* big number, one that cannot be computed in this universe. But Rakudo will try. As it does you will blow past reasonable limits related to memory allocation and indexing if you use the caching version and limits related to numeric calculations if you don't.

I try some examples from Rosettacode and encounter an issue with the provided Ackermann example

Quoting the task description with some **added emphasis**:

**Arbitrary precision** is preferred (since the function **grows so quickly**)

P6's standard integer type `Int`

is arbitrary precision. The P6 solution uses them to compute the most advanced answer possible. It only fails when you make it try to do the impossible.

When running it "unmodified" (I replaced the utf-8 variable names by latin-1 ones)

Replacing the variable names is not a significant change.

But adding the `A(4,3)`

line shifted the code from being computable in reality to not being computable in reality.

The example you modified has just one explanatory comment:

Here's a caching version of that ... *to make ***A(4,2)** possible

Note that the `A(4,2)`

solution is nearly 20,000 digits long.

If you look at the other solutions on that page most don't even try to reach `A(4,2)`

. There are comments like this one on the Phix version:

optimised. still no bignum library, so ack(4,2), which is power(2,65536)-3, which is apparently 19729 digits, and any above, are beyond (the CPU/FPU hardware) and this [code].

A solution for `A(4,2)`

is the most advanced possible.

`A(4,3)`

is not computable in practice

To quote Academic Kids: Ackermann function:

Even for small inputs (4,3, say) the values of the Ackermann function become so large that they cannot be feasibly computed, and in fact their decimal expansions cannot even be stored in the entire physical universe.

So computing `A(4,3).say`

is impossible (in this universe).

It *must inevitably* lead to an overflow of even arbitrary precision integer arithmetic. It's just a matter of when and how.

`Cannot unbox 65536 bit wide bigint into native integer`

The first error message mentions this line of code:

```
proto A(Int \m, Int \n) { (state @)[m][n] //= {*} }
```

The `state @`

is an anonymous state array variable.

By default `@`

variables use the default concrete type for P6's abstract array type. This default array type provides a balance between implementation complexity and decent performance.

While computing `A(4,2)`

the indexes (`m`

and `n`

) remain small enough that the computation completes without overflowing the default array's indexing limit.

This limit is a "native" integer (note: *not* a "natural" integer). A "native" integer is what P6 calls the fixed width integers supported by the hardware it's running on, typically a long long which in turn is typically 64 bits.

A 64 bit wide index can handle indices up to 9,223,372,036,854,775,807.

But in trying to compute `A(4,3)`

the algorithm generates a 65536 bits (8192 bytes) wide integer index. Such an integer could be as big as 2^{65536}, a 20,032 decimal digit number. But the biggest index allowed is a 64 bit native integer. So unless you comment out the caching line that uses an array, then for `A(4,3)`

the program ends up throwing the exception:

Cannot unbox 65536 bit wide bigint into native integer

# Limits to allocations and indexing of the default array type

As already explained, there is no array that could be big enough to help fully compute `A(4,3)`

. In addition, a 64 bit integer is already a pretty big index (`9,223,372,036,854,775,807`

). That said, P6 can accommodate larger arrays so I'll discuss that briefly below because the theoretical possibilities might be of interest for other problems.

But before discussing bigger arrays running the code below on tio.run shows the *practical* limits *for the default array type* on that platform:

```
my @array;
@array[2**29]++; # works
@array[2**30]++; # could not allocate 8589967360 bytes
@array[2**60]++; # Unable to allocate ... 1152921504606846977 elements
@array[2**63]++; # Cannot unbox 64 bit wide bigint into native integer
```

(Comment out error lines to see later/greater errors.)

The "could not allocate 8589967360 bytes" error is a MoarVM panic. It's a result of tio.run refusing a memory allocation request.

I think the "Unable to allocate ... elements" error is a P6 level exception that's thrown as a result of exceeding some internal Rakudo implementation limit.

The last error message shows the indexing limit for the default array type even if vast amounts of memory were made available to programs.

# What if someone wanted to do larger indexing?

It's possible to create/use other `@`

(`does Positional`

) data types that support things like sparse arrays etc.

And, using this mechanism, it's possible that someone could write an array implementation that supports larger integer indexing than is supported by the default array type (presumably by layering logic on top of the underlying platform's instructions).

If such an alternative were created and called `BigArray`

then the cache line could be replaced with:

```
my @array is BigArray;
sub A(Int \𝑚, Int \𝑛) { @BigArray[𝑚][𝑛] //= {*} }
```

Again, this *still* wouldn't be enough to store interim results for fully computing `A(4,3)`

but my point was to show use of custom array types.

`Numeric overflow`

When you comment out the caching you get:

Numeric overflow

P6/Rakudo do arbitrary precision arithmetic. While this is sometimes called infinite precision it isn't (can't be) *actually* infinite but is instead, well, "arbitrary", which in practice in computing means "sane" for some definition of "sane".

This classically means running out of memory to store a number. But in Rakudo's case I think there's an attempt to keep things sane by switching from a truly vast `Int`

to a `Num`

(a floating point number) before completely running out of RAM. But then computing `A(4,3)`

eventually overflows even a double float.

So while the caching blows up sooner, the code is bound to blow up later anyway, and then you'd get a numeric overflow that would either manifest as an out of memory error or a numeric overflow error as it is in this case..