AnyEvent-MP/MP/Transport.pm

=head1 NAME

AnyEvent::MP::Transport - actual transport protocol handler

=head1 SYNOPSIS

   use AnyEvent::MP::Transport;

=head1 DESCRIPTION

This module implements (and documents) the actual transport protocol for
AEMP.

See the "PROTOCOL" section below if you want to write another client for
this protocol.

=head1 FUNCTIONS/METHODS

=over 4

=cut

package AnyEvent::MP::Transport;

use common::sense;

use Scalar::Util ();
use List::Util ();
use MIME::Base64 ();
use Storable ();
use JSON::XS ();

use Digest::MD6 ();
use Digest::HMAC_MD6 ();

use AE ();
use AnyEvent::Socket ();
use AnyEvent::Handle 4.92 ();

use AnyEvent::MP::Config ();

our $PROTOCOL_VERSION = 0;

=item $listener = mp_listener $host, $port, <constructor-args>

Creates a listener on the given host/port using
C<AnyEvent::Socket::tcp_server>.

See C<new>, below, for constructor arguments.

Defaults for peerhost, peerport and fh are provided.

=cut

sub mp_server($$;%) {
   my ($host, $port, %arg) = @_;

   AnyEvent::Socket::tcp_server $host, $port, sub {
      my ($fh, $host, $port) = @_;

      my $tp = new AnyEvent::MP::Transport
         fh       => $fh,
         peerhost => $host,
         peerport => $port,
         %arg,
      ;
      $tp->{keepalive} = $tp;
   }, delete $arg{prepare}
}

=item $guard = mp_connect $host, $port, <constructor-args>, $cb->($transport)

=cut

sub mp_connect {
   my $release = pop;
   my ($host, $port, @args) = @_;

   my $state;

   $state = AnyEvent::Socket::tcp_connect $host, $port, my$x=sub {
      my ($fh, $nhost, $nport) = @_;

      return $release->() unless $fh;

      $state = new AnyEvent::MP::Transport
         fh       => $fh,
         peername => $host,
         peerhost => $nhost,
         peerport => $nport,
         release  => $release,
         @args,
      ;
   };

   \$state
}

=item new AnyEvent::MP::Transport

   # immediately starts negotiation
   my $transport = new AnyEvent::MP::Transport
      # mandatory
      fh       => $filehandle,
      local_id => $identifier,
      on_recv  => sub { receive-callback },
      on_error => sub { error-callback },

      # optional
      on_eof   => sub { clean-close-callback },
      on_connect => sub { successful-connect-callback },
      greeting => { key => value },

      # tls support
      tls_ctx  => AnyEvent::TLS,
      peername => $peername, # for verification
   ;

=cut

sub LATENCY() { 3 } # assumed max. network latency

our @FRAMINGS = qw(json storable); # the framing types we accept and send, in order of preference
our @AUTH_SND = qw(tls_md6_64_256 hmac_md6_64_256); # auth types we send
our @AUTH_RCV = (@AUTH_SND, qw(tls_anon cleartext)); # auth types we accept

#AnyEvent::Handle::register_write_type mp_record => sub {
#};

sub new {
   my ($class, %arg) = @_;

   my $self = bless \%arg, $class;

   $self->{queue} = [];

   {
      Scalar::Util::weaken (my $self = $self);

      my $config = AnyEvent::MP::Config::config;

      my $latency = $config->{network_latency} || LATENCY;

      $self->{secret} = $config->{secret}
         unless exists $self->{secret};

      $self->{timeout} = $config->{monitor_timeout} || $AnyEvent::MP::Kernel::MONITOR_TIMEOUT
         unless exists $self->{timeout};

      $self->{timeout} -= $latency;

      $self->{timeout} = 1 + $latency
         if $self->{timeout} < 1 + $latency;

      my $secret = $self->{secret};

      if (exists $config->{cert}) {
         $self->{tls_ctx} = {
            sslv2   => 0,
            sslv3   => 0,
            tlsv1   => 1,
            verify  => 1,
            cert    => $config->{cert},
            ca_cert => $config->{cert},
            verify_require_client_cert => 1,
         };
      }

      $self->{hdl} = new AnyEvent::Handle
         fh       => delete $self->{fh},
         autocork => 1,
         no_delay => 1,
         on_error => sub {
            $self->error ($_[2]);
         },
         rtimeout => $latency,
         peername => delete $self->{peername},
      ;

      my $greeting_kv = $self->{greeting} ||= {};

      $self->{local_node} ||= $AnyEvent::MP::Kernel::NODE;

      $greeting_kv->{tls}      = "1.0" if $self->{tls_ctx};
      $greeting_kv->{provider} = "AE-$AnyEvent::MP::Kernel::VERSION";
      $greeting_kv->{peeraddr} = AnyEvent::Socket::format_hostport $self->{peerhost}, $self->{peerport};
      $greeting_kv->{timeout}  = $self->{timeout};

      # send greeting
      my $lgreeting1 = "aemp;$PROTOCOL_VERSION"
                     . ";$self->{local_node}"
                     . ";" . (join ",", @AUTH_RCV)
                     . ";" . (join ",", @FRAMINGS)
                     . (join "", map ";$_=$greeting_kv->{$_}", keys %$greeting_kv);

      my $lgreeting2 = MIME::Base64::encode_base64 AnyEvent::MP::Kernel::nonce (66), "";

      $self->{hdl}->push_write ("$lgreeting1\012$lgreeting2\012");

      # expect greeting
      $self->{hdl}->rbuf_max (4 * 1024);
      $self->{hdl}->push_read (line => sub {
         my $rgreeting1 = $_[1];

         my ($aemp, $version, $rnode, $auths, $framings, @kv) = split /;/, $rgreeting1;

         if ($aemp ne "aemp") {
            return $self->error ("unparsable greeting");
         } elsif ($version != $PROTOCOL_VERSION) {
            return $self->error ("version mismatch (we: $PROTOCOL_VERSION, they: $version)");
         } elsif ($rnode eq $self->{local_node}) {
            AnyEvent::MP::Global::avoid_seed ($self->{seed})
               if exists $self->{seed};

            return $self->error ("I refuse to talk to myself");
         } elsif ($AnyEvent::MP::Kernel::NODE{$rnode} && $AnyEvent::MP::Kernel::NODE{$rnode}{transport}) {
            return $self->error ("$rnode already connected, not connecting again.");
         }

         $self->{remote_node} = $rnode;

         $self->{remote_greeting} = {
            map /^([^=]+)(?:=(.*))?/ ? ($1 => $2) : (),
               @kv
         };

         # read nonce
         $self->{hdl}->push_read (line => sub {
            my $rgreeting2 = $_[1];

            "$lgreeting1\012$lgreeting2" ne "$rgreeting1\012$rgreeting2" # echo attack?
               or return $self->error ("authentication error, echo attack?");

            my $tls = $self->{tls_ctx} && 1 == int $self->{remote_greeting}{tls};

            my $s_auth;
            for my $auth_ (split /,/, $auths) {
               if (grep $auth_ eq $_, @AUTH_SND and ($auth_ !~ /^tls_/ or $tls)) {
                  $s_auth = $auth_;
                  last;
               }
            }

            defined $s_auth
               or return $self->error ("$auths: no common auth type supported");

            my $s_framing;
            for my $framing_ (split /,/, $framings) {
               if (grep $framing_ eq $_, @FRAMINGS) {
                  $s_framing = $framing_;
                  last;
               }
            }

            defined $s_framing
               or return $self->error ("$framings: no common framing method supported");

            my $key;
            my $lauth;

            if ($tls) {
               $self->{tls} = $lgreeting2 lt $rgreeting2 ? "connect" : "accept";
               $self->{hdl}->starttls ($self->{tls}, $self->{tls_ctx});

               $lauth =
                  $s_auth eq "tls_anon"       ? ""
                : $s_auth eq "tls_md6_64_256" ? Digest::MD6::md6_hex "$lgreeting1\012$lgreeting2\012$rgreeting1\012$rgreeting2\012"
                : return $self->error ("$s_auth: fatal, selected unsupported snd auth method");

            } elsif (length $secret) {
               return $self->error ("$s_auth: fatal, selected unsupported snd auth method")
                  unless $s_auth eq "hmac_md6_64_256"; # hardcoded atm.

               $key = Digest::MD6::md6 $secret;
               # we currently only support hmac_md6_64_256
               $lauth = Digest::HMAC_MD6::hmac_md6_hex $key, "$lgreeting1\012$lgreeting2\012$rgreeting1\012$rgreeting2\012", 64, 256;

            } else {
               return $self->error ("unable to handshake TLS and no shared secret configured");
            }

            $self->{hdl}->push_write ("$s_auth;$lauth;$s_framing\012");

            # read the authentication response
            $self->{hdl}->push_read (line => sub {
               my ($hdl, $rline) = @_;

               my ($auth_method, $rauth2, $r_framing) = split /;/, $rline;

               my $rauth =
                  $auth_method eq "hmac_md6_64_256" ? Digest::HMAC_MD6::hmac_md6_hex $key, "$rgreeting1\012$rgreeting2\012$lgreeting1\012$lgreeting2\012", 64, 256
                : $auth_method eq "cleartext"       ? unpack "H*", $secret
                : $auth_method eq "tls_anon"        ? ($tls ? "" : "\012\012") # \012\012 never matches
                : $auth_method eq "tls_md6_64_256"  ? ($tls ? Digest::MD6::md6_hex "$rgreeting1\012$rgreeting2\012$lgreeting1\012$lgreeting2\012" : "\012\012")
                : return $self->error ("$auth_method: fatal, selected unsupported rcv auth method");

               if ($rauth2 ne $rauth) {
                  return $self->error ("authentication failure/shared secret mismatch");
               }

               $self->{s_framing} = $s_framing;

               $hdl->rbuf_max (undef);
               my $queue = delete $self->{queue}; # we are connected

               $self->{hdl}->rtimeout ($self->{remote_greeting}{timeout});
               $self->{hdl}->wtimeout ($self->{timeout} - LATENCY);
               $self->{hdl}->on_wtimeout (sub { $self->send ([]) });

               $self->connected;

               # send queued messages
               $self->send ($_)
                  for @$queue;

               # receive handling
               my $src_node = $self->{node};
               my $rmsg; $rmsg = $self->{rmsg} = sub {
                  $_[0]->push_read ($r_framing => $rmsg);

                  local $AnyEvent::MP::Kernel::SRCNODE = $src_node;
                  AnyEvent::MP::Kernel::_inject (@{ $_[1] });
               };
               $hdl->push_read ($r_framing => $rmsg);

               Scalar::Util::weaken $rmsg;
               Scalar::Util::weaken $src_node;
            });
         });
      });
   }

   $self
}

sub error {
   my ($self, $msg) = @_;

   delete $self->{keepalive};

#   $AnyEvent::MP::Kernel::WARN->(9, "$self->{peerhost}:$self->{peerport} $msg");#d#

   $self->{node}->transport_error (transport_error => $self->{node}{id}, $msg)
      if $self->{node} && $self->{node}{transport} == $self;

   (delete $self->{release})->()
      if exists $self->{release};
   
#   $AnyEvent::MP::Kernel::WARN->(7, "$self->{peerhost}:$self->{peerport}: $msg");
   $self->destroy;
}

sub connected {
   my ($self) = @_;

   delete $self->{keepalive};

   (delete $self->{release})->()
      if exists $self->{release};

   $AnyEvent::MP::Kernel::WARN->(9, "$self->{peerhost}:$self->{peerport} connected as $self->{remote_node}");

   my $node = AnyEvent::MP::Kernel::add_node ($self->{remote_node});
   Scalar::Util::weaken ($self->{node} = $node);
   $node->transport_connect ($self);
}

sub send {
   $_[0]{hdl}->push_write ($_[0]{s_framing} => $_[1]);
}

sub destroy {
   my ($self) = @_;

   (delete $self->{release})->()
      if exists $self->{release};

   $self->{hdl}->destroy
      if $self->{hdl};
}

sub DESTROY {
   my ($self) = @_;

   $self->destroy;
}

=back

=head1 PROTOCOL

The AEMP protocol is relatively simple, and consists of three phases which
are symmetrical for both sides: greeting (followed by optionally switching
to TLS mode), authentication and packet exchange.

The protocol is designed to allow both full-text and binary streams.

The greeting consists of two text lines that are ended by either an ASCII
CR LF pair, or a single ASCII LF (recommended).

=head2 GREETING

All the lines until after authentication must not exceed 4kb in length,
including line delimiter. Afterwards there is no limit on the packet size
that can be received.

=head3 First Greeting Line

Example:

   aemp;0;rain;tls_md6_64_256,hmac_md6_64_256,tls_anon,cleartext;json,storable;timeout=12;peeraddr=10.0.0.1:48082

The first line contains strings separated (not ended) by C<;>
characters. The first five strings are fixed by the protocol, the
remaining strings are C<KEY=VALUE> pairs. None of them may contain C<;>
characters themselves (when escaping is needed, use C<%3b> to represent
C<;> and C<%25> to represent C<%>)-

The fixed strings are:

=over 4

=item protocol identification

The constant C<aemp> to identify this protocol.

=item protocol version

The protocol version supported by this end, currently C<0>. If the
versions don't match then no communication is possible. Minor extensions
are supposed to be handled through additional key-value pairs.

=item the node ID

This is the node ID of the connecting node.

=item the acceptable authentication methods

A comma-separated list of authentication methods supported by the
node. Note that AnyEvent::MP supports a C<hex_secret> authentication
method that accepts a clear-text password (hex-encoded), but will not use
this authentication method itself.

The receiving side should choose the first authentication method it
supports.

=item the acceptable framing formats

A comma-separated list of packet encoding/framing formats understood. The
receiving side should choose the first framing format it supports for
sending packets (which might be different from the format it has to accept).

=back

The remaining arguments are C<KEY=VALUE> pairs. The following key-value
pairs are known at this time:

=over 4

=item timeout=<seconds>

The amount of time after which this node should be detected as dead unless
some data has been received. The node is responsible to send traffic
reasonably more often than this interval (such as every timeout minus five
seconds).

=item provider=<module-version>

The software provider for this implementation. For AnyEvent::MP, this is
C<AE-0.0> or whatever version it currently is at.

=item peeraddr=<host>:<port>

The peer address (socket address of the other side) as seen locally.

=item tls=<major>.<minor>

Indicates that the other side supports TLS (version should be 1.0) and
wishes to do a TLS handshake.

=back

=head3 Second Greeting Line

After this greeting line there will be a second line containing a
cryptographic nonce, i.e. random data of high quality. To keep the
protocol text-only, these are usually 32 base64-encoded octets, but
it could be anything that doesn't contain any ASCII CR or ASCII LF
characters.

I<< The two nonces B<must> be different, and an aemp implementation
B<must> check and fail when they are identical >>.

Example of a nonce line (yes, it's random-looking because it is random
data):

   2XYhdG7/O6epFa4wuP0ujAEx1rXYWRcOypjUYK7eF6yWAQr7gwIN9m/2+mVvBrTPXz5GJDgfGm9d8QRABAbmAP/s

=head2 TLS handshake

I<< If, after the handshake, both sides indicate interest in TLS, then the
connection B<must> use TLS, or fail to continue. >>

Both sides compare their nonces, and the side who sent the lower nonce
value ("string" comparison on the raw octet values) becomes the client,
and the one with the higher nonce the server.

=head2 AUTHENTICATION PHASE

After the greeting is received (and the optional TLS handshake),
the authentication phase begins, which consists of sending a single
C<;>-separated line with three fixed strings and any number of
C<KEY=VALUE> pairs.

The three fixed strings are:

=over 4

=item the authentication method chosen

This must be one of the methods offered by the other side in the greeting.

Note that all methods starting with C<tls_> are only valid I<iff> TLS was
successfully handshaked (and to be secure the implementation must enforce
this).

The currently supported authentication methods are:

=over 4

=item cleartext

This is simply the shared secret, lowercase-hex-encoded. This method is of
course very insecure if TLS is not used (and not completely secure even
if TLS is used), which is why this module will accept, but not generate,
cleartext auth replies.

=item hmac_md6_64_256

This method uses an MD6 HMAC with 64 bit blocksize and 256 bit hash, and
requires a shared secret. It is the preferred auth method when a shared
secret is available.

First, the shared secret is hashed with MD6:

   key = MD6 (secret)

This secret is then used to generate the "local auth reply", by taking
the two local greeting lines and the two remote greeting lines (without
line endings), appending \012 to all of them, concatenating them and
calculating the MD6 HMAC with the key:

   lauth = HMAC_MD6 key, "lgreeting1\012lgreeting2\012rgreeting1\012rgreeting2\012"

This authentication token is then lowercase-hex-encoded and sent to the
other side.

Then the remote auth reply is generated using the same method, but local
and remote greeting lines swapped:

   rauth = HMAC_MD6 key, "rgreeting1\012rgreeting2\012lgreeting1\012lgreeting2\012"

This is the token that is expected from the other side.

=item tls_anon

This type is only valid I<iff> TLS was enabled and the TLS handshake
was successful. It has no authentication data, as the server/client
certificate was successfully verified.

This authentication type is somewhat insecure, as it allows a
man-in-the-middle attacker to change some of the connection parameters
(such as the framing format), although there is no known attack that
exploits this in a way that is worse than just denying the service.

By default, this implementation accepts but never generates this auth
reply.

=item tls_md6_64_256

This type is only valid I<iff> TLS was enabled and the TLS handshake was
successful.

This authentication type simply calculates:

   lauth = MD6 "rgreeting1\012rgreeting2\012lgreeting1\012lgreeting2\012"

and lowercase-hex encodes the result and sends it as authentication
data. No shared secret is required (authentication is done by TLS). The
checksum exists only to make tinkering with the greeting hard.

=back

=item the authentication data

The authentication data itself, usually base64 or hex-encoded data, see
above.

=item the framing protocol chosen

This must be one of the framing protocols offered by the other side in the
greeting. Each side must accept the choice of the other side, and generate
packets in the format it chose itself.

=back

Example of an authentication reply:

   hmac_md6_64_256;363d5175df38bd9eaddd3f6ca18aa1c0c4aa22f0da245ac638d048398c26b8d3;json

=head2 DATA PHASE

After this, packets get exchanged using the chosen framing protocol. It is
quite possible that both sides use a different framing protocol.

=head2 FULL EXAMPLE

This is an actual protocol dump of a handshake, followed by a single data
packet. The greater than/less than lines indicate the direction of the
transfer only.

   > aemp;0;anon/57Cs1CggVJjzYaQp13XXg4;tls_md6_64_256,hmac_md6_64_256,tls_anon,cleartext;json,storable;provider=AE-0.8;timeout=12;peeraddr=10.0.0.17:4040
   > yLgdG1ov/02shVkVQer3wzeuywZK+oraTdEQBmIqWHaegxSGDG4g+HqogLQbvdypFOsoDWJ1Sh4ImV4DMhvUBwTK

   < aemp;0;ruth;tls_md6_64_256,hmac_md6_64_256,tls_anon,cleartext;json,storable;provider=AE-0.8;timeout=12;peeraddr=10.0.0.1:37108
   < +xMQXP8ElfNmuvEhsmcp+s2wCJOuQAsPxSg3d2Ewhs6gBnJz+ypVdWJ/wAVrXqlIJfLeVS/CBy4gEGkyWHSuVb1L

   > hmac_md6_64_256;5ad913855742ae5a03a5aeb7eafa4c78629de136bed6acd73eea36c9e98df44a;json

   < hmac_md6_64_256;84cd590976f794914c2ca26dac3a207a57a6798b9171289c114de07cf0c20401;json
   < ["","AnyEvent::MP::_spawn","57Cs1CggVJjzYaQp13XXg4.c","AnyEvent::MP::Global::connect",0,"anon/57Cs1CggVJjzYaQp13XXg4"]
   ...

The shared secret in use was C<8ugxrtw6H5tKnfPWfaSr4HGhE8MoJXmzTT1BWq7sLutNcD0IbXprQlZjIbl7MBKoeklG3IEfY9GlJthC0pENzk>.

=head1 SEE ALSO

L<AnyEvent::MP>.

=head1 AUTHOR

 Marc Lehmann <schmorp@schmorp.de>
 http://home.schmorp.de/

=cut

1

Revision:	1.46
Committed:	Sun Aug 30 19:49:47 2009 UTC (14 years, 10 months ago) by root
Branch:	MAIN
Changes since 1.45:	+4 -4 lines
Log Message:	* empty log message *
#	Content
1	=head1 NAME
2
3	AnyEvent::MP::Transport - actual transport protocol handler
4
5	=head1 SYNOPSIS
6
7	use AnyEvent::MP::Transport;
8
9	=head1 DESCRIPTION
10
11	This module implements (and documents) the actual transport protocol for
12	AEMP.
13
14	See the "PROTOCOL" section below if you want to write another client for
15	this protocol.
16
17	=head1 FUNCTIONS/METHODS
18
19	=over 4
20
21	=cut
22
23	package AnyEvent::MP::Transport;
24
25	use common::sense;
26
27	use Scalar::Util ();
28	use List::Util ();
29	use MIME::Base64 ();
30	use Storable ();
31	use JSON::XS ();
32
33	use Digest::MD6 ();
34	use Digest::HMAC_MD6 ();
35
36	use AE ();
37	use AnyEvent::Socket ();
38	use AnyEvent::Handle 4.92 ();
39
40	use AnyEvent::MP::Config ();
41
42	our $PROTOCOL_VERSION = 0;
43
44	=item $listener = mp_listener $host, $port, <constructor-args>
45
46	Creates a listener on the given host/port using
47	C<AnyEvent::Socket::tcp_server>.
48
49	See C<new>, below, for constructor arguments.
50
51	Defaults for peerhost, peerport and fh are provided.
52
53	=cut
54
55	sub mp_server($$;%) {
56	my ($host, $port, %arg) = @_;
57
58	AnyEvent::Socket::tcp_server $host, $port, sub {
59	my ($fh, $host, $port) = @_;
60
61	my $tp = new AnyEvent::MP::Transport
62	fh => $fh,
63	peerhost => $host,
64	peerport => $port,
65	%arg,
66	;
67	$tp->{keepalive} = $tp;
68	}, delete $arg{prepare}
69	}
70
71	=item $guard = mp_connect $host, $port, <constructor-args>, $cb->($transport)
72
73	=cut
74
75	sub mp_connect {
76	my $release = pop;
77	my ($host, $port, @args) = @_;
78
79	my $state;
80
81	$state = AnyEvent::Socket::tcp_connect $host, $port, my$x=sub {
82	my ($fh, $nhost, $nport) = @_;
83
84	return $release->() unless $fh;
85
86	$state = new AnyEvent::MP::Transport
87	fh => $fh,
88	peername => $host,
89	peerhost => $nhost,
90	peerport => $nport,
91	release => $release,
92	@args,
93	;
94	};
95
96	\$state
97	}
98
99	=item new AnyEvent::MP::Transport
100
101	# immediately starts negotiation
102	my $transport = new AnyEvent::MP::Transport
103	# mandatory
104	fh => $filehandle,
105	local_id => $identifier,
106	on_recv => sub { receive-callback },
107	on_error => sub { error-callback },
108
109	# optional
110	on_eof => sub { clean-close-callback },
111	on_connect => sub { successful-connect-callback },
112	greeting => { key => value },
113
114	# tls support
115	tls_ctx => AnyEvent::TLS,
116	peername => $peername, # for verification
117	;
118
119	=cut
120
121	sub LATENCY() { 3 } # assumed max. network latency
122
123	our @FRAMINGS = qw(json storable); # the framing types we accept and send, in order of preference
124	our @AUTH_SND = qw(tls_md6_64_256 hmac_md6_64_256); # auth types we send
125	our @AUTH_RCV = (@AUTH_SND, qw(tls_anon cleartext)); # auth types we accept
126
127	#AnyEvent::Handle::register_write_type mp_record => sub {
128	#};
129
130	sub new {
131	my ($class, %arg) = @_;
132
133	my $self = bless \%arg, $class;
134
135	$self->{queue} = [];
136
137	{
138	Scalar::Util::weaken (my $self = $self);
139
140	my $config = AnyEvent::MP::Config::config;
141
142	my $latency = $config->{network_latency} \|\| LATENCY;
143
144	$self->{secret} = $config->{secret}
145	unless exists $self->{secret};
146
147	$self->{timeout} = $config->{monitor_timeout} \|\| $AnyEvent::MP::Kernel::MONITOR_TIMEOUT
148	unless exists $self->{timeout};
149
150	$self->{timeout} -= $latency;
151
152	$self->{timeout} = 1 + $latency
153	if $self->{timeout} < 1 + $latency;
154
155	my $secret = $self->{secret};
156
157	if (exists $config->{cert}) {
158	$self->{tls_ctx} = {
159	sslv2 => 0,
160	sslv3 => 0,
161	tlsv1 => 1,
162	verify => 1,
163	cert => $config->{cert},
164	ca_cert => $config->{cert},
165	verify_require_client_cert => 1,
166	};
167	}
168
169	$self->{hdl} = new AnyEvent::Handle
170	fh => delete $self->{fh},
171	autocork => 1,
172	no_delay => 1,
173	on_error => sub {
174	$self->error ($_[2]);
175	},
176	rtimeout => $latency,
177	peername => delete $self->{peername},
178	;
179
180	my $greeting_kv = $self->{greeting} \|\|= {};
181
182	$self->{local_node} \|\|= $AnyEvent::MP::Kernel::NODE;
183
184	$greeting_kv->{tls} = "1.0" if $self->{tls_ctx};
185	$greeting_kv->{provider} = "AE-$AnyEvent::MP::Kernel::VERSION";
186	$greeting_kv->{peeraddr} = AnyEvent::Socket::format_hostport $self->{peerhost}, $self->{peerport};
187	$greeting_kv->{timeout} = $self->{timeout};
188
189	# send greeting
190	my $lgreeting1 = "aemp;$PROTOCOL_VERSION"
191	. ";$self->{local_node}"
192	. ";" . (join ",", @AUTH_RCV)
193	. ";" . (join ",", @FRAMINGS)
194	. (join "", map ";$_=$greeting_kv->{$_}", keys %$greeting_kv);
195
196	my $lgreeting2 = MIME::Base64::encode_base64 AnyEvent::MP::Kernel::nonce (66), "";
197
198	$self->{hdl}->push_write ("$lgreeting1\012$lgreeting2\012");
199
200	# expect greeting
201	$self->{hdl}->rbuf_max (4 * 1024);
202	$self->{hdl}->push_read (line => sub {
203	my $rgreeting1 = $_[1];
204
205	my ($aemp, $version, $rnode, $auths, $framings, @kv) = split /;/, $rgreeting1;
206
207	if ($aemp ne "aemp") {
208	return $self->error ("unparsable greeting");
209	} elsif ($version != $PROTOCOL_VERSION) {
210	return $self->error ("version mismatch (we: $PROTOCOL_VERSION, they: $version)");
211	} elsif ($rnode eq $self->{local_node}) {
212	AnyEvent::MP::Global::avoid_seed ($self->{seed})
213	if exists $self->{seed};
214
215	return $self->error ("I refuse to talk to myself");
216	} elsif ($AnyEvent::MP::Kernel::NODE{$rnode} && $AnyEvent::MP::Kernel::NODE{$rnode}{transport}) {
217	return $self->error ("$rnode already connected, not connecting again.");
218	}
219
220	$self->{remote_node} = $rnode;
221
222	$self->{remote_greeting} = {
223	map /^([^=]+)(?:=(.*))?/ ? ($1 => $2) : (),
224	@kv
225	};
226
227	# read nonce
228	$self->{hdl}->push_read (line => sub {
229	my $rgreeting2 = $_[1];
230
231	"$lgreeting1\012$lgreeting2" ne "$rgreeting1\012$rgreeting2" # echo attack?
232	or return $self->error ("authentication error, echo attack?");
233
234	my $tls = $self->{tls_ctx} && 1 == int $self->{remote_greeting}{tls};
235
236	my $s_auth;
237	for my $auth_ (split /,/, $auths) {
238	if (grep $auth_ eq $_, @AUTH_SND and ($auth_ !~ /^tls_/ or $tls)) {
239	$s_auth = $auth_;
240	last;
241	}
242	}
243
244	defined $s_auth
245	or return $self->error ("$auths: no common auth type supported");
246
247	my $s_framing;
248	for my $framing_ (split /,/, $framings) {
249	if (grep $framing_ eq $_, @FRAMINGS) {
250	$s_framing = $framing_;
251	last;
252	}
253	}
254
255	defined $s_framing
256	or return $self->error ("$framings: no common framing method supported");
257
258	my $key;
259	my $lauth;
260
261	if ($tls) {
262	$self->{tls} = $lgreeting2 lt $rgreeting2 ? "connect" : "accept";
263	$self->{hdl}->starttls ($self->{tls}, $self->{tls_ctx});
264
265	$lauth =
266	$s_auth eq "tls_anon" ? ""
267	: $s_auth eq "tls_md6_64_256" ? Digest::MD6::md6_hex "$lgreeting1\012$lgreeting2\012$rgreeting1\012$rgreeting2\012"
268	: return $self->error ("$s_auth: fatal, selected unsupported snd auth method");
269
270	} elsif (length $secret) {
271	return $self->error ("$s_auth: fatal, selected unsupported snd auth method")
272	unless $s_auth eq "hmac_md6_64_256"; # hardcoded atm.
273
274	$key = Digest::MD6::md6 $secret;
275	# we currently only support hmac_md6_64_256
276	$lauth = Digest::HMAC_MD6::hmac_md6_hex $key, "$lgreeting1\012$lgreeting2\012$rgreeting1\012$rgreeting2\012", 64, 256;
277
278	} else {
279	return $self->error ("unable to handshake TLS and no shared secret configured");
280	}
281
282	$self->{hdl}->push_write ("$s_auth;$lauth;$s_framing\012");
283
284	# read the authentication response
285	$self->{hdl}->push_read (line => sub {
286	my ($hdl, $rline) = @_;
287
288	my ($auth_method, $rauth2, $r_framing) = split /;/, $rline;
289
290	my $rauth =
291	$auth_method eq "hmac_md6_64_256" ? Digest::HMAC_MD6::hmac_md6_hex $key, "$rgreeting1\012$rgreeting2\012$lgreeting1\012$lgreeting2\012", 64, 256
292	: $auth_method eq "cleartext" ? unpack "H*", $secret
293	: $auth_method eq "tls_anon" ? ($tls ? "" : "\012\012") # \012\012 never matches
294	: $auth_method eq "tls_md6_64_256" ? ($tls ? Digest::MD6::md6_hex "$rgreeting1\012$rgreeting2\012$lgreeting1\012$lgreeting2\012" : "\012\012")
295	: return $self->error ("$auth_method: fatal, selected unsupported rcv auth method");
296
297	if ($rauth2 ne $rauth) {
298	return $self->error ("authentication failure/shared secret mismatch");
299	}
300
301	$self->{s_framing} = $s_framing;
302
303	$hdl->rbuf_max (undef);
304	my $queue = delete $self->{queue}; # we are connected
305
306	$self->{hdl}->rtimeout ($self->{remote_greeting}{timeout});
307	$self->{hdl}->wtimeout ($self->{timeout} - LATENCY);
308	$self->{hdl}->on_wtimeout (sub { $self->send ([]) });
309
310	$self->connected;
311
312	# send queued messages
313	$self->send ($_)
314	for @$queue;
315
316	# receive handling
317	my $src_node = $self->{node};
318	my $rmsg; $rmsg = $self->{rmsg} = sub {
319	$_[0]->push_read ($r_framing => $rmsg);
320
321	local $AnyEvent::MP::Kernel::SRCNODE = $src_node;
322	AnyEvent::MP::Kernel::_inject (@{ $_[1] });
323	};
324	$hdl->push_read ($r_framing => $rmsg);
325
326	Scalar::Util::weaken $rmsg;
327	Scalar::Util::weaken $src_node;
328	});
329	});
330	});
331	}
332
333	$self
334	}
335
336	sub error {
337	my ($self, $msg) = @_;
338
339	delete $self->{keepalive};
340
341	# $AnyEvent::MP::Kernel::WARN->(9, "$self->{peerhost}:$self->{peerport} $msg");#d#
342
343	$self->{node}->transport_error (transport_error => $self->{node}{id}, $msg)
344	if $self->{node} && $self->{node}{transport} == $self;
345
346	(delete $self->{release})->()
347	if exists $self->{release};
348
349	# $AnyEvent::MP::Kernel::WARN->(7, "$self->{peerhost}:$self->{peerport}: $msg");
350	$self->destroy;
351	}
352
353	sub connected {
354	my ($self) = @_;
355
356	delete $self->{keepalive};
357
358	(delete $self->{release})->()
359	if exists $self->{release};
360
361	$AnyEvent::MP::Kernel::WARN->(9, "$self->{peerhost}:$self->{peerport} connected as $self->{remote_node}");
362
363	my $node = AnyEvent::MP::Kernel::add_node ($self->{remote_node});
364	Scalar::Util::weaken ($self->{node} = $node);
365	$node->transport_connect ($self);
366	}
367
368	sub send {
369	$_[0]{hdl}->push_write ($_[0]{s_framing} => $_[1]);
370	}
371
372	sub destroy {
373	my ($self) = @_;
374
375	(delete $self->{release})->()
376	if exists $self->{release};
377
378	$self->{hdl}->destroy
379	if $self->{hdl};
380	}
381
382	sub DESTROY {
383	my ($self) = @_;
384
385	$self->destroy;
386	}
387
388	=back
389
390	=head1 PROTOCOL
391
392	The AEMP protocol is relatively simple, and consists of three phases which
393	are symmetrical for both sides: greeting (followed by optionally switching
394	to TLS mode), authentication and packet exchange.
395
396	The protocol is designed to allow both full-text and binary streams.
397
398	The greeting consists of two text lines that are ended by either an ASCII
399	CR LF pair, or a single ASCII LF (recommended).
400
401	=head2 GREETING
402
403	All the lines until after authentication must not exceed 4kb in length,
404	including line delimiter. Afterwards there is no limit on the packet size
405	that can be received.
406
407	=head3 First Greeting Line
408
409	Example:
410
411	aemp;0;rain;tls_md6_64_256,hmac_md6_64_256,tls_anon,cleartext;json,storable;timeout=12;peeraddr=10.0.0.1:48082
412
413	The first line contains strings separated (not ended) by C<;>
414	characters. The first five strings are fixed by the protocol, the
415	remaining strings are C<KEY=VALUE> pairs. None of them may contain C<;>
416	characters themselves (when escaping is needed, use C<%3b> to represent
417	C<;> and C<%25> to represent C<%>)-
418
419	The fixed strings are:
420
421	=over 4
422
423	=item protocol identification
424
425	The constant C<aemp> to identify this protocol.
426
427	=item protocol version
428
429	The protocol version supported by this end, currently C<0>. If the
430	versions don't match then no communication is possible. Minor extensions
431	are supposed to be handled through additional key-value pairs.
432
433	=item the node ID
434
435	This is the node ID of the connecting node.
436
437	=item the acceptable authentication methods
438
439	A comma-separated list of authentication methods supported by the
440	node. Note that AnyEvent::MP supports a C<hex_secret> authentication
441	method that accepts a clear-text password (hex-encoded), but will not use
442	this authentication method itself.
443
444	The receiving side should choose the first authentication method it
445	supports.
446
447	=item the acceptable framing formats
448
449	A comma-separated list of packet encoding/framing formats understood. The
450	receiving side should choose the first framing format it supports for
451	sending packets (which might be different from the format it has to accept).
452
453	=back
454
455	The remaining arguments are C<KEY=VALUE> pairs. The following key-value
456	pairs are known at this time:
457
458	=over 4
459
460	=item timeout=<seconds>
461
462	The amount of time after which this node should be detected as dead unless
463	some data has been received. The node is responsible to send traffic
464	reasonably more often than this interval (such as every timeout minus five
465	seconds).
466
467	=item provider=<module-version>
468
469	The software provider for this implementation. For AnyEvent::MP, this is
470	C<AE-0.0> or whatever version it currently is at.
471
472	=item peeraddr=<host>:<port>
473
474	The peer address (socket address of the other side) as seen locally.
475
476	=item tls=<major>.<minor>
477
478	Indicates that the other side supports TLS (version should be 1.0) and
479	wishes to do a TLS handshake.
480
481	=back
482
483	=head3 Second Greeting Line
484
485	After this greeting line there will be a second line containing a
486	cryptographic nonce, i.e. random data of high quality. To keep the
487	protocol text-only, these are usually 32 base64-encoded octets, but
488	it could be anything that doesn't contain any ASCII CR or ASCII LF
489	characters.
490
491	I<< The two nonces B<must> be different, and an aemp implementation
492	B<must> check and fail when they are identical >>.
493
494	Example of a nonce line (yes, it's random-looking because it is random
495	data):
496
497	2XYhdG7/O6epFa4wuP0ujAEx1rXYWRcOypjUYK7eF6yWAQr7gwIN9m/2+mVvBrTPXz5GJDgfGm9d8QRABAbmAP/s
498
499	=head2 TLS handshake
500
501	I<< If, after the handshake, both sides indicate interest in TLS, then the
502	connection B<must> use TLS, or fail to continue. >>
503
504	Both sides compare their nonces, and the side who sent the lower nonce
505	value ("string" comparison on the raw octet values) becomes the client,
506	and the one with the higher nonce the server.
507
508	=head2 AUTHENTICATION PHASE
509
510	After the greeting is received (and the optional TLS handshake),
511	the authentication phase begins, which consists of sending a single
512	C<;>-separated line with three fixed strings and any number of
513	C<KEY=VALUE> pairs.
514
515	The three fixed strings are:
516
517	=over 4
518
519	=item the authentication method chosen
520
521	This must be one of the methods offered by the other side in the greeting.
522
523	Note that all methods starting with C<tls_> are only valid I<iff> TLS was
524	successfully handshaked (and to be secure the implementation must enforce
525	this).
526
527	The currently supported authentication methods are:
528
529	=over 4
530
531	=item cleartext
532
533	This is simply the shared secret, lowercase-hex-encoded. This method is of
534	course very insecure if TLS is not used (and not completely secure even
535	if TLS is used), which is why this module will accept, but not generate,
536	cleartext auth replies.
537
538	=item hmac_md6_64_256
539
540	This method uses an MD6 HMAC with 64 bit blocksize and 256 bit hash, and
541	requires a shared secret. It is the preferred auth method when a shared
542	secret is available.
543
544	First, the shared secret is hashed with MD6:
545
546	key = MD6 (secret)
547
548	This secret is then used to generate the "local auth reply", by taking
549	the two local greeting lines and the two remote greeting lines (without
550	line endings), appending \012 to all of them, concatenating them and
551	calculating the MD6 HMAC with the key:
552
553	lauth = HMAC_MD6 key, "lgreeting1\012lgreeting2\012rgreeting1\012rgreeting2\012"
554
555	This authentication token is then lowercase-hex-encoded and sent to the
556	other side.
557
558	Then the remote auth reply is generated using the same method, but local
559	and remote greeting lines swapped:
560
561	rauth = HMAC_MD6 key, "rgreeting1\012rgreeting2\012lgreeting1\012lgreeting2\012"
562
563	This is the token that is expected from the other side.
564
565	=item tls_anon
566
567	This type is only valid I<iff> TLS was enabled and the TLS handshake
568	was successful. It has no authentication data, as the server/client
569	certificate was successfully verified.
570
571	This authentication type is somewhat insecure, as it allows a
572	man-in-the-middle attacker to change some of the connection parameters
573	(such as the framing format), although there is no known attack that
574	exploits this in a way that is worse than just denying the service.
575
576	By default, this implementation accepts but never generates this auth
577	reply.
578
579	=item tls_md6_64_256
580
581	This type is only valid I<iff> TLS was enabled and the TLS handshake was
582	successful.
583
584	This authentication type simply calculates:
585
586	lauth = MD6 "rgreeting1\012rgreeting2\012lgreeting1\012lgreeting2\012"
587
588	and lowercase-hex encodes the result and sends it as authentication
589	data. No shared secret is required (authentication is done by TLS). The
590	checksum exists only to make tinkering with the greeting hard.
591
592	=back
593
594	=item the authentication data
595
596	The authentication data itself, usually base64 or hex-encoded data, see
597	above.
598
599	=item the framing protocol chosen
600
601	This must be one of the framing protocols offered by the other side in the
602	greeting. Each side must accept the choice of the other side, and generate
603	packets in the format it chose itself.
604
605	=back
606
607	Example of an authentication reply:
608
609	hmac_md6_64_256;363d5175df38bd9eaddd3f6ca18aa1c0c4aa22f0da245ac638d048398c26b8d3;json
610
611	=head2 DATA PHASE
612
613	After this, packets get exchanged using the chosen framing protocol. It is
614	quite possible that both sides use a different framing protocol.
615
616	=head2 FULL EXAMPLE
617
618	This is an actual protocol dump of a handshake, followed by a single data
619	packet. The greater than/less than lines indicate the direction of the
620	transfer only.
621
622	> aemp;0;anon/57Cs1CggVJjzYaQp13XXg4;tls_md6_64_256,hmac_md6_64_256,tls_anon,cleartext;json,storable;provider=AE-0.8;timeout=12;peeraddr=10.0.0.17:4040
623	> yLgdG1ov/02shVkVQer3wzeuywZK+oraTdEQBmIqWHaegxSGDG4g+HqogLQbvdypFOsoDWJ1Sh4ImV4DMhvUBwTK
624
625	< aemp;0;ruth;tls_md6_64_256,hmac_md6_64_256,tls_anon,cleartext;json,storable;provider=AE-0.8;timeout=12;peeraddr=10.0.0.1:37108
626	< +xMQXP8ElfNmuvEhsmcp+s2wCJOuQAsPxSg3d2Ewhs6gBnJz+ypVdWJ/wAVrXqlIJfLeVS/CBy4gEGkyWHSuVb1L
627
628	> hmac_md6_64_256;5ad913855742ae5a03a5aeb7eafa4c78629de136bed6acd73eea36c9e98df44a;json
629
630	< hmac_md6_64_256;84cd590976f794914c2ca26dac3a207a57a6798b9171289c114de07cf0c20401;json
631	< ["","AnyEvent::MP::_spawn","57Cs1CggVJjzYaQp13XXg4.c","AnyEvent::MP::Global::connect",0,"anon/57Cs1CggVJjzYaQp13XXg4"]
632	...
633
634	The shared secret in use was C<8ugxrtw6H5tKnfPWfaSr4HGhE8MoJXmzTT1BWq7sLutNcD0IbXprQlZjIbl7MBKoeklG3IEfY9GlJthC0pENzk>.
635
636	=head1 SEE ALSO
637
638	L<AnyEvent::MP>.
639
640	=head1 AUTHOR
641
642	Marc Lehmann <schmorp@schmorp.de>
643	http://home.schmorp.de/
644
645	=cut
646
647	1
648