This type of problem is my cup of tea. Here are my thoughts:

# Let's take a step back

The key objective here is to reduce the amount of time taken to evaluate the results. You have 3^24 = 282+ billion evaluations that need to be performed which cannot be avoided. However, there are a few tricks that can be employed to make lighter work of the problem (the comments also allude to some of these):

- Parallelize the effort to cut down the time needed
- Avoid repeated calculations

# Parallelized computing

### Divide and conquer

The key to unlocking parallelization (as has already been mentioned) is to divide the effort into smaller segments. In the context of this problem, the tuples need to be divided into more manageable chunks.

If I have a quad-core processor, I might want to split the tuples into four baskets:

```
my ( @baskets, $iter );
push @{ $baskets[ $iter++ % 4 ] }, $_ for $iterator->combinations;
```

This kind of functionality is quite readily rolled into a sub:

```
sub segment {
my $num_segments = shift;
my ( @baskets, $iter );
push @{ $baskets[ $iter++ % $num_segments ] }, $_ for @_;
return @baskets;
}
my @jobs = segment( 4, $iterator->combinations );
```

### Launch in parallel

The use of threads should be adequate here since the per-tuple computation is lightweight (refer to `perldoc perlthrtut`

for more information on how to use threads in Perl):

```
use threads; # imports threads module
sub work { # What each thread will run
my @tuples = @_;
my $sum;
for my $tuple ( @tuples ) {
my $freq = 1;
$freq *= $_ for @$tuple;
$sum += $freq * $freq;
}
return $sum;
}
my @threads = map threads->new( \&work, @$_ ), @jobs; # Create and launch threads
# with different tuple sets
my $grand_total;
$grand_total += $_->join for @threads; # Accumulate sub-totals
```

# Kill *n* birds with 1 stone (multiplied by *n*)

**Disclaimer:** The effectiveness of this solution increases as the number of discrete probabilities increases. It is not easy to judge whether this proposal would actually reduce the time to get the result.

Assuming 2 d.p., there can only ever be 100 possible different values across all tuples (I guess this is where the Birthday Problem comes into play). Given that you have 24 probabilities in each tuple, I imagine the likelihood of two tuples yielding the same frequency is high (a statistician can confirm this assumption). This can be demonstrated with a simple example in which I've limited the number of probabilities to just 3:

```
[ 0.33, 0.45, 0.22 ], # Tuple A
.
.
.
[ 0.45, 0.22, 0.33 ], # Tuple B
```

Here, tuples A and B will return the same value for `$freq`

. If we count the number of times this `$freq`

value would appear, one can simply compute `$freq`

once and multiply it by the number of "repeat" tuples (and thereby killing many tuples with one stone).

This would involve detecting the number of repeats:

```
my %seen;
for my $tuple ( $iterator->combinations ) {
my @sorted = sort @$tuple;
my $tuple_as_string = "@sorted";
$seen{$tuple_as_string}{count}++;
next unless exists $seen{$tuple_as_string}{freq};
my $freq = 1;
$freq *= $_ for @$tuple;
$seen{$tuple_as_string}{freq} = $freq;
}
my $grand_total;
for my $unique ( keys %seen ) {
my $count = $seen{$unique}{count};
my $freq = $seen{$unique}{freq};
$grand_total += $count * $freq * $freq;
}
```

If you wish to combine this idea with parallelization, I would recommend identifying the "unique" tuples first before proceeding with parallelizing the operation.

significantlymore expensive than just`$tuple->[0] * $tuple->[1] * $tuple->[2] ...`

– ysth Mar 28 '14 at 16:43`$freq =1; $freq *= $_ for @$tuple;`

instead of`$freq = reduce { $a * $b } @$tuple;`

– Сухой27 Mar 28 '14 at 16:49signficant, but still a way to go sadly. – Reuben John Pengelly Mar 28 '14 at 17:08`0.33`

s. – ThisSuitIsBlackNot Mar 28 '14 at 17:17