libcryptx-perl/lib/Crypt/PK/ECC.pm

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package Crypt::PK::ECC;
use strict;
use warnings;
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our $VERSION = '0.058_002';
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require Exporter; our @ISA = qw(Exporter); ### use Exporter 'import';
our %EXPORT_TAGS = ( all => [qw( ecc_encrypt ecc_decrypt ecc_sign_message ecc_verify_message ecc_sign_hash ecc_verify_hash ecc_shared_secret )] );
our @EXPORT_OK = ( @{ $EXPORT_TAGS{'all'} } );
our @EXPORT = qw();
use Carp;
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$Carp::Internal{(__PACKAGE__)}++;
use CryptX;
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use Crypt::Digest qw(digest_data digest_data_b64u);
use Crypt::Misc qw(read_rawfile encode_b64u decode_b64u encode_b64 decode_b64 pem_to_der der_to_pem);
use Crypt::PK;
our %curve = (
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# extra curves not recognized by libtomcrypt
'wap-wsg-idm-ecid-wtls8' => {
prime => "FFFFFFFFFFFFFFFFFFFFFFFFFDE7",
A => "0000000000000000000000000000",
B => "0000000000000000000000000003",
order => "0100000000000001ECEA551AD837E9",
Gx => "0000000000000000000000000001",
Gy => "0000000000000000000000000002",
cofactor => 1,
oid => '2.23.43.1.4.8',
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},
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'wap-wsg-idm-ecid-wtls9' => {
prime => "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFC808F",
A => "0000000000000000000000000000000000000000",
B => "0000000000000000000000000000000000000003",
order => "0100000000000000000001CDC98AE0E2DE574ABF33",
Gx => "0000000000000000000000000000000000000001",
Gy => "0000000000000000000000000000000000000002",
cofactor => 1,
oid => '2.23.43.1.4.9',
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},
);
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my %jwk2curve = (
'P-192' => 'secp192r1',
'P-224' => 'secp224r1',
'P-256' => 'secp256r1',
'P-384' => 'secp384r1',
'P-521' => 'secp521r1',
);
my %curve2jwk = (
'1.2.840.10045.3.1.1' => 'P-192', # secp192r1
'1.3.132.0.33' => 'P-224', # secp224r1
'1.2.840.10045.3.1.7' => 'P-256', # secp256r1
'1.3.132.0.34' => 'P-384', # secp384r1
'1.3.132.0.35' => 'P-521', # secp521r1
'nistp192' => 'P-192',
'nistp224' => 'P-224',
'nistp256' => 'P-256',
'nistp384' => 'P-384',
'nistp521' => 'P-521',
'prime192v1' => 'P-192',
'prime256v1' => 'P-256',
'secp192r1' => 'P-192',
'secp224r1' => 'P-224',
'secp256r1' => 'P-256',
'secp384r1' => 'P-384',
'secp521r1' => 'P-521',
);
our %curve2ltc = ( # must be "our" as we use it from XS code
# OIDs
"1.2.840.10045.3.1.1" => "SECP192R1",
"1.2.840.10045.3.1.2" => "PRIME192V2",
"1.2.840.10045.3.1.3" => "PRIME192V3",
"1.2.840.10045.3.1.4" => "PRIME239V1",
"1.2.840.10045.3.1.5" => "PRIME239V2",
"1.2.840.10045.3.1.6" => "PRIME239V3",
"1.2.840.10045.3.1.7" => "SECP256R1",
"1.3.132.0.10" => "SECP256K1",
"1.3.132.0.28" => "SECP128R1",
"1.3.132.0.29" => "SECP128R2",
"1.3.132.0.30" => "SECP160R2",
"1.3.132.0.31" => "SECP192K1",
"1.3.132.0.32" => "SECP224K1",
"1.3.132.0.33" => "SECP224R1",
"1.3.132.0.34" => "SECP384R1",
"1.3.132.0.35" => "SECP521R1",
"1.3.132.0.6" => "SECP112R1",
"1.3.132.0.7" => "SECP112R2",
"1.3.132.0.8" => "SECP160R1",
"1.3.132.0.9" => "SECP160K1",
"1.3.36.3.3.2.8.1.1.1" => "BRAINPOOLP160R1",
"1.3.36.3.3.2.8.1.1.11" => "BRAINPOOLP384R1",
"1.3.36.3.3.2.8.1.1.13" => "BRAINPOOLP512R1",
"1.3.36.3.3.2.8.1.1.3" => "BRAINPOOLP192R1",
"1.3.36.3.3.2.8.1.1.5" => "BRAINPOOLP224R1",
"1.3.36.3.3.2.8.1.1.7" => "BRAINPOOLP256R1",
"1.3.36.3.3.2.8.1.1.9" => "BRAINPOOLP320R1",
"1.3.36.3.3.2.8.1.1.10" => "BRAINPOOLP320T1",
"1.3.36.3.3.2.8.1.1.12" => "BRAINPOOLP384T1",
"1.3.36.3.3.2.8.1.1.14" => "BRAINPOOLP512T1",
"1.3.36.3.3.2.8.1.1.2" => "BRAINPOOLP160T1",
"1.3.36.3.3.2.8.1.1.4" => "BRAINPOOLP192T1",
"1.3.36.3.3.2.8.1.1.6" => "BRAINPOOLP224T1",
"1.3.36.3.3.2.8.1.1.8" => "BRAINPOOLP256T1",
# JWT names
"P-192" => "SECP192R1",
"P-224" => "SECP224R1",
"P-256" => "SECP256R1",
"P-384" => "SECP384R1",
"P-521" => "SECP521R1",
# openssl names
"brainpoolp160r1" => "BRAINPOOLP160R1",
"brainpoolp192r1" => "BRAINPOOLP192R1",
"brainpoolp224r1" => "BRAINPOOLP224R1",
"brainpoolp256r1" => "BRAINPOOLP256R1",
"brainpoolp320r1" => "BRAINPOOLP320R1",
"brainpoolp384r1" => "BRAINPOOLP384R1",
"brainpoolp512r1" => "BRAINPOOLP512R1",
"brainpoolp160t1" => "BRAINPOOLP160T1",
"brainpoolp192t1" => "BRAINPOOLP192T1",
"brainpoolp224t1" => "BRAINPOOLP224T1",
"brainpoolp256t1" => "BRAINPOOLP256T1",
"brainpoolp320t1" => "BRAINPOOLP320T1",
"brainpoolp384t1" => "BRAINPOOLP384T1",
"brainpoolp512t1" => "BRAINPOOLP512T1",
"nistp192" => "SECP192R1",
"nistp224" => "SECP224R1",
"nistp256" => "SECP256R1",
"nistp384" => "SECP384R1",
"nistp521" => "SECP521R1",
"prime192v1" => "SECP192R1",
"prime192v2" => "PRIME192V2",
"prime192v3" => "PRIME192V3",
"prime239v1" => "PRIME239V1",
"prime239v2" => "PRIME239V2",
"prime239v3" => "PRIME239V3",
"prime256v1" => "SECP256R1",
"secp112r1" => "SECP112R1",
"secp112r2" => "SECP112R2",
"secp128r1" => "SECP128R1",
"secp128r2" => "SECP128R2",
"secp160k1" => "SECP160K1",
"secp160r1" => "SECP160R1",
"secp160r2" => "SECP160R2",
"secp192k1" => "SECP192K1",
"secp192r1" => "SECP192R1",
"secp224k1" => "SECP224K1",
"secp224r1" => "SECP224R1",
"secp256k1" => "SECP256K1",
"secp256r1" => "SECP256R1",
"secp384r1" => "SECP384R1",
"secp521r1" => "SECP521R1",
"wap-wsg-idm-ecid-wtls6" => 'SECP112R1',
"wap-wsg-idm-ecid-wtls7" => 'SECP160R2',
"wap-wsg-idm-ecid-wtls12" => 'SECP224R1',
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);
sub _import_hex {
my ($self, $x, $y, $k, $crv) = @_;
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croak "FATAL: no curve" if !$crv;
if (defined $k && length($k) > 0) {
croak "FATAL: invalid length (k)" if length($k) % 2;
return $self->import_key_raw(pack("H*", $k), $crv);
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}
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elsif (defined $x && defined $y) {
croak "FATAL: invalid length (x)" if length($x) % 2;
croak "FATAL: invalid length (y)" if length($y) % 2;
croak "FATAL: invalid length (x,y)" if length($y) != length($x);
my $pub_hex = "04" . $x . $y;
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return $self->import_key_raw(pack("H*", $pub_hex), $crv);
}
}
sub new {
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my $self = shift->_new();
return @_ > 0 ? $self->import_key(@_) : $self;
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}
sub export_key_pem {
my ($self, $type, $password, $cipher) = @_;
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local $SIG{__DIE__} = \&CryptX::_croak;
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my $key = $self->export_key_der($type||'');
return unless $key;
return der_to_pem($key, "EC PRIVATE KEY", $password, $cipher) if substr($type, 0, 7) eq 'private';
return der_to_pem($key, "PUBLIC KEY") if substr($type,0, 6) eq 'public';
}
sub export_key_jwk {
my ($self, $type, $wanthash) = @_;
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local $SIG{__DIE__} = \&CryptX::_croak;
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my $kh = $self->key2hash;
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$kh->{curve_oid} = '' if !defined $kh->{curve_oid};
$kh->{curve_name} = '' if !defined $kh->{curve_name};
my $curve_jwt = $curve2jwk{$kh->{curve_oid}} || $curve2jwk{lc $kh->{curve_name}} || $kh->{curve_name};
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if ($type && $type eq 'private') {
return unless $kh->{pub_x} && $kh->{pub_y} && $kh->{k};
for (qw/pub_x pub_y k/) {
$kh->{$_} = "0$kh->{$_}" if length($kh->{$_}) % 2;
}
# NOTE: x + y are not necessary in privkey
# but they are used in https://tools.ietf.org/html/rfc7517#appendix-A.2
my $hash = {
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kty => "EC", crv => $curve_jwt,
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x => encode_b64u(pack("H*", $kh->{pub_x})),
y => encode_b64u(pack("H*", $kh->{pub_y})),
d => encode_b64u(pack("H*", $kh->{k})),
};
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return $wanthash ? $hash : CryptX::_encode_json($hash);
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}
elsif ($type && $type eq 'public') {
return unless $kh->{pub_x} && $kh->{pub_y};
for (qw/pub_x pub_y/) {
$kh->{$_} = "0$kh->{$_}" if length($kh->{$_}) % 2;
}
my $hash = {
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kty => "EC", crv => $curve_jwt,
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x => encode_b64u(pack("H*", $kh->{pub_x})),
y => encode_b64u(pack("H*", $kh->{pub_y})),
};
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return $wanthash ? $hash : CryptX::_encode_json($hash);
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}
}
sub export_key_jwk_thumbprint {
my ($self, $hash_name) = @_;
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local $SIG{__DIE__} = \&CryptX::_croak;
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$hash_name ||= 'SHA256';
my $h = $self->export_key_jwk('public', 1);
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my $json = CryptX::_encode_json({crv=>$h->{crv}, kty=>$h->{kty}, x=>$h->{x}, y=>$h->{y}});
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return digest_data_b64u($hash_name, $json);
}
sub import_key {
my ($self, $key, $password) = @_;
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local $SIG{__DIE__} = \&CryptX::_croak;
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croak "FATAL: undefined key" unless $key;
# special case
if (ref($key) eq 'HASH') {
if (($key->{pub_x} && $key->{pub_y}) || $key->{k}) {
# hash exported via key2hash
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my $curve_name = $key->{curve_name} || $key->{curve_oid};
return $self->_import_hex($key->{pub_x}, $key->{pub_y}, $key->{k}, $curve_name);
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}
if ($key->{crv} && $key->{kty} && $key->{kty} eq "EC" && ($key->{d} || ($key->{x} && $key->{y}))) {
# hash with items corresponding to JSON Web Key (JWK)
$key = {%$key}; # make a copy as we will modify it
for (qw/x y d/) {
$key->{$_} = eval { unpack("H*", decode_b64u($key->{$_})) } if exists $key->{$_};
}
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if (my $curve_name = $jwk2curve{$key->{crv}}) {
return $self->_import_hex($key->{x}, $key->{y}, $key->{d}, $curve_name);
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}
# curve is not JWK compliant e.g. P-192 P-224 P-256 P-384 P-521 (we'll try to import anyway)
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return $self->_import_hex($key->{x}, $key->{y}, $key->{d}, $key->{crv});
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}
croak "FATAL: unexpected ECC key hash";
}
my $data;
if (ref($key) eq 'SCALAR') {
$data = $$key;
}
elsif (-f $key) {
$data = read_rawfile($key);
}
else {
croak "FATAL: non-existing file '$key'";
}
croak "FATAL: invalid key data" unless $data;
if ($data =~ /-----BEGIN (EC PRIVATE|EC PUBLIC|PUBLIC) KEY-----(.*?)-----END/sg) {
$data = pem_to_der($data, $password);
return $self->_import($data);
}
elsif ($data =~ /-----BEGIN PRIVATE KEY-----(.*?)-----END/sg) {
$data = pem_to_der($data, $password);
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return $self->_import_pkcs8($data, $password);
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}
elsif ($data =~ /-----BEGIN ENCRYPTED PRIVATE KEY-----(.*?)-----END/sg) {
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$data = pem_to_der($data, $password);
return $self->_import_pkcs8($data, $password);
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}
elsif ($data =~ /^\s*(\{.*?\})\s*$/s) {
# JSON Web Key (JWK) - http://tools.ietf.org/html/draft-ietf-jose-json-web-key
my $json = "$1";
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my $h = CryptX::_decode_json($json);
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if ($h && $h->{kty} eq "EC") {
for (qw/x y d/) {
$h->{$_} = eval { unpack("H*", decode_b64u($h->{$_})) } if exists $h->{$_};
}
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if (my $curve_name = $jwk2curve{$h->{crv}}) {
return $self->_import_hex($h->{x}, $h->{y}, $h->{d}, $curve_name);
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}
# curve is not JWK compliant e.g. P-192 P-224 P-256 P-384 P-521 (we'll try to import anyway)
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return $self->_import_hex($h->{x}, $h->{y}, $h->{d}, $h->{crv});
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}
}
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elsif ($data =~ /-----BEGIN CERTIFICATE-----(.*?)-----END CERTIFICATE-----/sg) {
$data = pem_to_der($data);
return $self->_import_x509($data);
}
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elsif ($data =~ /---- BEGIN SSH2 PUBLIC KEY ----(.*?)---- END SSH2 PUBLIC KEY ----/sg) {
$data = pem_to_der($data);
my ($typ, $skip, $pubkey) = Crypt::PK::_ssh_parse($data);
return $self->import_key_raw($pubkey, "$2") if $pubkey && $typ =~ /^ecdsa-(.+?)-(.*)$/;
}
elsif ($data =~ /(ecdsa-\S+)\s+(\S+)/) {
$data = decode_b64("$2");
my ($typ, $skip, $pubkey) = Crypt::PK::_ssh_parse($data);
return $self->import_key_raw($pubkey, "$2") if $pubkey && $typ =~ /^ecdsa-(.+?)-(.*)$/;
}
else {
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my $rv = eval { $self->_import($data) } || eval { $self->_import_pkcs8($data, $password) } || eval { $self->_import_x509($data) };
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return $rv if $rv;
}
croak "FATAL: invalid or unsupported EC key format";
}
sub curve2hash {
my $self = shift;
my $kh = $self->key2hash;
return {
prime => $kh->{curve_prime},
A => $kh->{curve_A},
B => $kh->{curve_B},
Gx => $kh->{curve_Gx},
Gy => $kh->{curve_Gy},
cofactor => $kh->{curve_cofactor},
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order => $kh->{curve_order},
oid => $kh->{curve_oid},
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};
}
### FUNCTIONS
sub ecc_encrypt {
my $key = shift;
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local $SIG{__DIE__} = \&CryptX::_croak;
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$key = __PACKAGE__->new($key) unless ref $key;
carp "FATAL: invalid 'key' param" unless ref($key) eq __PACKAGE__;
return $key->encrypt(@_);
}
sub ecc_decrypt {
my $key = shift;
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local $SIG{__DIE__} = \&CryptX::_croak;
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$key = __PACKAGE__->new($key) unless ref $key;
carp "FATAL: invalid 'key' param" unless ref($key) eq __PACKAGE__;
return $key->decrypt(@_);
}
sub ecc_sign_message {
my $key = shift;
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local $SIG{__DIE__} = \&CryptX::_croak;
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$key = __PACKAGE__->new($key) unless ref $key;
carp "FATAL: invalid 'key' param" unless ref($key) eq __PACKAGE__;
return $key->sign_message(@_);
}
sub ecc_verify_message {
my $key = shift;
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local $SIG{__DIE__} = \&CryptX::_croak;
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$key = __PACKAGE__->new($key) unless ref $key;
carp "FATAL: invalid 'key' param" unless ref($key) eq __PACKAGE__;
return $key->verify_message(@_);
}
sub ecc_sign_hash {
my $key = shift;
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local $SIG{__DIE__} = \&CryptX::_croak;
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$key = __PACKAGE__->new($key) unless ref $key;
carp "FATAL: invalid 'key' param" unless ref($key) eq __PACKAGE__;
return $key->sign_hash(@_);
}
sub ecc_verify_hash {
my $key = shift;
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local $SIG{__DIE__} = \&CryptX::_croak;
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$key = __PACKAGE__->new($key) unless ref $key;
carp "FATAL: invalid 'key' param" unless ref($key) eq __PACKAGE__;
return $key->verify_hash(@_);
}
sub ecc_shared_secret {
my ($privkey, $pubkey) = @_;
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local $SIG{__DIE__} = \&CryptX::_croak;
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$privkey = __PACKAGE__->new($privkey) unless ref $privkey;
$pubkey = __PACKAGE__->new($pubkey) unless ref $pubkey;
carp "FATAL: invalid 'privkey' param" unless ref($privkey) eq __PACKAGE__ && $privkey->is_private;
carp "FATAL: invalid 'pubkey' param" unless ref($pubkey) eq __PACKAGE__;
return $privkey->shared_secret($pubkey);
}
sub CLONE_SKIP { 1 } # prevent cloning
1;
=pod
=head1 NAME
Crypt::PK::ECC - Public key cryptography based on EC
=head1 SYNOPSIS
### OO interface
#Encryption: Alice
my $pub = Crypt::PK::ECC->new('Bob_pub_ecc1.der');
my $ct = $pub->encrypt("secret message");
#
#Encryption: Bob (received ciphertext $ct)
my $priv = Crypt::PK::ECC->new('Bob_priv_ecc1.der');
my $pt = $priv->decrypt($ct);
#Signature: Alice
my $priv = Crypt::PK::ECC->new('Alice_priv_ecc1.der');
my $sig = $priv->sign_message($message);
#
#Signature: Bob (received $message + $sig)
my $pub = Crypt::PK::ECC->new('Alice_pub_ecc1.der');
$pub->verify_message($sig, $message) or die "ERROR";
#Shared secret
my $priv = Crypt::PK::ECC->new('Alice_priv_ecc1.der');
my $pub = Crypt::PK::ECC->new('Bob_pub_ecc1.der');
my $shared_secret = $priv->shared_secret($pub);
#Key generation
my $pk = Crypt::PK::ECC->new();
$pk->generate_key('secp160r1');
my $private_der = $pk->export_key_der('private');
my $public_der = $pk->export_key_der('public');
my $private_pem = $pk->export_key_pem('private');
my $public_pem = $pk->export_key_pem('public');
my $public_raw = $pk->export_key_raw('public');
### Functional interface
#Encryption: Alice
my $ct = ecc_encrypt('Bob_pub_ecc1.der', "secret message");
#Encryption: Bob (received ciphertext $ct)
my $pt = ecc_decrypt('Bob_priv_ecc1.der', $ct);
#Signature: Alice
my $sig = ecc_sign_message('Alice_priv_ecc1.der', $message);
#Signature: Bob (received $message + $sig)
ecc_verify_message('Alice_pub_ecc1.der', $sig, $message) or die "ERROR";
#Shared secret
my $shared_secret = ecc_shared_secret('Alice_priv_ecc1.der', 'Bob_pub_ecc1.der');
=head1 DESCRIPTION
The module provides a set of core ECC functions as well as implementation of ECDSA and ECDH.
Supports elliptic curves C<y^2 = x^3 + a*x + b> over prime fields C<Fp = Z/pZ> (binary fields not supported).
=head1 METHODS
=head2 new
my $pk = Crypt::PK::ECC->new();
#or
my $pk = Crypt::PK::ECC->new($priv_or_pub_key_filename);
#or
my $pk = Crypt::PK::ECC->new(\$buffer_containing_priv_or_pub_key);
Support for password protected PEM keys
my $pk = Crypt::PK::ECC->new($priv_pem_key_filename, $password);
#or
my $pk = Crypt::PK::ECC->new(\$buffer_containing_priv_pem_key, $password);
=head2 generate_key
Uses Yarrow-based cryptographically strong random number generator seeded with
random data taken from C</dev/random> (UNIX) or C<CryptGenRandom> (Win32).
$pk->generate_key($curve_name);
#or
$pk->generate_key($hashref_with_curve_params);
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The following predefined C<$curve_name> values are supported:
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# curves from http://www.ecc-brainpool.org/download/Domain-parameters.pdf
'brainpoolp160r1'
'brainpoolp192r1'
'brainpoolp224r1'
'brainpoolp256r1'
'brainpoolp320r1'
'brainpoolp384r1'
'brainpoolp512r1'
# curves from http://www.secg.org/collateral/sec2_final.pdf
'secp112r1'
'secp112r2'
'secp128r1'
'secp128r2'
'secp160k1'
'secp160r1'
'secp160r2'
'secp192k1'
'secp192r1' ... same as nistp192, prime192v1
'secp224k1'
'secp224r1' ... same as nistp224
'secp256k1' ... used by Bitcoin
'secp256r1' ... same as nistp256, prime256v1
'secp384r1' ... same as nistp384
'secp521r1' ... same as nistp521
#curves from http://nvlpubs.nist.gov/nistpubs/FIPS/NIST.FIPS.186-4.pdf
'nistp192' ... same as secp192r1, prime192v1
'nistp224' ... same as secp224r1
'nistp256' ... same as secp256r1, prime256v1
'nistp384' ... same as secp384r1
'nistp521' ... same as secp521r1
# curves from ANS X9.62
'prime192v1' ... same as nistp192, secp192r1
'prime192v2'
'prime192v3'
'prime239v1'
'prime239v2'
'prime239v3'
'prime256v1' ... same as nistp256, secp256r1
Using custom curve parameters:
$pk->generate_key({ prime => 'FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFFFFFFFFFFFF',
A => 'FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFFFFFFFFFFFC',
B => '22123DC2395A05CAA7423DAECCC94760A7D462256BD56916',
Gx => '7D29778100C65A1DA1783716588DCE2B8B4AEE8E228F1896',
Gy => '38A90F22637337334B49DCB66A6DC8F9978ACA7648A943B0',
order => 'FFFFFFFFFFFFFFFFFFFFFFFF7A62D031C83F4294F640EC13',
cofactor => 1 });
See L<http://nvlpubs.nist.gov/nistpubs/FIPS/NIST.FIPS.186-4.pdf>, L<http://www.secg.org/collateral/sec2_final.pdf>, L<http://www.ecc-brainpool.org/download/Domain-parameters.pdf>
=head2 import_key
Loads private or public key in DER or PEM format.
$pk->import_key($filename);
#or
$pk->import_key(\$buffer_containing_key);
Support for password protected PEM keys:
$pk->import_key($filename, $password);
#or
$pk->import_key(\$buffer_containing_key, $password);
Loading private or public keys form perl hash:
$pk->import_key($hashref);
# the $hashref is either a key exported via key2hash
$pk->import_key({
curve_A => "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF7FFFFFFC",
curve_B => "1C97BEFC54BD7A8B65ACF89F81D4D4ADC565FA45",
curve_bits => 160,
curve_bytes => 20,
curve_cofactor => 1,
curve_Gx => "4A96B5688EF573284664698968C38BB913CBFC82",
curve_Gy => "23A628553168947D59DCC912042351377AC5FB32",
curve_order => "0100000000000000000001F4C8F927AED3CA752257",
curve_prime => "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF7FFFFFFF",
k => "B0EE84A749FE95DF997E33B8F333E12101E824C3",
pub_x => "5AE1ACE3ED0AEA9707CE5C0BCE014F6A2F15023A",
pub_y => "895D57E992D0A15F88D6680B27B701F615FCDC0F",
});
# or with the curve defined just by name
$pk->import_key({
curve_name => "secp160r1",
k => "B0EE84A749FE95DF997E33B8F333E12101E824C3",
pub_x => "5AE1ACE3ED0AEA9707CE5C0BCE014F6A2F15023A",
pub_y => "895D57E992D0A15F88D6680B27B701F615FCDC0F",
});
# or a hash with items corresponding to JWK (JSON Web Key)
$pk->import_key({
kty => "EC",
crv => "P-256",
x => "MKBCTNIcKUSDii11ySs3526iDZ8AiTo7Tu6KPAqv7D4",
y => "4Etl6SRW2YiLUrN5vfvVHuhp7x8PxltmWWlbbM4IFyM",
d => "870MB6gfuTJ4HtUnUvYMyJpr5eUZNP4Bk43bVdj3eAE",
});
Supported key formats:
# all formats can be loaded from a file
my $pk = Crypt::PK::ECC->new($filename);
# or from a buffer containing the key
my $pk = Crypt::PK::ECC->new(\$buffer_with_key);
=over
=item * EC private keys with with all curve parameters
-----BEGIN EC PRIVATE KEY-----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-----END EC PRIVATE KEY-----
=item * EC private keys with curve defined by OID (short form)
-----BEGIN EC PRIVATE KEY-----
MHcCAQEEIBG1c3z52T8XwMsahGVdOZWgKCQJfv+l7djuJjgetdbDoAoGCCqGSM49
AwEHoUQDQgAEoBUyo8CQAFPeYPvv78ylh5MwFZjTCLQeb042TjiMJxG+9DLFmRSM
lBQ9T/RsLLc+PmpB1+7yPAR+oR5gZn3kJQ==
-----END EC PRIVATE KEY-----
=item * EC private keys in password protected PEM format
-----BEGIN EC PRIVATE KEY-----
Proc-Type: 4,ENCRYPTED
DEK-Info: AES-128-CBC,98245C830C9282F7937E13D1D5BA11EC
0Y85oZ2+BKXYwrkBjsZdj6gnhOAfS5yDVmEsxFCDug+R3+Kw3QvyIfO4MVo9iWoA
D7wtoRfbt2OlBaLVl553+6QrUoa2DyKf8kLHQs1x1/J7tJOMM4SCXjlrOaToQ0dT
o7fOnjQjHne16pjgBVqGilY/I79Ab85AnE4uw7vgEucBEiU0d3nrhwuS2Opnhzyx
009q9VLDPwY2+q7tXjTqnk9mCmQgsiaDJqY09wlauSukYPgVuOJFmi1VdkRSDKYZ
rUUsQvz6Q6Q+QirSlfHna+NhUgQ2eyhGszwcP6NU8iqIxI+NCwfFVuAzw539yYwS
8SICczoC/YRlaclayXuomQ==
-----END EC PRIVATE KEY-----
=item * EC public keys with all curve parameters
-----BEGIN PUBLIC KEY-----
MIH1MIGuBgcqhkjOPQIBMIGiAgEBMCwGByqGSM49AQECIQD/////////////////
///////////////////+///8LzAGBAEABAEHBEEEeb5mfvncu6xVoGKVzocLBwKb
/NstzijZWfKBWxb4F5hIOtp3JqPEZV2k+/wOEQio/Re0SKaFVBmcR9CP+xDUuAIh
AP////////////////////66rtzmr0igO7/SXozQNkFBAgEBA0IABITjF/nKK3jg
pjmBRXKWAv7ekR1Ko/Nb5FFPHXjH0sDrpS7qRxFALwJHv7ylGnekgfKU3vzcewNs
lvjpBYt0Yg4=
-----END PUBLIC KEY-----
=item * EC public keys with curve defined by OID (short form)
-----BEGIN PUBLIC KEY-----
MFkwEwYHKoZIzj0CAQYIKoZIzj0DAQcDQgAEoBUyo8CQAFPeYPvv78ylh5MwFZjT
CLQeb042TjiMJxG+9DLFmRSMlBQ9T/RsLLc+PmpB1+7yPAR+oR5gZn3kJQ==
-----END PUBLIC KEY-----
=item * PKCS#8 private keys with all curve parameters
-----BEGIN PRIVATE KEY-----
MIIBMAIBADCB0wYHKoZIzj0CATCBxwIBATAkBgcqhkjOPQEBAhkA////////////
/////////v//////////MEsEGP////////////////////7//////////AQYIhI9
wjlaBcqnQj2uzMlHYKfUYiVr1WkWAxUAxGloRDXes3jEtlypWR4qV2MFmi4EMQR9
KXeBAMZaHaF4NxZYjc4ri0rujiKPGJY4qQ8iY3M3M0tJ3LZqbcj5l4rKdkipQ7AC
GQD///////////////96YtAxyD9ClPZA7BMCAQEEVTBTAgEBBBiKolTGIsTgOCtl
6dpdos0LvuaExCDFyT6hNAMyAAREwaCX0VY1LZxLW3G75tmft4p9uhc0J7/+NGaP
DN3Tr7SXkT9+co2a+8KPJhQy10k=
-----END PRIVATE KEY-----
=item * PKCS#8 private keys with curve defined by OID (short form)
-----BEGIN PRIVATE KEY-----
MG8CAQAwEwYHKoZIzj0CAQYIKoZIzj0DAQMEVTBTAgEBBBjFP/caeQV4WO3fnWWS
f917PGzwtypd/t+hNAMyAATSg6pBT7RO6l/p+aKcrFsGuthUdfwJWS5V3NGcVt1b
lEHQYjWya2YnHaPq/iMFa7A=
-----END PRIVATE KEY-----
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=item * PKCS#8 encrypted private keys
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-----BEGIN ENCRYPTED PRIVATE KEY-----
MIGYMBwGCiqGSIb3DQEMAQMwDgQINApjTa6oFl0CAggABHi+59l4d4e6KtG9yci2
BSC65LEsQSnrnFAExfKptNU1zMFsDLCRvDeDQDbxc6HlfoxyqFL4SmH1g3RvC/Vv
NfckdL5O2L8MRnM+ljkFtV2Te4fszWcJFdd7KiNOkPpn+7sWLfzQdvhHChLKUzmz
4INKZyMv/G7VpZ0=
-----END ENCRYPTED PRIVATE KEY-----
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=item * EC public key from X509 certificate
-----BEGIN CERTIFICATE-----
MIIBdDCCARqgAwIBAgIJAL2BBClDEnnOMAoGCCqGSM49BAMEMBcxFTATBgNVBAMM
DFRlc3QgQ2VydCBFQzAgFw0xNzEyMzAyMDMzNDFaGA8zMDE3MDUwMjIwMzM0MVow
FzEVMBMGA1UEAwwMVGVzdCBDZXJ0IEVDMFYwEAYHKoZIzj0CAQYFK4EEAAoDQgAE
KvkL2r5xZp7RzxLQJK+6tn/7lic+L70e1fmNbHOdxRaRvbK5G0AQWrdsbjJb92Ni
lCQk2+w/i+VuS2Q3MSR5TaNQME4wHQYDVR0OBBYEFGbJkDyKgaMcIGHS8/WuqIVw
+R8sMB8GA1UdIwQYMBaAFGbJkDyKgaMcIGHS8/WuqIVw+R8sMAwGA1UdEwQFMAMB
Af8wCgYIKoZIzj0EAwQDSAAwRQIhAJtOsmrM+gJpImoynAyqTN+7myL71uxd+YeC
6ze4MnzWAiBQi5/BqEr/SQ1+BC2TPtswvJPRFh2ZvT/6Km3gKoNVXQ==
-----END CERTIFICATE-----
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=item * SSH public EC keys
ecdsa-sha2-nistp256 AAAAE2VjZHNhLXNoYTItbmlzdHAyNT...T3xYfJIs=
=item * SSH public EC keys (RFC-4716 format)
---- BEGIN SSH2 PUBLIC KEY ----
Comment: "521-bit ECDSA, converted from OpenSSH"
AAAAE2VjZHNhLXNoYTItbmlzdHA1MjEAAAAIbmlzdHA1MjEAAACFBAFk35srteP9twCwYK
vU9ovMBi77Dd6lEBPrFaMEb0CZdZ5MC3nSqflGHRWkSbUpjdPdO7cYQNpK9YXHbNSO5hbU
1gFZgyiGFxwJYYz8NAjedBXMgyH4JWplK5FQm5P5cvaglItC9qkKioUXhCc67YMYBtivXl
Ue0PgIq6kbHTqbX6+5Nw==
---- END SSH2 PUBLIC KEY ----
=item * EC private keys in JSON Web Key (JWK) format
See L<http://tools.ietf.org/html/draft-ietf-jose-json-web-key>
{
"kty":"EC",
"crv":"P-256",
"x":"MKBCTNIcKUSDii11ySs3526iDZ8AiTo7Tu6KPAqv7D4",
"y":"4Etl6SRW2YiLUrN5vfvVHuhp7x8PxltmWWlbbM4IFyM",
"d":"870MB6gfuTJ4HtUnUvYMyJpr5eUZNP4Bk43bVdj3eAE",
}
B<BEWARE:> For JWK support you need to have L<JSON::PP>, L<JSON::XS> or L<Cpanel::JSON::XS> module.
=item * EC public keys in JSON Web Key (JWK) format
{
"kty":"EC",
"crv":"P-256",
"x":"MKBCTNIcKUSDii11ySs3526iDZ8AiTo7Tu6KPAqv7D4",
"y":"4Etl6SRW2YiLUrN5vfvVHuhp7x8PxltmWWlbbM4IFyM",
}
B<BEWARE:> For JWK support you need to have L<JSON::PP>, L<JSON::XS> or L<Cpanel::JSON::XS> module.
=back
=head2 import_key_raw
Import raw public/private key - can load data exported by L</export_key_raw>.
$pk->import_key_raw($key, $curve);
# $key .... data exported by export_key_raw()
# $curve .. curve name or hashref with curve parameters - same as by generate_key()
=head2 export_key_der
my $private_der = $pk->export_key_der('private');
#or
my $public_der = $pk->export_key_der('public');
Since CryptX-0.36 C<export_key_der> can also export keys in a format
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that does not explicitly contain curve parameters but only curve OID.
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my $private_der = $pk->export_key_der('private_short');
#or
my $public_der = $pk->export_key_der('public_short');
=head2 export_key_pem
my $private_pem = $pk->export_key_pem('private');
#or
my $public_pem = $pk->export_key_pem('public');
Since CryptX-0.36 C<export_key_pem> can also export keys in a format
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that does not explicitly contain curve parameters but only curve OID.
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my $private_pem = $pk->export_key_pem('private_short');
#or
my $public_pem = $pk->export_key_pem('public_short');
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Since CryptX-0.58 C<export_key_pem> can also export keys in "compressed" format
that defines curve by OID + stores public point in compressed form.
my $private_pem = $pk->export_key_pem('private_compressed');
#or
my $public_pem = $pk->export_key_pem('public_compressed');
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Support for password protected PEM keys
my $private_pem = $pk->export_key_pem('private', $password);
#or
my $private_pem = $pk->export_key_pem('private', $password, $cipher);
# supported ciphers: 'DES-CBC'
# 'DES-EDE3-CBC'
# 'SEED-CBC'
# 'CAMELLIA-128-CBC'
# 'CAMELLIA-192-CBC'
# 'CAMELLIA-256-CBC'
# 'AES-128-CBC'
# 'AES-192-CBC'
# 'AES-256-CBC' (DEFAULT)
=head2 export_key_jwk
I<Since: CryptX-0.022>
Exports public/private keys as a JSON Web Key (JWK).
my $private_json_text = $pk->export_key_jwk('private');
#or
my $public_json_text = $pk->export_key_jwk('public');
Also exports public/private keys as a perl HASH with JWK structure.
my $jwk_hash = $pk->export_key_jwk('private', 1);
#or
my $jwk_hash = $pk->export_key_jwk('public', 1);
B<BEWARE:> For JWK support you need to have L<JSON::PP>, L<JSON::XS> or L<Cpanel::JSON::XS> module.
=head2 export_key_jwk_thumbprint
I<Since: CryptX-0.031>
Exports the key's JSON Web Key Thumbprint as a string.
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If you don't know what this is, see RFC 7638 L<https://tools.ietf.org/html/rfc7638>.
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my $thumbprint = $pk->export_key_jwk_thumbprint('SHA256');
=head2 export_key_raw
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Export raw public/private key. Public key is exported in ASN X9.62 format (compressed or uncompressed),
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private key is exported as raw bytes (padded with leading zeros to have the same size as the ECC curve).
my $pubkey_octets = $pk->export_key_raw('public');
#or
my $pubckey_octets = $pk->export_key_raw('public_compressed');
#or
my $privkey_octets = $pk->export_key_raw('private');
=head2 encrypt
my $pk = Crypt::PK::ECC->new($pub_key_filename);
my $ct = $pk->encrypt($message);
#or
my $ct = $pk->encrypt($message, $hash_name);
#NOTE: $hash_name can be 'SHA1' (DEFAULT), 'SHA256' or any other hash supported by Crypt::Digest
=head2 decrypt
my $pk = Crypt::PK::ECC->new($priv_key_filename);
my $pt = $pk->decrypt($ciphertext);
=head2 sign_message
my $pk = Crypt::PK::ECC->new($priv_key_filename);
my $signature = $priv->sign_message($message);
#or
my $signature = $priv->sign_message($message, $hash_name);
#NOTE: $hash_name can be 'SHA1' (DEFAULT), 'SHA256' or any other hash supported by Crypt::Digest
=head2 sign_message_rfc7518
I<Since: CryptX-0.024>
Same as L<sign_message|/sign_message> only the signature format is as defined by L<https://tools.ietf.org/html/rfc7518>
(JWA - JSON Web Algorithms).
=head2 verify_message
my $pk = Crypt::PK::ECC->new($pub_key_filename);
my $valid = $pub->verify_message($signature, $message)
#or
my $valid = $pub->verify_message($signature, $message, $hash_name);
#NOTE: $hash_name can be 'SHA1' (DEFAULT), 'SHA256' or any other hash supported by Crypt::Digest
=head2 verify_message_rfc7518
I<Since: CryptX-0.024>
Same as L<verify_message|/verify_message> only the signature format is as defined by L<https://tools.ietf.org/html/rfc7518>
(JWA - JSON Web Algorithms).
=head2 sign_hash
my $pk = Crypt::PK::ECC->new($priv_key_filename);
my $signature = $priv->sign_hash($message_hash);
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=head2 sign_hash_rfc7518
I<Since: CryptX-0.059>
Same as L<sign_hash|/sign_hash> only the signature format is as defined by L<https://tools.ietf.org/html/rfc7518>
(JWA - JSON Web Algorithms).
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=head2 verify_hash
my $pk = Crypt::PK::ECC->new($pub_key_filename);
my $valid = $pub->verify_hash($signature, $message_hash);
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=head2 verify_hash_rfc7518
I<Since: CryptX-0.059>
Same as L<verify_hash|/verify_hash> only the signature format is as defined by L<https://tools.ietf.org/html/rfc7518>
(JWA - JSON Web Algorithms).
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=head2 shared_secret
# Alice having her priv key $pk and Bob's public key $pkb
my $pk = Crypt::PK::ECC->new($priv_key_filename);
my $pkb = Crypt::PK::ECC->new($pub_key_filename);
my $shared_secret = $pk->shared_secret($pkb);
# Bob having his priv key $pk and Alice's public key $pka
my $pk = Crypt::PK::ECC->new($priv_key_filename);
my $pka = Crypt::PK::ECC->new($pub_key_filename);
my $shared_secret = $pk->shared_secret($pka); # same value as computed by Alice
=head2 is_private
my $rv = $pk->is_private;
# 1 .. private key loaded
# 0 .. public key loaded
# undef .. no key loaded
=head2 size
my $size = $pk->size;
# returns key size in bytes or undef if no key loaded
=head2 key2hash
my $hash = $pk->key2hash;
# returns hash like this (or undef if no key loaded):
{
size => 20, # integer: key (curve) size in bytes
type => 1, # integer: 1 .. private, 0 .. public
#curve parameters
curve_A => "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF7FFFFFFC",
curve_B => "1C97BEFC54BD7A8B65ACF89F81D4D4ADC565FA45",
curve_bits => 160,
curve_bytes => 20,
curve_cofactor => 1,
curve_Gx => "4A96B5688EF573284664698968C38BB913CBFC82",
curve_Gy => "23A628553168947D59DCC912042351377AC5FB32",
curve_name => "secp160r1",
curve_order => "0100000000000000000001F4C8F927AED3CA752257",
curve_prime => "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF7FFFFFFF",
#private key
k => "B0EE84A749FE95DF997E33B8F333E12101E824C3",
#public key point coordinates
pub_x => "5AE1ACE3ED0AEA9707CE5C0BCE014F6A2F15023A",
pub_y => "895D57E992D0A15F88D6680B27B701F615FCDC0F",
}
=head2 curve2hash
I<Since: CryptX-0.024>
my $crv = $pk->curve2hash;
# returns a hash that can be passed to: $pk->generate_key($crv)
{
A => "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF7FFFFFFC",
B => "1C97BEFC54BD7A8B65ACF89F81D4D4ADC565FA45",
cofactor => 1,
Gx => "4A96B5688EF573284664698968C38BB913CBFC82",
Gy => "23A628553168947D59DCC912042351377AC5FB32",
order => "0100000000000000000001F4C8F927AED3CA752257",
prime => "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF7FFFFFFF",
}
=head1 FUNCTIONS
=head2 ecc_encrypt
Elliptic Curve Diffie-Hellman (ECDH) encryption as implemented by libtomcrypt. See method L</encrypt> below.
my $ct = ecc_encrypt($pub_key_filename, $message);
#or
my $ct = ecc_encrypt(\$buffer_containing_pub_key, $message);
#or
my $ct = ecc_encrypt($pub_key_filename, $message, $hash_name);
#NOTE: $hash_name can be 'SHA1' (DEFAULT), 'SHA256' or any other hash supported by Crypt::Digest
ECCDH Encryption is performed by producing a random key, hashing it, and XOR'ing the digest against the plaintext.
=head2 ecc_decrypt
Elliptic Curve Diffie-Hellman (ECDH) decryption as implemented by libtomcrypt. See method L</decrypt> below.
my $pt = ecc_decrypt($priv_key_filename, $ciphertext);
#or
my $pt = ecc_decrypt(\$buffer_containing_priv_key, $ciphertext);
=head2 ecc_sign_message
Elliptic Curve Digital Signature Algorithm (ECDSA) - signature generation. See method L</sign_message> below.
my $sig = ecc_sign_message($priv_key_filename, $message);
#or
my $sig = ecc_sign_message(\$buffer_containing_priv_key, $message);
#or
my $sig = ecc_sign_message($priv_key, $message, $hash_name);
=head2 ecc_verify_message
Elliptic Curve Digital Signature Algorithm (ECDSA) - signature verification. See method L</verify_message> below.
ecc_verify_message($pub_key_filename, $signature, $message) or die "ERROR";
#or
ecc_verify_message(\$buffer_containing_pub_key, $signature, $message) or die "ERROR";
#or
ecc_verify_message($pub_key, $signature, $message, $hash_name) or die "ERROR";
=head2 ecc_sign_hash
Elliptic Curve Digital Signature Algorithm (ECDSA) - signature generation. See method L</sign_hash> below.
my $sig = ecc_sign_hash($priv_key_filename, $message_hash);
#or
my $sig = ecc_sign_hash(\$buffer_containing_priv_key, $message_hash);
=head2 ecc_verify_hash
Elliptic Curve Digital Signature Algorithm (ECDSA) - signature verification. See method L</verify_hash> below.
ecc_verify_hash($pub_key_filename, $signature, $message_hash) or die "ERROR";
#or
ecc_verify_hash(\$buffer_containing_pub_key, $signature, $message_hash) or die "ERROR";
=head2 ecc_shared_secret
Elliptic curve Diffie-Hellman (ECDH) - construct a Diffie-Hellman shared secret with a private and public ECC key. See method L</shared_secret> below.
#on Alice side
my $shared_secret = ecc_shared_secret('Alice_priv_ecc1.der', 'Bob_pub_ecc1.der');
#on Bob side
my $shared_secret = ecc_shared_secret('Bob_priv_ecc1.der', 'Alice_pub_ecc1.der');
=head1 OpenSSL interoperability
### let's have:
# ECC private key in PEM format - eckey.priv.pem
# ECC public key in PEM format - eckey.pub.pem
# data file to be signed - input.data
=head2 Sign by OpenSSL, verify by Crypt::PK::ECC
Create signature (from commandline):
openssl dgst -sha1 -sign eckey.priv.pem -out input.sha1-ec.sig input.data
Verify signature (Perl code):
use Crypt::PK::ECC;
use Crypt::Digest 'digest_file';
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use Crypt::Misc 'read_rawfile';
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my $pkec = Crypt::PK::ECC->new("eckey.pub.pem");
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my $signature = read_rawfile("input.sha1-ec.sig");
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my $valid = $pkec->verify_hash($signature, digest_file("SHA1", "input.data"), "SHA1", "v1.5");
print $valid ? "SUCCESS" : "FAILURE";
=head2 Sign by Crypt::PK::ECC, verify by OpenSSL
Create signature (Perl code):
use Crypt::PK::ECC;
use Crypt::Digest 'digest_file';
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use Crypt::Misc 'write_rawfile';
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my $pkec = Crypt::PK::ECC->new("eckey.priv.pem");
my $signature = $pkec->sign_hash(digest_file("SHA1", "input.data"), "SHA1", "v1.5");
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write_rawfile("input.sha1-ec.sig", $signature);
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Verify signature (from commandline):
openssl dgst -sha1 -verify eckey.pub.pem -signature input.sha1-ec.sig input.data
=head2 Keys generated by Crypt::PK::ECC
Generate keys (Perl code):
use Crypt::PK::ECC;
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use Crypt::Misc 'write_rawfile';
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my $pkec = Crypt::PK::ECC->new;
$pkec->generate_key('secp160k1');
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write_rawfile("eckey.pub.der", $pkec->export_key_der('public'));
write_rawfile("eckey.priv.der", $pkec->export_key_der('private'));
write_rawfile("eckey.pub.pem", $pkec->export_key_pem('public'));
write_rawfile("eckey.priv.pem", $pkec->export_key_pem('private'));
write_rawfile("eckey-passwd.priv.pem", $pkec->export_key_pem('private', 'secret'));
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Use keys by OpenSSL:
openssl ec -in eckey.priv.der -text -inform der
openssl ec -in eckey.priv.pem -text
openssl ec -in eckey-passwd.priv.pem -text -inform pem -passin pass:secret
openssl ec -in eckey.pub.der -pubin -text -inform der
openssl ec -in eckey.pub.pem -pubin -text
=head2 Keys generated by OpenSSL
Generate keys:
openssl ecparam -param_enc explicit -name prime192v3 -genkey -out eckey.priv.pem
openssl ec -param_enc explicit -in eckey.priv.pem -out eckey.pub.pem -pubout
openssl ec -param_enc explicit -in eckey.priv.pem -out eckey.priv.der -outform der
openssl ec -param_enc explicit -in eckey.priv.pem -out eckey.pub.der -outform der -pubout
openssl ec -param_enc explicit -in eckey.priv.pem -out eckey.privc.der -outform der -conv_form compressed
openssl ec -param_enc explicit -in eckey.priv.pem -out eckey.pubc.der -outform der -pubout -conv_form compressed
openssl ec -param_enc explicit -in eckey.priv.pem -passout pass:secret -des3 -out eckey-passwd.priv.pem
Load keys (Perl code):
use Crypt::PK::ECC;
my $pkec = Crypt::PK::ECC->new;
$pkec->import_key("eckey.pub.der");
$pkec->import_key("eckey.pubc.der");
$pkec->import_key("eckey.priv.der");
$pkec->import_key("eckey.privc.der");
$pkec->import_key("eckey.pub.pem");
$pkec->import_key("eckey.priv.pem");
$pkec->import_key("eckey-passwd.priv.pem", "secret");
=head1 SEE ALSO
=over
=item * L<https://en.wikipedia.org/wiki/Elliptic_curve_cryptography|https://en.wikipedia.org/wiki/Elliptic_curve_cryptography>
=item * L<https://en.wikipedia.org/wiki/Elliptic_curve_Diffie%E2%80%93Hellman|https://en.wikipedia.org/wiki/Elliptic_curve_Diffie%E2%80%93Hellman>
=item * L<https://en.wikipedia.org/wiki/ECDSA|https://en.wikipedia.org/wiki/ECDSA>
=back
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=cut