Here is one in perl with a few differences from Fnord's:

- It always clamps (add non-clamping behavior flags, if you wish, by following Fnord's example).
- It catches lines of zero-length line segments that would otherwise cause a divide by zero.
- The
`1e-6`

values below are used to deal with possible floating point errors. Adjust or remove those if you need a different tolerance:

```
use strict;
use warnings;
use Math::Vector::Real;
use Math::Matrix;
# True if $a >= $b within $tolerance
sub approx_greater
{
my ($a, $b, $tolerance) = @_;
$tolerance //= 1e-6;
return ($a-$b) > -$tolerance;
}
# True if $a <= $b within $tolerance
sub approx_lesser
{
my ($a, $b, $tolerance) = @_;
$tolerance //= 1e-6;
return ($b-$a) > -$tolerance;
}
# True if $a == $b within $tolerance
sub approx_equal
{
my ($a, $b, $tolerance) = @_;
$tolerance //= 1e-6;
return abs($a-$b) < $tolerance;
}
# Returns shortest line: [ [x1,y1,z1], [x2,y2,z2], distance ].
# If askew lines cross (or nearly-intersect) then xyz1 and xyz2 are undefined
# and only distance is returned.
#
# Thank you to @Fnord: https://stackoverflow.com/a/18994296/14055985
sub line_intersect
{
# Map @_ as vectors:
my ($a0, $a1, $b0, $b1) = map { V(@{ $_ }) } @_;
my $A = ($a1-$a0);
my $B = ($b1-$b0);
my $magA = abs($A);
my $magB = abs($B);
# If length line segment:
if ($magA == 0 || $magB == 0)
{
return V(undef, undef, 0);
}
my $_A = $A / $magA;
my $_B = $B / $magB;
my $cross = $_A x $_B;
my $denom = $cross->norm2;
# If lines are parallel (denom=0) test if lines overlap.
# If they don't overlap then there is a closest point solution.
# If they do overlap, there are infinite closest positions, but there is a closest distance
#if ($denom == 0)
if (approx_equal($denom, 0))
{
my $d0 = $_A * ($b0-$a0);
my $d1 = $_A * ($b1-$a0);
# Is segment B before A?
#if ($d0 <= 0 && 0 >= $d1)
if (approx_lesser($d0, 0) && approx_greater(0, $d1))
{
if (abs($d0) < abs($d1))
{
return V($a0, $b0, abs($a0-$b0));
}
else
{
return V($a0, $b1, abs($a0-$b1));
}
}
# Is segment B after A?
#elsif ($d0 >= $magA && $magA <= $d1)
elsif (approx_greater($d0, $magA) && approx_lesser($magA, $d1))
{
if (abs($d0) < abs($d1))
{
return V($a1, $b0, abs($a1-$b0));
}
else
{
return V($a1, $b1, abs($a1-$b1));
}
}
else
{
# Segments overlap, return distance between parallel segments
return V(V(), V(), abs((($d0*$_A)+$a0)-$b0));
}
}
else
{
# Lines criss-cross: Calculate the projected closest points
my $t = ($b0 - $a0);
# Math::Matrix won't wirth with Math::Vector::Real
# even though they are blessed arrays,
# so convert them to arrays and back to refs:
my $detA = Math::Matrix->new([ [ @$t ], [ @$_B ], [ @$cross] ])->det;
my $detB = Math::Matrix->new([ [ @$t ], [ @$_A ], [ @$cross] ])->det;
my $t0 = $detA / $denom;
my $t1 = $detB / $denom;
my $pA = $a0 + ($_A * $t0); # Projected closest point on segment A
my $pB = $b0 + ($_B * $t1); # Projected closest point on segment A
if ($t0 < 0)
{
$pA = $a0;
}
elsif ($t0 > $magA)
{
$pA = $a1;
}
if ($t1 < 0)
{
$pB = $b0;
}
elsif ($t1 > $magB)
{
$pB = $b1;
}
# Clamp projection A
if ($t0 < 0 || $t0 > $magA)
{
my $dot = $_B * ($pA-$b0);
if ($dot < 0)
{
$dot = 0;
}
elsif ($dot > $magB)
{
$dot = $magB;
}
$pB = $b0 + ($_B * $dot)
}
# Clamp projection B
if ($t1 < 0 || $t1 > $magB)
{
my $dot = $_A * ($pB-$a0);
if ($dot < 0)
{
$dot = 0;
}
elsif ($dot > $magA)
{
$dot = $magA;
}
$pA = $a0 + ($_A * $dot)
}
return V($pA, $pB, abs($pA-$pB));
}
}
print "example: " . line_intersect(
[13.43, 21.77, 46.81 ], [27.83, 31.74, -26.60 ],
[77.54, 7.53, 6.22 ], [26.99, 12.39, 11.18 ]) . "\n" ;
print "contiguous: " . line_intersect(
[0, 0, 0 ], [ 0, 0, 1 ],
[0, 0, 1 ], [ 0, 0, 2 ],
) . "\n" ;
print "contiguous 90: " . line_intersect(
[0, 0, 0 ], [ 0, 0, 1 ],
[0, 0, 1 ], [ 0, 1, 1 ],
) . "\n" ;
print "colinear separate: " . line_intersect(
[0, 0, 0 ], [ 0, 0, 1 ],
[0, 0, 2 ], [ 0, 0, 3 ],
) . "\n" ;
print "cross: " . line_intersect(
[1, 1, 0 ], [ -1, -1, 0 ],
[-1, 1, 0 ], [ 1, -1, 0 ],
) . "\n" ;
print "cross+z: " . line_intersect(
[1, 1, 0 ], [ -1, -1, 0 ],
[-1, 1, 1 ], [ 1, -1, 1 ],
) . "\n" ;
print "full overlap1: " . line_intersect(
[2, 0, 0 ], [ 5, 0, 0 ],
[3, 0, 0 ], [ 4, 0, 0 ],
) . "\n" ;
print "full overlap2: " . line_intersect(
[3, 0, 0 ], [ 4, 0, 0 ],
[2, 0, 0 ], [ 5, 0, 0 ],
) . "\n" ;
print "partial overlap1: " . line_intersect(
[2, 0, 0 ], [ 5, 0, 0 ],
[3, 0, 0 ], [ 6, 0, 0 ],
) . "\n" ;
print "partial overlap2: " . line_intersect(
[3, 0, 0 ], [ 6, 0, 0 ],
[2, 0, 0 ], [ 5, 0, 0 ],
) . "\n" ;
print "parallel: " . line_intersect(
[3, 0, 0 ], [ 6, 0, 0 ],
[3, 0, 1 ], [ 6, 0, 1 ],
) . "\n" ;
```

### Output

```
example: {{20.29994361624, 26.5264817954106, 11.7875999397098}, {26.99, 12.39, 11.18}, 15.6513944955904}
contiguous: {{0, 0, 1}, {0, 0, 1}, 0}
contiguous 90: {{0, 0, 1}, {0, 0, 1}, 0}
colinear separate: {{0, 0, 1}, {0, 0, 2}, 1}
cross: {{-2.22044604925031e-16, -2.22044604925031e-16, 0}, {2.22044604925031e-16, -2.22044604925031e-16, 0}, 4.44089209850063e-16}
cross+z: {{-2.22044604925031e-16, -2.22044604925031e-16, 0}, {2.22044604925031e-16, -2.22044604925031e-16, 1}, 1}
full overlap1: {{}, {}, 0}
full overlap2: {{}, {}, 0}
partial overlap1: {{}, {}, 0}
partial overlap2: {{}, {}, 0}
parallel: {{}, {}, 1}
```