Computing GCDs over the Gaussian Integers: Difference between revisions
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<pre> |
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#!/usr/bin/perl |
#!/usr/bin/perl |
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use Math::Complex; |
use Math::Complex; |
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&gcd($z1, $z2); |
&gcd($z1, $z2); |
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</pre> |
Revision as of 14:46, 26 November 2011
I wrote up a very simple Perl script for computing GCDs over the Gaussian integers. It comes with no guarantee.
#!/usr/bin/perl use Math::Complex; ## A Quick hack for computing GCDs of Gaussian integers. $z2 = 857 + i; $z1 = 255; sub gcd { # the Euclidean algorithm my $x = $_[0]; my $y = $_[1]; if ($x * $y == 0) { print "Done!\n"; } else { $q = &approx($x/$y); $r = $x - $q*$y; print "($x) = ($q)($y) + ($r)\n"; &gcd($y,$r); } } sub approx { # find the nearest Gaussian integer to a point on the complex plane my $z = $_[0]; my $x = int(Re($z)); my $y = int(Im($z)); if (abs($z - (($x+1) + i*$y) ) < 1/sqrt(2)) { return ($x+1) + i*$y; } elsif (abs($z - (($x) + i*($y+1)) ) < 1/sqrt(2)) { return $x + i*($y+1); } elsif (abs($z - (($x+1) + i*($y+1)) ) < 1/sqrt(2)) { return ($x+1) + i*($y+1); } else { return $x + i*$y; } } &gcd($z1, $z2);