%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2007-2010. All Rights Reserved.
%%
%% The contents of this file are subject to the Erlang Public License,
%% Version 1.1, (the "License"); you may not use this file except in
%% compliance with the License. You should have received a copy of the
%% Erlang Public License along with this software. If not, it can be
%% retrieved online at http://www.erlang.org/.
%%
%% Software distributed under the License is distributed on an "AS IS"
%% basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
%% the License for the specific language governing rights and limitations
%% under the License.
%%
%% %CopyrightEnd%
%%
%%----------------------------------------------------------------------
%% Purpose: Help funtions for handling the SSL-handshake protocol
%%----------------------------------------------------------------------
-module(ssl_handshake).
-include("ssl_handshake.hrl").
-include("ssl_record.hrl").
-include("ssl_cipher.hrl").
-include("ssl_alert.hrl").
-include("ssl_internal.hrl").
-include("ssl_debug.hrl").
-include_lib("public_key/include/public_key.hrl").
-export([master_secret/4, client_hello/4, server_hello/3, hello/2,
hello_request/0, certify/5, certificate/3,
client_certificate_verify/6,
certificate_verify/6, certificate_request/2,
key_exchange/2, finished/4,
verify_connection/5,
get_tls_handshake/4,
server_hello_done/0, sig_alg/1,
encode_handshake/3, init_hashes/0,
update_hashes/2, decrypt_premaster_secret/2]).
%%====================================================================
%% Internal application API
%%====================================================================
%%--------------------------------------------------------------------
%% Function: client_hello(Host, Port, ConnectionStates, SslOpts) ->
%% #client_hello{}
%% Host
%% Port
%% ConnectionStates = #connection_states{}
%% SslOpts = #ssl_options{}
%%
%% Description: Creates a client hello message.
%%--------------------------------------------------------------------
client_hello(Host, Port, ConnectionStates, #ssl_options{versions = Versions,
ciphers = Ciphers}
= SslOpts) ->
Fun = fun(Version) ->
ssl_record:protocol_version(Version)
end,
Version = ssl_record:highest_protocol_version(lists:map(Fun, Versions)),
Pending = ssl_record:pending_connection_state(ConnectionStates, read),
SecParams = Pending#connection_state.security_parameters,
Id = ssl_manager:client_session_id(Host, Port, SslOpts),
#client_hello{session_id = Id,
client_version = Version,
cipher_suites = Ciphers,
compression_methods = ssl_record:compressions(),
random = SecParams#security_parameters.client_random
}.
%%--------------------------------------------------------------------
%% Function: server_hello(Host, Port, SessionId,
%% Version, ConnectionStates) -> #server_hello{}
%% SessionId
%% Version
%% ConnectionStates
%%
%%
%% Description: Creates a server hello message.
%%--------------------------------------------------------------------
server_hello(SessionId, Version, ConnectionStates) ->
Pending = ssl_record:pending_connection_state(ConnectionStates, read),
SecParams = Pending#connection_state.security_parameters,
#server_hello{server_version = Version,
cipher_suite = SecParams#security_parameters.cipher_suite,
compression_method =
SecParams#security_parameters.compression_algorithm,
random = SecParams#security_parameters.server_random,
session_id = SessionId
}.
%%--------------------------------------------------------------------
%% Function: hello_request() -> #hello_request{}
%%
%% Description: Creates a hello request message sent by server to
%% trigger renegotiation.
%%--------------------------------------------------------------------
hello_request() ->
#hello_request{}.
%%--------------------------------------------------------------------
%% Function: hello(Hello, Info) ->
%% {Version, Id, NewConnectionStates} |
%% #alert{}
%%
%% Hello = #client_hello{} | #server_hello{}
%% Info = ConnectionStates | {Port, Session, ConnectionStates}
%% ConnectionStates = #connection_states{}
%%
%% Description: Handles a recieved hello message
%%--------------------------------------------------------------------
hello(#server_hello{cipher_suite = CipherSuite, server_version = Version,
compression_method = Compression, random = Random,
session_id = SessionId}, ConnectionStates) ->
NewConnectionStates =
hello_pending_connection_states(client, CipherSuite, Random,
Compression, ConnectionStates),
{Version, SessionId, NewConnectionStates};
hello(#client_hello{client_version = ClientVersion, random = Random} = Hello,
{Port, #ssl_options{versions = Versions} = SslOpts,
Session0, Cache, CacheCb, ConnectionStates0}) ->
Version = select_version(ClientVersion, Versions),
case ssl_record:is_acceptable_version(Version) of
true ->
{Type, #session{cipher_suite = CipherSuite,
compression_method = Compression} = Session}
= select_session(Hello, Port, Session0, Version,
SslOpts, Cache, CacheCb),
case CipherSuite of
no_suite ->
?ALERT_REC(?FATAL, ?INSUFFICIENT_SECURITY);
_ ->
ConnectionStates =
hello_pending_connection_states(server,
CipherSuite,
Random,
Compression,
ConnectionStates0),
{Version, {Type, Session}, ConnectionStates}
end;
false ->
?ALERT_REC(?FATAL, ?PROTOCOL_VERSION)
end.
%%--------------------------------------------------------------------
%% Function: certify(Certs, CertDbRef, MaxPathLen) ->
%% {PeerCert, PublicKeyInfo} | #alert{}
%%
%% Certs = #certificate{}
%% CertDbRef = reference()
%% MaxPathLen = integer() | nolimit
%%
%% Description: Handles a certificate handshake message
%%--------------------------------------------------------------------
certify(#certificate{asn1_certificates = ASN1Certs}, CertDbRef,
MaxPathLen, Verify, VerifyFun) ->
[PeerCert | _] = ASN1Certs,
VerifyBool = verify_bool(Verify),
try
%% Allow missing root_cert and check that with VerifyFun
ssl_certificate:trusted_cert_and_path(ASN1Certs, CertDbRef, false) of
{TrustedErlCert, CertPath, VerifyErrors} ->
Result = public_key:pkix_path_validation(TrustedErlCert,
CertPath,
[{max_path_length,
MaxPathLen},
{verify, VerifyBool},
{acc_errors,
VerifyErrors}]),
case Result of
{error, Reason} ->
path_validation_alert(Reason, Verify);
{ok, {PublicKeyInfo,_, []}} ->
{PeerCert, PublicKeyInfo};
{ok, {PublicKeyInfo,_, AccErrors = [Error | _]}} ->
case VerifyFun(AccErrors) of
true ->
{PeerCert, PublicKeyInfo};
false ->
path_validation_alert(Error, Verify)
end
end
catch
throw:Alert ->
Alert
end.
%%--------------------------------------------------------------------
%% Function: certificate(OwnCert, CertDbRef, Role) -> #certificate{}
%%
%% OwnCert = binary()
%% CertDbRef = term() as returned by ssl_certificate_db:create()
%%
%% Description: Creates a certificate message.
%%--------------------------------------------------------------------
certificate(OwnCert, CertDbRef, client) ->
Chain =
case ssl_certificate:certificate_chain(OwnCert, CertDbRef) of
{ok, CertChain} ->
CertChain;
{error, _} ->
%% If no suitable certificate is available, the client
%% SHOULD send a certificate message containing no
%% certificates. (chapter 7.4.6. rfc 4346)
[]
end,
#certificate{asn1_certificates = Chain};
certificate(OwnCert, CertDbRef, server) ->
case ssl_certificate:certificate_chain(OwnCert, CertDbRef) of
{ok, Chain} ->
#certificate{asn1_certificates = Chain};
{error, _} ->
?ALERT_REC(?FATAL, ?INTERNAL_ERROR)
end.
%%--------------------------------------------------------------------
%% Function: client_certificate_verify(Cert, ConnectionStates) ->
%% #certificate_verify{} | ignore
%% Cert = #'OTPcertificate'{}
%% ConnectionStates = #connection_states{}
%%
%% Description: Creates a certificate_verify message, called by the client.
%%--------------------------------------------------------------------
client_certificate_verify(undefined, _, _, _, _, _) ->
ignore;
client_certificate_verify(_, _, _, _, undefined, _) ->
ignore;
client_certificate_verify(OwnCert, MasterSecret, Version, Algorithm,
PrivateKey, {Hashes0, _}) ->
case public_key:pkix_is_fixed_dh_cert(OwnCert) of
true ->
ignore;
false ->
Hashes =
calc_certificate_verify(Version, MasterSecret,
Algorithm, Hashes0),
Signed = digitally_signed(Hashes, PrivateKey),
#certificate_verify{signature = Signed}
end.
%%--------------------------------------------------------------------
%% Function: certificate_verify(Signature, PublicKeyInfo) -> valid | #alert{}
%%
%% Signature = binary()
%% PublicKeyInfo = {Algorithm, PublicKey, PublicKeyParams}
%%
%% Description: Checks that the certificate_verify message is valid.
%%--------------------------------------------------------------------
certificate_verify(Signature, {_, PublicKey, _}, Version,
MasterSecret, Algorithm, {_, Hashes0})
when Algorithm =:= rsa; Algorithm =:= dh_rsa; Algorithm =:= dhe_rsa ->
Hashes = calc_certificate_verify(Version, MasterSecret,
Algorithm, Hashes0),
case public_key:decrypt_public(Signature, PublicKey,
[{rsa_pad, rsa_pkcs1_padding}]) of
Hashes ->
valid;
_ ->
?ALERT_REC(?FATAL, ?BAD_CERTIFICATE)
end.
%% TODO dsa clause
%%--------------------------------------------------------------------
%% Function: certificate_request(ConnectionStates, CertDbRef) ->
%% #certificate_request{}
%%
%% Description: Creates a certificate_request message, called by the server.
%%--------------------------------------------------------------------
certificate_request(ConnectionStates, CertDbRef) ->
#connection_state{security_parameters =
#security_parameters{cipher_suite = CipherSuite}} =
ssl_record:pending_connection_state(ConnectionStates, read),
Types = certificate_types(CipherSuite),
Authorities = certificate_authorities(CertDbRef),
#certificate_request{
certificate_types = Types,
certificate_authorities = Authorities
}.
%%--------------------------------------------------------------------
%% Function: key_exchange(Role, Secret, Params) ->
%% #client_key_exchange{} | #server_key_exchange{}
%%
%% Secret -
%% Params -
%%
%% Description: Creates a keyexchange message.
%%--------------------------------------------------------------------
key_exchange(client, {premaster_secret, Secret, {_, PublicKey, _}}) ->
EncPremasterSecret =
encrypted_premaster_secret(Secret, PublicKey),
#client_key_exchange{exchange_keys = EncPremasterSecret};
key_exchange(client, fixed_diffie_hellman) ->
#client_key_exchange{exchange_keys =
#client_diffie_hellman_public{
dh_public = <<>>
}};
key_exchange(client, {dh, PublicKey}) ->
Len = byte_size(PublicKey),
#client_key_exchange{
exchange_keys = #client_diffie_hellman_public{
dh_public = <<?UINT16(Len), PublicKey/binary>>}
};
%% key_exchange(server, {{?'dhpublicnumber', _PublicKey,
%% #'DomainParameters'{p = P, g = G, y = Y},
%% SignAlgorithm, ClientRandom, ServerRandom}}) ->
%% ServerDHParams = #server_dh_params{dh_p = P, dh_g = G, dh_y = Y},
%% PLen = byte_size(P),
%% GLen = byte_size(G),
%% YLen = byte_size(Y),
%% Hash = server_key_exchange_hash(SignAlgorithm, <<ClientRandom/binary,
%% ServerRandom/binary,
%% ?UINT16(PLen), P/binary,
%% ?UINT16(GLen), G/binary,
%% ?UINT16(YLen), Y/binary>>),
%% Signed = digitally_signed(Hash, PrivateKey),
%% #server_key_exchange{
%% params = ServerDHParams,
%% signed_params = Signed
%% };
key_exchange(_, _) ->
%%TODO : Real imp
#server_key_exchange{}.
%%--------------------------------------------------------------------
%% Function: master_secret(Version, Session/PremasterSecret,
%% ConnectionStates, Role) ->
%% {MasterSecret, NewConnectionStates} | #alert{}
%% Version = #protocol_version{}
%% Session = #session{} (session contains master secret)
%% PremasterSecret = binary()
%% ConnectionStates = #connection_states{}
%% Role = client | server
%%
%% Description: Sets or calculates the master secret and calculate keys,
%% updating the pending connection states. The Mastersecret and the update
%% connection states are returned or an alert if the calculation fails.
%%-------------------------------------------------------------------
master_secret(Version, #session{master_secret = Mastersecret},
ConnectionStates, Role) ->
ConnectionState =
ssl_record:pending_connection_state(ConnectionStates, read),
SecParams = ConnectionState#connection_state.security_parameters,
try master_secret(Version, Mastersecret, SecParams,
ConnectionStates, Role)
catch
exit:Reason ->
error_logger:error_report("Key calculation failed due to ~p",
[Reason]),
?ALERT_REC(?FATAL, ?HANDSHAKE_FAILURE)
end;
master_secret(Version, PremasterSecret, ConnectionStates, Role) ->
ConnectionState =
ssl_record:pending_connection_state(ConnectionStates, read),
SecParams = ConnectionState#connection_state.security_parameters,
#security_parameters{client_random = ClientRandom,
server_random = ServerRandom} = SecParams,
try master_secret(Version,
calc_master_secret(Version,PremasterSecret,
ClientRandom, ServerRandom),
SecParams, ConnectionStates, Role)
catch
exit:Reason ->
error_logger:error_report("Master secret calculation failed"
" due to ~p", [Reason]),
?ALERT_REC(?FATAL, ?HANDSHAKE_FAILURE)
end.
%%--------------------------------------------------------------------
%% Function: finished(Version, Role, MacSecret, Hashes) -> #finished{}
%%
%% ConnectionStates = #connection_states{}
%%
%% Description: Creates a handshake finished message
%%-------------------------------------------------------------------
finished(Version, Role, MasterSecret, {Hashes, _}) -> % use the current hashes
#finished{verify_data =
calc_finished(Version, Role, MasterSecret, Hashes)}.
%%--------------------------------------------------------------------
%% Function: verify_connection(Finished, Role,
%% MasterSecret, Hashes) -> verified | #alert{}
%%
%% Finished = #finished{}
%% Role = client | server - the role of the process that sent the finished
%% message.
%% MasterSecret = binary()
%% Hashes = binary() - {md5_hash, sha_hash}
%%
%%
%% Description: Checks the ssl handshake finished message to verify
%% the connection.
%%-------------------------------------------------------------------
verify_connection(Version, #finished{verify_data = Data},
Role, MasterSecret, {_, {MD5, SHA}}) ->
%% use the previous hashes
?DBG_HEX(crypto:md5_final(MD5)),
?DBG_HEX(crypto:sha_final(SHA)),
case calc_finished(Version, Role, MasterSecret, {MD5, SHA}) of
Data ->
verified;
_E ->
?ALERT_REC(?FATAL, ?HANDSHAKE_FAILURE)
end.
server_hello_done() ->
#server_hello_done{}.
%%--------------------------------------------------------------------
%% Function: encode_handshake(HandshakeRec) -> BinHandshake
%% HandshakeRec = #client_hello | #server_hello{} | server_hello_done |
%% #certificate{} | #client_key_exchange{} | #finished{} |
%% #client_certify_request{}
%%
%% encode a handshake packet to binary
%%--------------------------------------------------------------------
encode_handshake(Package, Version, SigAlg) ->
{MsgType, Bin} = enc_hs(Package, Version, SigAlg),
Len = byte_size(Bin),
[MsgType, ?uint24(Len), Bin].
%%--------------------------------------------------------------------
%% Function: get_tls_handshake(Data, Buffer) -> Result
%% Result = {[#handshake{}], [Raw], NewBuffer}
%% Data = Buffer = NewBuffer = Raw = binary()
%%
%% Description: Given buffered and new data from ssl_record, collects
%% and returns it as a list of #handshake, also returns leftover
%% data.
%%--------------------------------------------------------------------
get_tls_handshake(Data, <<>>, KeyAlg, Version) ->
get_tls_handshake_aux(Data, KeyAlg, Version, []);
get_tls_handshake(Data, Buffer, KeyAlg, Version) ->
get_tls_handshake_aux(list_to_binary([Buffer, Data]),
KeyAlg, Version, []).
get_tls_handshake_aux(<<?BYTE(Type), ?UINT24(Length), Body:Length/binary,Rest/binary>>,
KeyAlg, Version, Acc) ->
Raw = <<?BYTE(Type), ?UINT24(Length), Body/binary>>,
H = dec_hs(Type, Body, KeyAlg, Version),
get_tls_handshake_aux(Rest, KeyAlg, Version, [{H,Raw} | Acc]);
get_tls_handshake_aux(Data, _KeyAlg, _Version, Acc) ->
{lists:reverse(Acc), Data}.
%%--------------------------------------------------------------------
%% Function: sig_alg(atom()) -> integer()
%%
%% Description: Convert from key exchange as atom to signature
%% algorithm as a ?SIGNATURE_... constant
%%--------------------------------------------------------------------
sig_alg(dh_anon) ->
?SIGNATURE_ANONYMOUS;
sig_alg(Alg) when Alg == dhe_rsa; Alg == rsa; Alg == dh_rsa ->
?SIGNATURE_RSA;
sig_alg(Alg) when Alg == dh_dss; Alg == dhe_dss ->
?SIGNATURE_DSA;
sig_alg(_) ->
?NULL.
%%--------------------------------------------------------------------
%%% Internal functions
%%--------------------------------------------------------------------
verify_bool(verify_peer) ->
true;
verify_bool(verify_none) ->
false.
path_validation_alert({bad_cert, cert_expired}, _) ->
?ALERT_REC(?FATAL, ?CERTIFICATE_EXPIRED);
path_validation_alert({bad_cert, invalid_issuer}, _) ->
?ALERT_REC(?FATAL, ?BAD_CERTIFICATE);
path_validation_alert({bad_cert, invalid_signature} , _) ->
?ALERT_REC(?FATAL, ?BAD_CERTIFICATE);
path_validation_alert({bad_cert, name_not_permitted}, _) ->
?ALERT_REC(?FATAL, ?BAD_CERTIFICATE);
path_validation_alert({bad_cert, unknown_critical_extension}, _) ->
?ALERT_REC(?FATAL, ?UNSUPPORTED_CERTIFICATE);
path_validation_alert({bad_cert, cert_revoked}, _) ->
?ALERT_REC(?FATAL, ?CERTIFICATE_REVOKED);
path_validation_alert(_, _) ->
?ALERT_REC(?FATAL, ?HANDSHAKE_FAILURE).
select_session(Hello, Port, Session, Version,
#ssl_options{ciphers = UserSuites} = SslOpts, Cache, CacheCb) ->
SuggestedSessionId = Hello#client_hello.session_id,
SessionId = ssl_manager:server_session_id(Port, SuggestedSessionId,
SslOpts),
Suites = case UserSuites of
[] ->
ssl_cipher:suites(Version);
_ ->
UserSuites
end,
case ssl_session:is_new(SuggestedSessionId, SessionId) of
true ->
CipherSuite =
select_cipher_suite(Hello#client_hello.cipher_suites, Suites),
Compressions = Hello#client_hello.compression_methods,
Compression = select_compression(Compressions),
{new, Session#session{session_id = SessionId,
cipher_suite = CipherSuite,
compression_method = Compression}};
false ->
{resumed, CacheCb:lookup(Cache, {Port, SessionId})}
end.
%% Update pending connection states with parameters exchanged via
%% hello messages
%% NOTE : Role is the role of the receiver of the hello message
%% currently being processed.
hello_pending_connection_states(Role, CipherSuite, Random, Compression,
ConnectionStates) ->
ReadState =
ssl_record:pending_connection_state(ConnectionStates, read),
WriteState =
ssl_record:pending_connection_state(ConnectionStates, write),
NewReadSecParams =
hello_security_parameters(Role, ReadState, CipherSuite,
Random, Compression),
NewWriteSecParams =
hello_security_parameters(Role, WriteState, CipherSuite,
Random, Compression),
ssl_record:update_security_params(NewReadSecParams,
NewWriteSecParams,
ConnectionStates).
hello_security_parameters(client, ConnectionState, CipherSuite, Random,
Compression) ->
SecParams = ConnectionState#connection_state.security_parameters,
NewSecParams = ssl_cipher:security_parameters(CipherSuite, SecParams),
NewSecParams#security_parameters{
server_random = Random,
compression_algorithm = Compression
};
hello_security_parameters(server, ConnectionState, CipherSuite, Random,
Compression) ->
SecParams = ConnectionState#connection_state.security_parameters,
NewSecParams = ssl_cipher:security_parameters(CipherSuite, SecParams),
NewSecParams#security_parameters{
client_random = Random,
compression_algorithm = Compression
}.
select_version(ClientVersion, Versions) ->
Fun = fun(Version) ->
ssl_record:protocol_version(Version)
end,
ServerVersion = ssl_record:highest_protocol_version(lists:map(Fun,
Versions)),
ssl_record:lowest_protocol_version(ClientVersion, ServerVersion).
select_cipher_suite([], _) ->
no_suite;
select_cipher_suite([Suite | ClientSuites], SupportedSuites) ->
case is_member(Suite, SupportedSuites) of
true ->
Suite;
false ->
select_cipher_suite(ClientSuites, SupportedSuites)
end.
is_member(Suite, SupportedSuites) ->
lists:member(Suite, SupportedSuites).
select_compression(_CompressionMetodes) ->
?NULL.
master_secret(Version, MasterSecret, #security_parameters{
client_random = ClientRandom,
server_random = ServerRandom,
hash_size = HashSize,
key_material_length = KML,
expanded_key_material_length = EKML,
iv_size = IVS,
exportable = Exportable},
ConnectionStates, Role) ->
{ClientWriteMacSecret, ServerWriteMacSecret, ClientWriteKey,
ServerWriteKey, ClientIV, ServerIV} =
setup_keys(Version, Exportable, MasterSecret, ServerRandom,
ClientRandom, HashSize, KML, EKML, IVS),
?DBG_HEX(ClientWriteKey),
?DBG_HEX(ClientIV),
ConnStates1 = ssl_record:set_master_secret(MasterSecret, ConnectionStates),
ConnStates2 =
ssl_record:set_mac_secret(ClientWriteMacSecret, ServerWriteMacSecret,
Role, ConnStates1),
ClientCipherState = #cipher_state{iv = ClientIV, key = ClientWriteKey},
ServerCipherState = #cipher_state{iv = ServerIV, key = ServerWriteKey},
{MasterSecret,
ssl_record:set_pending_cipher_state(ConnStates2, ClientCipherState,
ServerCipherState, Role)}.
dec_hs(?HELLO_REQUEST, <<>>, _, _) ->
#hello_request{};
%% Client hello v2.
%% The server must be able to receive such messages, from clients that
%% are willing to use ssl v3 or higher, but have ssl v2 compatibility.
dec_hs(?CLIENT_HELLO, <<?BYTE(Major), ?BYTE(Minor),
?UINT16(CSLength), ?UINT16(0),
?UINT16(CDLength),
CipherSuites:CSLength/binary,
ChallengeData:CDLength/binary>>,
_, _) ->
?DBG_HEX(CipherSuites),
?DBG_HEX(CipherSuites),
#client_hello{client_version = {Major, Minor},
random = ssl_ssl2:client_random(ChallengeData, CDLength),
session_id = 0,
cipher_suites = from_3bytes(CipherSuites),
compression_methods = [?NULL]
};
dec_hs(?CLIENT_HELLO, <<?BYTE(Major), ?BYTE(Minor), Random:32/binary,
?BYTE(SID_length), Session_ID:SID_length/binary,
?UINT16(Cs_length), CipherSuites:Cs_length/binary,
?BYTE(Cm_length), Comp_methods:Cm_length/binary,
_FutureCompatData/binary>>,
_, _) ->
#client_hello{
client_version = {Major,Minor},
random = Random,
session_id = Session_ID,
cipher_suites = from_2bytes(CipherSuites),
compression_methods = Comp_methods
};
dec_hs(?SERVER_HELLO, <<?BYTE(Major), ?BYTE(Minor), Random:32/binary,
?BYTE(SID_length), Session_ID:SID_length/binary,
Cipher_suite:2/binary, ?BYTE(Comp_method)>>, _, _) ->
#server_hello{
server_version = {Major,Minor},
random = Random,
session_id = Session_ID,
cipher_suite = Cipher_suite,
compression_method = Comp_method
};
dec_hs(?CERTIFICATE, <<?UINT24(ACLen), ASN1Certs:ACLen/binary>>, _, _) ->
#certificate{asn1_certificates = certs_to_list(ASN1Certs)};
dec_hs(?SERVER_KEY_EXCHANGE, <<?UINT16(ModLen), Mod:ModLen/binary,
?UINT16(ExpLen), Exp:ExpLen/binary,
Sig/binary>>,
?KEY_EXCHANGE_RSA, _) ->
#server_key_exchange{params = #server_rsa_params{rsa_modulus = Mod,
rsa_exponent = Exp},
signed_params = Sig};
dec_hs(?SERVER_KEY_EXCHANGE, <<?UINT16(PLen), P:PLen/binary,
?UINT16(GLen), G:GLen/binary,
?UINT16(YLen), Y:YLen/binary,
Sig/binary>>,
?KEY_EXCHANGE_DIFFIE_HELLMAN, _) ->
#server_key_exchange{params = #server_dh_params{dh_p = P,dh_g = G, dh_y = Y},
signed_params = Sig};
dec_hs(?CERTIFICATE_REQUEST,
<<?BYTE(CertTypesLen), CertTypes:CertTypesLen/binary,
?UINT16(CertAuthsLen), CertAuths:CertAuthsLen/binary>>, _, _) ->
%% TODO: maybe we should chop up CertAuths into a list?
#certificate_request{certificate_types = CertTypes,
certificate_authorities = CertAuths};
dec_hs(?SERVER_HELLO_DONE, <<>>, _, _) ->
#server_hello_done{};
dec_hs(?CERTIFICATE_VERIFY,<<?UINT16(_), Signature/binary>>, _, _)->
#certificate_verify{signature = Signature};
dec_hs(?CLIENT_KEY_EXCHANGE, PKEPMS, rsa, {3, 0}) ->
PreSecret = #encrypted_premaster_secret{premaster_secret = PKEPMS},
#client_key_exchange{exchange_keys = PreSecret};
dec_hs(?CLIENT_KEY_EXCHANGE, <<?UINT16(_), PKEPMS/binary>>, rsa, _) ->
PreSecret = #encrypted_premaster_secret{premaster_secret = PKEPMS},
#client_key_exchange{exchange_keys = PreSecret};
dec_hs(?CLIENT_KEY_EXCHANGE, <<>>, ?KEY_EXCHANGE_DIFFIE_HELLMAN, _) ->
%% TODO: Should check whether the cert already contains a suitable DH-key (7.4.7.2)
throw(?ALERT_REC(?FATAL, implicit_public_value_encoding));
dec_hs(?CLIENT_KEY_EXCHANGE, <<?UINT16(DH_YCLen), DH_YC:DH_YCLen/binary>>,
?KEY_EXCHANGE_DIFFIE_HELLMAN, _) ->
#client_diffie_hellman_public{dh_public = DH_YC};
dec_hs(?FINISHED, VerifyData, _, _) ->
#finished{verify_data = VerifyData};
dec_hs(_, _, _, _) ->
throw(?ALERT_REC(?FATAL, ?HANDSHAKE_FAILURE)).
encrypted_premaster_secret(Secret, RSAPublicKey) ->
try
PreMasterSecret = public_key:encrypt_public(Secret, RSAPublicKey,
[{rsa_pad,
rsa_pkcs1_padding}]),
#encrypted_premaster_secret{premaster_secret = PreMasterSecret}
catch
_:_->
throw(?ALERT_REC(?FATAL, ?HANDSHAKE_FAILURE))
end.
decrypt_premaster_secret(Secret, RSAPrivateKey) ->
try public_key:decrypt_private(Secret, RSAPrivateKey,
[{rsa_pad, rsa_pkcs1_padding}])
catch
_:_ ->
throw(?ALERT_REC(?FATAL, ?DECRYPTION_FAILED))
end.
%% encode/decode stream of certificate data to/from list of certificate data
certs_to_list(ASN1Certs) ->
certs_to_list(ASN1Certs, []).
certs_to_list(<<?UINT24(CertLen), Cert:CertLen/binary, Rest/binary>>, Acc) ->
certs_to_list(Rest, [Cert | Acc]);
certs_to_list(<<>>, Acc) ->
lists:reverse(Acc, []).
certs_from_list(ACList) ->
list_to_binary([begin
CertLen = byte_size(Cert),
<<?UINT24(CertLen), Cert/binary>>
end || Cert <- ACList]).
enc_hs(#hello_request{}, _Version, _) ->
{?HELLO_REQUEST, <<>>};
enc_hs(#client_hello{
client_version = {Major, Minor},
random = Random,
session_id = SessionID,
cipher_suites = CipherSuites,
compression_methods = CompMethods}, _Version, _) ->
SIDLength = byte_size(SessionID),
BinCompMethods = list_to_binary(CompMethods),
CmLength = byte_size(BinCompMethods),
BinCipherSuites = list_to_binary(CipherSuites),
CsLength = byte_size(BinCipherSuites),
{?CLIENT_HELLO, <<?BYTE(Major), ?BYTE(Minor), Random:32/binary,
?BYTE(SIDLength), SessionID/binary,
?UINT16(CsLength), BinCipherSuites/binary,
?BYTE(CmLength), BinCompMethods/binary>>};
enc_hs(#server_hello{
server_version = {Major, Minor},
random = Random,
session_id = Session_ID,
cipher_suite = Cipher_suite,
compression_method = Comp_method}, _Version, _) ->
SID_length = byte_size(Session_ID),
{?SERVER_HELLO, <<?BYTE(Major), ?BYTE(Minor), Random:32/binary,
?BYTE(SID_length), Session_ID/binary,
Cipher_suite/binary, ?BYTE(Comp_method)>>};
enc_hs(#certificate{asn1_certificates = ASN1CertList}, _Version, _) ->
ASN1Certs = certs_from_list(ASN1CertList),
ACLen = erlang:iolist_size(ASN1Certs),
{?CERTIFICATE, <<?UINT24(ACLen), ASN1Certs:ACLen/binary>>};
enc_hs(#server_key_exchange{params = #server_rsa_params{rsa_modulus = Mod,
rsa_exponent = Exp},
signed_params = SignedParams}, _Version, _) ->
ModLen = byte_size(Mod),
ExpLen = byte_size(Exp),
{?SERVER_KEY_EXCHANGE, <<?UINT16(ModLen), Mod/binary,
?UINT16(ExpLen), Exp/binary,
SignedParams/binary>>
};
enc_hs(#server_key_exchange{params = #server_dh_params{
dh_p = P, dh_g = G, dh_y = Y},
signed_params = SignedParams}, _Version, _) ->
PLen = byte_size(P),
GLen = byte_size(G),
YLen = byte_size(Y),
{?SERVER_KEY_EXCHANGE, <<?UINT16(PLen), P:PLen/binary,
?UINT16(GLen), G:GLen/binary,
?UINT16(YLen), Y:YLen/binary,
SignedParams/binary>>
};
enc_hs(#certificate_request{certificate_types = CertTypes,
certificate_authorities = CertAuths},
_Version, _) ->
CertTypesLen = byte_size(CertTypes),
CertAuthsLen = byte_size(CertAuths),
{?CERTIFICATE_REQUEST,
<<?BYTE(CertTypesLen), CertTypes/binary,
?UINT16(CertAuthsLen), CertAuths/binary>>
};
enc_hs(#server_hello_done{}, _Version, _) ->
{?SERVER_HELLO_DONE, <<>>};
enc_hs(#client_key_exchange{exchange_keys = ExchangeKeys}, Version, _) ->
{?CLIENT_KEY_EXCHANGE, enc_cke(ExchangeKeys, Version)};
enc_hs(#certificate_verify{signature = BinSig}, _, _) ->
EncSig = enc_bin_sig(BinSig),
{?CERTIFICATE_VERIFY, EncSig};
enc_hs(#finished{verify_data = VerifyData}, _Version, _) ->
{?FINISHED, VerifyData}.
enc_cke(#encrypted_premaster_secret{premaster_secret = PKEPMS},{3, 0}) ->
PKEPMS;
enc_cke(#encrypted_premaster_secret{premaster_secret = PKEPMS}, _) ->
PKEPMSLen = byte_size(PKEPMS),
<<?UINT16(PKEPMSLen), PKEPMS/binary>>;
enc_cke(#client_diffie_hellman_public{dh_public = DHPublic}, _) ->
Len = byte_size(DHPublic),
<<?UINT16(Len), DHPublic/binary>>.
enc_bin_sig(BinSig) ->
Size = byte_size(BinSig),
<<?UINT16(Size), BinSig/binary>>.
init_hashes() ->
T = {crypto:md5_init(), crypto:sha_init()},
{T, T}.
update_hashes(Hashes, % special-case SSL2 client hello
<<?CLIENT_HELLO, ?UINT24(_), ?BYTE(Major), ?BYTE(Minor),
?UINT16(CSLength), ?UINT16(0),
?UINT16(CDLength),
CipherSuites:CSLength/binary,
ChallengeData:CDLength/binary>>) ->
update_hashes(Hashes,
<<?CLIENT_HELLO, ?BYTE(Major), ?BYTE(Minor),
?UINT16(CSLength), ?UINT16(0),
?UINT16(CDLength),
CipherSuites:CSLength/binary,
ChallengeData:CDLength/binary>>);
update_hashes({{MD50, SHA0}, _Prev}, Data) ->
?DBG_HEX(Data),
{MD51, SHA1} = {crypto:md5_update(MD50, Data),
crypto:sha_update(SHA0, Data)},
?DBG_HEX(crypto:md5_final(MD51)),
?DBG_HEX(crypto:sha_final(SHA1)),
{{MD51, SHA1}, {MD50, SHA0}}.
from_3bytes(Bin3) ->
from_3bytes(Bin3, []).
from_3bytes(<<>>, Acc) ->
lists:reverse(Acc);
from_3bytes(<<?UINT24(N), Rest/binary>>, Acc) ->
from_3bytes(Rest, [?uint16(N) | Acc]).
from_2bytes(Bin2) ->
from_2bytes(Bin2, []).
from_2bytes(<<>>, Acc) ->
lists:reverse(Acc);
from_2bytes(<<?UINT16(N), Rest/binary>>, Acc) ->
from_2bytes(Rest, [?uint16(N) | Acc]).
certificate_types({KeyExchange, _, _, _})
when KeyExchange == rsa;
KeyExchange == dh_dss;
KeyExchange == dh_rsa;
KeyExchange == dhe_dss;
KeyExchange == dhe_rsa ->
<<?BYTE(?RSA_SIGN), ?BYTE(?DSS_SIGN)>>;
certificate_types(_) ->
%%TODO: Is this a good default,
%% is there a case where we like to request
%% a RSA_FIXED_DH or DSS_FIXED_DH
<<?BYTE(?RSA_SIGN)>>.
certificate_authorities(CertDbRef) ->
Authorities = certificate_authorities_from_db(CertDbRef),
Enc = fun(#'OTPCertificate'{tbsCertificate=TBSCert}) ->
OTPSubj = TBSCert#'OTPTBSCertificate'.subject,
Subj = public_key:pkix_transform(OTPSubj, encode),
{ok, DNEncoded} = 'OTP-PUB-KEY':encode('Name', Subj),
DNEncodedBin = iolist_to_binary(DNEncoded),
DNEncodedLen = byte_size(DNEncodedBin),
<<?UINT16(DNEncodedLen), DNEncodedBin/binary>>
end,
list_to_binary([Enc(Cert) || {_, Cert} <- Authorities]).
certificate_authorities_from_db(CertDbRef) ->
certificate_authorities_from_db(CertDbRef, no_candidate, []).
certificate_authorities_from_db(CertDbRef, PrevKey, Acc) ->
case ssl_certificate_db:issuer_candidate(PrevKey) of
no_more_candidates ->
lists:reverse(Acc);
{{CertDbRef, _, _} = Key, Cert} ->
certificate_authorities_from_db(CertDbRef, Key, [Cert|Acc]);
{Key, _Cert} ->
%% skip certs not from this ssl connection
certificate_authorities_from_db(CertDbRef, Key, Acc)
end.
digitally_signed(Hashes, #'RSAPrivateKey'{} = Key) ->
public_key:encrypt_private(Hashes, Key,
[{rsa_pad, rsa_pkcs1_padding}]);
digitally_signed(Hashes, #'DSAPrivateKey'{} = Key) ->
public_key:sign(Hashes, Key).
calc_master_secret({3,0}, PremasterSecret, ClientRandom, ServerRandom) ->
ssl_ssl3:master_secret(PremasterSecret, ClientRandom, ServerRandom);
calc_master_secret({3,N},PremasterSecret, ClientRandom, ServerRandom)
when N == 1; N == 2 ->
ssl_tls1:master_secret(PremasterSecret, ClientRandom, ServerRandom).
setup_keys({3,0}, Exportable, MasterSecret,
ServerRandom, ClientRandom, HashSize, KML, EKML, IVS) ->
ssl_ssl3:setup_keys(Exportable, MasterSecret, ServerRandom,
ClientRandom, HashSize, KML, EKML, IVS);
setup_keys({3,1}, _Exportable, MasterSecret,
ServerRandom, ClientRandom, HashSize, KML, _EKML, IVS) ->
ssl_tls1:setup_keys(MasterSecret, ServerRandom, ClientRandom, HashSize,
KML, IVS);
setup_keys({3,2}, _Exportable, MasterSecret,
ServerRandom, ClientRandom, HashSize, KML, _EKML, _IVS) ->
ssl_tls1:setup_keys(MasterSecret, ServerRandom,
ClientRandom, HashSize, KML).
calc_finished({3, 0}, Role, MasterSecret, Hashes) ->
ssl_ssl3:finished(Role, MasterSecret, Hashes);
calc_finished({3, N}, Role, MasterSecret, Hashes)
when N == 1; N == 2 ->
ssl_tls1:finished(Role, MasterSecret, Hashes).
calc_certificate_verify({3, 0}, MasterSecret, Algorithm, Hashes) ->
ssl_ssl3:certificate_verify(Algorithm, MasterSecret, Hashes);
calc_certificate_verify({3, N}, _, Algorithm, Hashes)
when N == 1; N == 2 ->
ssl_tls1:certificate_verify(Algorithm, Hashes).
%% server_key_exchange_hash(Algorithm, Value) when Algorithm == rsa;
%% Algorithm == dh_rsa;
%% Algorithm == dhe_rsa ->
%% MD5 = crypto:md5_final(Value),
%% SHA = crypto:sha_final(Value),
%% <<MD5/binary, SHA/binary>>;
%% server_key_exchange_hash(Algorithm, Value) when Algorithm == dh_dss;
%% Algorithm == dhe_dss ->
%% crypto:sha_final(Value).