Here's how you can do the same thing you're doing with R in Perl using the Math::SymbolicX::Statistics::Distributions module from CPAN:

```
use strict; use warnings;
use Math::SymbolicX::Statistics::Distributions qw/normal_distribution/;
my $norm = normal_distribution(qw/mean sd/);
print $norm->value(mean => 4, sd => 10, x => 0), "\n";
# curry it with the parameter values
$norm->implement(mean => 4, sd => 10);
print $norm->value(x => 0),"\n"; # prints the same as above
```

The normal_distribution() function from that module is a generator for functions. $norm will be a Math::Symbolic (::Operator) object that you can modify. For example with *implement*, which, in the above example, replaces the two parameter variables with constants.

Note, however as Dirk pointed out, that you probably want the cumulative function of the normal distribution. Or more generally the integral in a certain range.

Unfortunately, Math::Symbolic can't do integration symbolically. Therefore, you'd have to resort to numerical integration with the likes of Math::Integral::Romberg. (Alternatively, search CPAN for an implementation of the error function.) This may be slow, but it's still easy to do. Add this to the above snippet:

```
use Math::Integral::Romberg 'integral';
my ($int_sub) = $norm->to_sub(); # compile to a faster Perl sub
print $int_sub->(0),"\n"; # same number as above
print "p=" . integral($int_sub, -100., 0) . "\n";
# -100 is an arbitrary, small number
```

This should give you the ~0.344578258389676 from Dirk's answer.