Provided by: libcrypt-dh-gmp-perl_0.00012-1build2_amd64 
NAME
Crypt::DH::GMP - Crypt::DH Using GMP Directly
SYNOPSIS
use Crypt::DH::GMP;
my $dh = Crypt::DH::GMP->new(p => $p, g => $g);
my $val = $dh->compute_secret();
# If you want compatibility with Crypt::DH (it uses Math::BigInt)
# then use this flag
# You /think/ you're using Crypt::DH, but...
use Crypt::DH::GMP qw(-compat);
my $dh = Crypt::DH->new(p => $p, g => $g);
my $val = $dh->compute_secret();
DESCRIPTION
Crypt::DH::GMP is a (somewhat) portable replacement to Crypt::DH, implemented mostly in C.
RATIONALE
In the beginning, there was "Crypt::DH". However, "Crypt::DH" suffers from a couple of
problems:
GMP/Pari libraries are almost always required
"Crypt::DH" works with a plain "Math::BigInt", but if you want to use it in
production, you almost always need to install "Math::BigInt::GMP" or
"Math::BigInt::Pari" because without them, the computation that is required by
"Crypt::DH" makes the module pretty much unusable.
Because of this, "Crypt::DH" might as well make "Math::BigInt::GMP" a hard
requirement.
Crypt::DH suffers from having Math::BigInt in between GMP
With or without "Math::BigInt::GMP" or "Math::BigInt::Pari", "Crypt::DH" makes several
round trip conversions between Perl scalars, Math::BigInt objects, and finally its C
representation (if GMP/Pari are installed).
Instantiating an object comes with a relatively high cost, and if you make many
computations in one go, your program will suffer dramatically because of this.
These problems quickly become apparent when you use modules such as
"Net::OpenID::Consumer", which requires to make a few calls to "Crypt::DH".
"Crypt::DH::GMP" attempts to alleviate these problems by providing a
"Crypt::DH"-compatible layer, which, instead of doing calculations via Math::BigInt,
directly works with libgmp in C.
This means that we've essentially eliminated 2 call stacks worth of expensive Perl method
calls and we also only load 1 (Crypt::DH::GMP) module instead of 3 (Crypt::DH +
Math::BigInt + Math::BigInt::GMP).
These add up to a fairly significant increase in performance.
COMPATIBILITY WITH Crypt::DH
Crypt::DH::GMP absolutely refuses to consider using anything other than strings as its
parameters and/or return values therefore if you would like to use Math::BigInt objects as
your return values, you can not use Crypt::DH::GMP directly. Instead, you need to be
explicit about it:
use Crypt::DH;
use Crypt::DH::GMP qw(-compat); # must be loaded AFTER Crypt::DH
Specifying -compat invokes a very nasty hack that overwrites Crypt::DH's symbol table --
this then forces Crypt::DH users to use Crypt::DH::GMP instead, even if you are writing
my $dh = Crypt::DH->new(...);
$dh->compute_key();
BENCHMARK
By NO MEANS is this an exhaustive benchmark, but here's what I get on my MacBook (OS X
10.5.8, 2.4 GHz Core 2 Duo, 4GB RAM)
Benchmarking instatiation cost...
Rate pp gmp
pp 9488/s -- -79%
gmp 45455/s 379% --
Benchmarking key generation cost...
Rate gmp pp
gmp 6.46/s -- -0%
pp 6.46/s 0% --
Benchmarking compute_key cost...
Rate pp gmp
pp 12925/s -- -96%
gmp 365854/s 2730% --
METHODS
new
p
g
compute_key
compute_secret
generate_keys
pub_key
priv_key
compute_key_twoc
Computes the key, and returns a string that is byte-padded two's compliment in binary
form.
pub_key_twoc
Returns the pub_key as a string that is byte-padded two's compliment in binary form.
clone
AUTHOR
Daisuke Maki "<daisuke@endeworks.jp>"
LICENSE
This program is free software; you can redistribute it and/or modify it under the same
terms as Perl itself.
See http://www.perl.com/perl/misc/Artistic.html