%% %% %CopyrightBegin% %% %% Copyright Ericsson AB 2013-2013. 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: Common handling of a TLS/SSL/DTLS connection, see also %% tls_connection.erl and dtls_connection.erl %%---------------------------------------------------------------------- -module(ssl_connection). -include("ssl_api.hrl"). -include("ssl_connection.hrl"). -include("ssl_handshake.hrl"). -include("ssl_alert.hrl"). -include("ssl_record.hrl"). -include("ssl_cipher.hrl"). -include("ssl_internal.hrl"). -include("ssl_srp.hrl"). -include_lib("public_key/include/public_key.hrl"). %% Setup -export([connect/8, ssl_accept/7, handshake/2, socket_control/4]). %% User Events -export([send/2, recv/3, close/1, shutdown/2, new_user/2, get_opts/2, set_opts/2, info/1, session_info/1, peer_certificate/1, renegotiation/1, negotiated_next_protocol/1, prf/5 ]). -export([handle_session/6]). %% SSL FSM state functions -export([hello/3, abbreviated/3, certify/3, cipher/3, connection/3]). %% SSL all state functions -export([handle_sync_event/4, handle_info/3, terminate/3]). %%==================================================================== %% Internal application API %%==================================================================== %%-------------------------------------------------------------------- -spec connect(tls_connection | dtls_connection, host(), inet:port_number(), port(), {#ssl_options{}, #socket_options{}}, pid(), tuple(), timeout()) -> {ok, #sslsocket{}} | {error, reason()}. %% %% Description: Connect to an ssl server. %%-------------------------------------------------------------------- connect(Connection, Host, Port, Socket, Options, User, CbInfo, Timeout) -> try Connection:start_fsm(client, Host, Port, Socket, Options, User, CbInfo, Timeout) catch exit:{noproc, _} -> {error, ssl_not_started} end. %%-------------------------------------------------------------------- -spec ssl_accept(tls_connection | dtls_connection, inet:port_number(), port(), {#ssl_options{}, #socket_options{}}, pid(), tuple(), timeout()) -> {ok, #sslsocket{}} | {error, reason()}. %% %% Description: Performs accept on an ssl listen socket. e.i. performs %% ssl handshake. %%-------------------------------------------------------------------- ssl_accept(Connection, Port, Socket, Opts, User, CbInfo, Timeout) -> try Connection:start_fsm(server, "localhost", Port, Socket, Opts, User, CbInfo, Timeout) catch exit:{noproc, _} -> {error, ssl_not_started} end. %%-------------------------------------------------------------------- -spec handshake(#sslsocket{}, timeout()) -> ok | {error, reason()}. %% %% Description: Starts ssl handshake. %%-------------------------------------------------------------------- handshake(#sslsocket{pid = Pid}, Timeout) -> case sync_send_all_state_event(Pid, {start, Timeout}) of connected -> ok; Error -> Error end. %-------------------------------------------------------------------- -spec socket_control(tls_connection | dtls_connection, port(), pid(), atom()) -> {ok, #sslsocket{}} | {error, reason()}. %% %% Description: Set the ssl process to own the accept socket %%-------------------------------------------------------------------- socket_control(Connection, Socket, Pid, Transport) -> case Transport:controlling_process(Socket, Pid) of ok -> {ok, ssl_socket:socket(Pid, Transport, Socket, Connection)}; {error, Reason} -> {error, Reason} end. %%-------------------------------------------------------------------- -spec send(pid(), iodata()) -> ok | {error, reason()}. %% %% Description: Sends data over the ssl connection %%-------------------------------------------------------------------- send(Pid, Data) -> sync_send_all_state_event(Pid, {application_data, %% iolist_to_binary should really %% be called iodata_to_binary() erlang:iolist_to_binary(Data)}). %%-------------------------------------------------------------------- -spec recv(pid(), integer(), timeout()) -> {ok, binary() | list()} | {error, reason()}. %% %% Description: Receives data when active = false %%-------------------------------------------------------------------- recv(Pid, Length, Timeout) -> sync_send_all_state_event(Pid, {recv, Length, Timeout}). %%-------------------------------------------------------------------- -spec close(pid()) -> ok | {error, reason()}. %% %% Description: Close an ssl connection %%-------------------------------------------------------------------- close(ConnectionPid) -> case sync_send_all_state_event(ConnectionPid, close) of {error, closed} -> ok; Other -> Other end. %%-------------------------------------------------------------------- -spec shutdown(pid(), atom()) -> ok | {error, reason()}. %% %% Description: Same as gen_tcp:shutdown/2 %%-------------------------------------------------------------------- shutdown(ConnectionPid, How) -> sync_send_all_state_event(ConnectionPid, {shutdown, How}). %%-------------------------------------------------------------------- -spec new_user(pid(), pid()) -> ok | {error, reason()}. %% %% Description: Changes process that receives the messages when active = true %% or once. %%-------------------------------------------------------------------- new_user(ConnectionPid, User) -> sync_send_all_state_event(ConnectionPid, {new_user, User}). %%-------------------------------------------------------------------- -spec negotiated_next_protocol(pid()) -> {ok, binary()} | {error, reason()}. %% %% Description: Returns the negotiated protocol %%-------------------------------------------------------------------- negotiated_next_protocol(ConnectionPid) -> sync_send_all_state_event(ConnectionPid, negotiated_next_protocol). %%-------------------------------------------------------------------- -spec get_opts(pid(), list()) -> {ok, list()} | {error, reason()}. %% %% Description: Same as inet:getopts/2 %%-------------------------------------------------------------------- get_opts(ConnectionPid, OptTags) -> sync_send_all_state_event(ConnectionPid, {get_opts, OptTags}). %%-------------------------------------------------------------------- -spec set_opts(pid(), list()) -> ok | {error, reason()}. %% %% Description: Same as inet:setopts/2 %%-------------------------------------------------------------------- set_opts(ConnectionPid, Options) -> sync_send_all_state_event(ConnectionPid, {set_opts, Options}). %%-------------------------------------------------------------------- -spec info(pid()) -> {ok, {atom(), tuple()}} | {error, reason()}. %% %% Description: Returns ssl protocol and cipher used for the connection %%-------------------------------------------------------------------- info(ConnectionPid) -> sync_send_all_state_event(ConnectionPid, info). %%-------------------------------------------------------------------- -spec session_info(pid()) -> {ok, list()} | {error, reason()}. %% %% Description: Returns info about the ssl session %%-------------------------------------------------------------------- session_info(ConnectionPid) -> sync_send_all_state_event(ConnectionPid, session_info). %%-------------------------------------------------------------------- -spec peer_certificate(pid()) -> {ok, binary()| undefined} | {error, reason()}. %% %% Description: Returns the peer cert %%-------------------------------------------------------------------- peer_certificate(ConnectionPid) -> sync_send_all_state_event(ConnectionPid, peer_certificate). %%-------------------------------------------------------------------- -spec renegotiation(pid()) -> ok | {error, reason()}. %% %% Description: Starts a renegotiation of the ssl session. %%-------------------------------------------------------------------- renegotiation(ConnectionPid) -> sync_send_all_state_event(ConnectionPid, renegotiate). %%-------------------------------------------------------------------- -spec prf(pid(), binary() | 'master_secret', binary(), binary() | ssl:prf_random(), non_neg_integer()) -> {ok, binary()} | {error, reason()} | {'EXIT', term()}. %% %% Description: use a ssl sessions TLS PRF to generate key material %%-------------------------------------------------------------------- prf(ConnectionPid, Secret, Label, Seed, WantedLength) -> sync_send_all_state_event(ConnectionPid, {prf, Secret, Label, Seed, WantedLength}). handle_session(#server_hello{cipher_suite = CipherSuite, compression_method = Compression}, Version, NewId, ConnectionStates, NextProtocol, #state{session = #session{session_id = OldId}, negotiated_version = ReqVersion} = State0) -> {KeyAlgorithm, _, _, _} = ssl_cipher:suite_definition(CipherSuite), PremasterSecret = make_premaster_secret(ReqVersion, KeyAlgorithm), NewNextProtocol = case NextProtocol of undefined -> State0#state.next_protocol; _ -> NextProtocol end, State = State0#state{key_algorithm = KeyAlgorithm, negotiated_version = Version, connection_states = ConnectionStates, premaster_secret = PremasterSecret, expecting_next_protocol_negotiation = NextProtocol =/= undefined, next_protocol = NewNextProtocol}, case ssl_session:is_new(OldId, NewId) of true -> handle_new_session(NewId, CipherSuite, Compression, State#state{connection_states = ConnectionStates}); false -> handle_resumed_session(NewId, State#state{connection_states = ConnectionStates}) end. %%-------------------------------------------------------------------- -spec hello(start | #hello_request{} | #server_hello{} | term(), #state{}, tls_connection | dtls_connection) -> gen_fsm_state_return(). %%-------------------------------------------------------------------- hello(start, #state{role = server} = State0, Connection) -> {Record, State} = Connection:next_record(State0), Connection:next_state(hello, hello, Record, State); hello(#hello_request{}, #state{role = client} = State0, Connection) -> {Record, State} = Connection:next_record(State0), Connection:next_state(hello, hello, Record, State); hello({common_client_hello, Type, ServerHelloExt, HashSign}, #state{session = #session{cipher_suite = CipherSuite}, negotiated_version = Version} = State, Connection) -> {KeyAlg, _, _, _} = ssl_cipher:suite_definition(CipherSuite), NegotiatedHashSign = negotiated_hashsign(HashSign, KeyAlg, Version), do_server_hello(Type, ServerHelloExt, State#state{hashsign_algorithm = NegotiatedHashSign}, Connection); hello(timeout, State, _) -> {next_state, hello, State, hibernate}; hello(Msg, State, Connection) -> Connection:handle_unexpected_message(Msg, hello, State). %%-------------------------------------------------------------------- -spec abbreviated(#hello_request{} | #finished{} | term(), #state{}, tls_connection | dtls_connection) -> gen_fsm_state_return(). %%-------------------------------------------------------------------- abbreviated(#hello_request{}, State0, Connection) -> {Record, State} = Connection:next_record(State0), Connection:next_state(abbreviated, hello, Record, State); abbreviated(#finished{verify_data = Data} = Finished, #state{role = server, negotiated_version = Version, tls_handshake_history = Handshake, session = #session{master_secret = MasterSecret}, connection_states = ConnectionStates0} = State, Connection) -> case ssl_handshake:verify_connection(Version, Finished, client, get_current_prf(ConnectionStates0, write), MasterSecret, Handshake) of verified -> ConnectionStates = ssl_record:set_client_verify_data(current_both, Data, ConnectionStates0), Connection:next_state_connection(abbreviated, ack_connection( State#state{connection_states = ConnectionStates})); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, abbreviated, State) end; abbreviated(#finished{verify_data = Data} = Finished, #state{role = client, tls_handshake_history = Handshake0, session = #session{master_secret = MasterSecret}, negotiated_version = Version, connection_states = ConnectionStates0} = State0, Connection) -> case ssl_handshake:verify_connection(Version, Finished, server, get_pending_prf(ConnectionStates0, write), MasterSecret, Handshake0) of verified -> ConnectionStates1 = ssl_record:set_server_verify_data(current_read, Data, ConnectionStates0), State = finalize_handshake(State0#state{connection_states = ConnectionStates1}, abbreviated, Connection), Connection:next_state_connection(abbreviated, ack_connection(State)); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, abbreviated, State0) end; %% only allowed to send next_protocol message after change cipher spec %% & before finished message and it is not allowed during renegotiation abbreviated(#next_protocol{selected_protocol = SelectedProtocol}, #state{role = server, expecting_next_protocol_negotiation = true} = State0, Connection) -> {Record, State} = Connection:next_record(State0#state{next_protocol = SelectedProtocol}), Connection:next_state(abbreviated, abbreviated, Record, State); abbreviated(timeout, State, _) -> {next_state, abbreviated, State, hibernate }; abbreviated(Msg, State, Connection) -> Connection:handle_unexpected_message(Msg, abbreviated, State). %%-------------------------------------------------------------------- -spec certify(#hello_request{} | #certificate{} | #server_key_exchange{} | #certificate_request{} | #server_hello_done{} | #client_key_exchange{} | term(), #state{}, tls_connection | dtls_connection) -> gen_fsm_state_return(). %%-------------------------------------------------------------------- certify(#hello_request{}, State0, Connection) -> {Record, State} = Connection:next_record(State0), Connection:next_state(certify, hello, Record, State); certify(#certificate{asn1_certificates = []}, #state{role = server, negotiated_version = Version, ssl_options = #ssl_options{verify = verify_peer, fail_if_no_peer_cert = true}} = State, Connection) -> Alert = ?ALERT_REC(?FATAL,?HANDSHAKE_FAILURE), Connection:handle_own_alert(Alert, Version, certify, State); certify(#certificate{asn1_certificates = []}, #state{role = server, ssl_options = #ssl_options{verify = verify_peer, fail_if_no_peer_cert = false}} = State0, Connection) -> {Record, State} = Connection:next_record(State0#state{client_certificate_requested = false}), Connection:next_state(certify, certify, Record, State); certify(#certificate{} = Cert, #state{negotiated_version = Version, role = Role, cert_db = CertDbHandle, cert_db_ref = CertDbRef, ssl_options = Opts} = State, Connection) -> case ssl_handshake:certify(Cert, CertDbHandle, CertDbRef, Opts#ssl_options.depth, Opts#ssl_options.verify, Opts#ssl_options.verify_fun, Role) of {PeerCert, PublicKeyInfo} -> handle_peer_cert(Role, PeerCert, PublicKeyInfo, State#state{client_certificate_requested = false}, Connection); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, certify, State) end; certify(#server_key_exchange{exchange_keys = Keys}, #state{role = client, negotiated_version = Version, key_algorithm = Alg, public_key_info = PubKeyInfo, connection_states = ConnectionStates} = State, Connection) when Alg == dhe_dss; Alg == dhe_rsa; Alg == ecdhe_rsa; Alg == ecdhe_ecdsa; Alg == dh_anon; Alg == ecdh_anon; Alg == psk; Alg == dhe_psk; Alg == rsa_psk; Alg == srp_dss; Alg == srp_rsa; Alg == srp_anon -> Params = ssl_handshake:decode_server_key(Keys, Alg, Version), HashSign = negotiated_hashsign(Params#server_key_params.hashsign, Alg, Version), case is_anonymous(Alg) of true -> calculate_secret(Params#server_key_params.params, State#state{hashsign_algorithm = HashSign}, Connection); false -> case ssl_handshake:verify_server_key(Params, HashSign, ConnectionStates, Version, PubKeyInfo) of true -> calculate_secret(Params#server_key_params.params, State#state{hashsign_algorithm = HashSign}, Connection); false -> ?ALERT_REC(?FATAL, ?DECRYPT_ERROR) end end; certify(#server_key_exchange{} = Msg, #state{role = client, key_algorithm = rsa} = State, Connection) -> Connection:handle_unexpected_message(Msg, certify_server_keyexchange, State); certify(#certificate_request{hashsign_algorithms = HashSigns}, #state{session = #session{own_certificate = Cert}} = State0, Connection) -> HashSign = ssl_handshake:select_hashsign(HashSigns, Cert), {Record, State} = Connection:next_record(State0#state{client_certificate_requested = true}), Connection:next_state(certify, certify, Record, State#state{cert_hashsign_algorithm = HashSign}); %% PSK and RSA_PSK might bypass the Server-Key-Exchange certify(#server_hello_done{}, #state{session = #session{master_secret = undefined}, negotiated_version = Version, psk_identity = PSKIdentity, ssl_options = #ssl_options{user_lookup_fun = PSKLookup}, premaster_secret = undefined, role = client, key_algorithm = Alg} = State0, Connection) when Alg == psk -> case ssl_handshake:premaster_secret({Alg, PSKIdentity}, PSKLookup) of #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, certify, State0); PremasterSecret -> State = master_secret(PremasterSecret, State0#state{premaster_secret = PremasterSecret}), client_certify_and_key_exchange(State, Connection) end; certify(#server_hello_done{}, #state{session = #session{master_secret = undefined}, ssl_options = #ssl_options{user_lookup_fun = PSKLookup}, negotiated_version = {Major, Minor}, psk_identity = PSKIdentity, premaster_secret = undefined, role = client, key_algorithm = Alg} = State0, Connection) when Alg == rsa_psk -> Rand = ssl:random_bytes(?NUM_OF_PREMASTERSECRET_BYTES-2), RSAPremasterSecret = <>, case ssl_handshake:premaster_secret({Alg, PSKIdentity}, PSKLookup, RSAPremasterSecret) of #alert{} = Alert -> Alert; PremasterSecret -> State = master_secret(PremasterSecret, State0#state{premaster_secret = RSAPremasterSecret}), client_certify_and_key_exchange(State, Connection) end; %% Master secret was determined with help of server-key exchange msg certify(#server_hello_done{}, #state{session = #session{master_secret = MasterSecret} = Session, connection_states = ConnectionStates0, negotiated_version = Version, premaster_secret = undefined, role = client} = State0, Connection) -> case ssl_handshake:master_secret(record_cb(Connection), Version, Session, ConnectionStates0, client) of {MasterSecret, ConnectionStates} -> State = State0#state{connection_states = ConnectionStates}, client_certify_and_key_exchange(State, Connection); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, certify, State0) end; %% Master secret is calculated from premaster_secret certify(#server_hello_done{}, #state{session = Session0, connection_states = ConnectionStates0, negotiated_version = Version, premaster_secret = PremasterSecret, role = client} = State0, Connection) -> case ssl_handshake:master_secret(record_cb(Connection), Version, PremasterSecret, ConnectionStates0, client) of {MasterSecret, ConnectionStates} -> Session = Session0#session{master_secret = MasterSecret}, State = State0#state{connection_states = ConnectionStates, session = Session}, client_certify_and_key_exchange(State, Connection); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, certify, State0) end; certify(#client_key_exchange{} = Msg, #state{role = server, client_certificate_requested = true, ssl_options = #ssl_options{fail_if_no_peer_cert = true}} = State, Connection) -> %% We expect a certificate here Connection:handle_unexpected_message(Msg, certify_client_key_exchange, State); certify(#client_key_exchange{exchange_keys = Keys}, State = #state{key_algorithm = KeyAlg, negotiated_version = Version}, Connection) -> try certify_client_key_exchange(ssl_handshake:decode_client_key(Keys, KeyAlg, Version), State, Connection) catch #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, certify, State) end; certify(timeout, State, _) -> {next_state, certify, State, hibernate}; certify(Msg, State, Connection) -> Connection:handle_unexpected_message(Msg, certify, State). %%-------------------------------------------------------------------- -spec cipher(#hello_request{} | #certificate_verify{} | #finished{} | term(), #state{}, tls_connection | dtls_connection) -> gen_fsm_state_return(). %%-------------------------------------------------------------------- cipher(#hello_request{}, State0, Connection) -> {Record, State} = Connection:next_record(State0), Connection:next_state(cipher, hello, Record, State); cipher(#certificate_verify{signature = Signature, hashsign_algorithm = CertHashSign}, #state{role = server, public_key_info = {Algo, _, _} =PublicKeyInfo, negotiated_version = Version, session = #session{master_secret = MasterSecret}, tls_handshake_history = Handshake } = State0, Connection) -> HashSign = ssl_handshake:select_cert_hashsign(CertHashSign, Algo, Version), case ssl_handshake:certificate_verify(Signature, PublicKeyInfo, Version, HashSign, MasterSecret, Handshake) of valid -> {Record, State} = Connection:next_record(State0), Connection:next_state(cipher, cipher, Record, State#state{cert_hashsign_algorithm = HashSign}); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, cipher, State0) end; %% client must send a next protocol message if we are expecting it cipher(#finished{}, #state{role = server, expecting_next_protocol_negotiation = true, next_protocol = undefined, negotiated_version = Version} = State0, Connection) -> Connection:handle_own_alert(?ALERT_REC(?FATAL,?UNEXPECTED_MESSAGE), Version, cipher, State0); cipher(#finished{verify_data = Data} = Finished, #state{negotiated_version = Version, host = Host, port = Port, role = Role, session = #session{master_secret = MasterSecret} = Session0, connection_states = ConnectionStates0, tls_handshake_history = Handshake0} = State, Connection) -> case ssl_handshake:verify_connection(Version, Finished, opposite_role(Role), get_current_prf(ConnectionStates0, read), MasterSecret, Handshake0) of verified -> Session = register_session(Role, Host, Port, Session0), cipher_role(Role, Data, Session, State, Connection); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, cipher, State) end; %% only allowed to send next_protocol message after change cipher spec %% & before finished message and it is not allowed during renegotiation cipher(#next_protocol{selected_protocol = SelectedProtocol}, #state{role = server, expecting_next_protocol_negotiation = true} = State0, Connection) -> {Record, State} = Connection:next_record(State0#state{next_protocol = SelectedProtocol}), Connection:next_state(cipher, cipher, Record, State); cipher(timeout, State, _) -> {next_state, cipher, State, hibernate}; cipher(Msg, State, Connection) -> Connection:handle_unexpected_message(Msg, cipher, State). %%-------------------------------------------------------------------- -spec connection(term(), #state{}, tls_connection | dtls_connection) -> gen_fsm_state_return(). %%-------------------------------------------------------------------- connection(timeout, State, _) -> {next_state, connection, State, hibernate}; connection(Msg, State, Connection) -> Connection:handle_unexpected_message(Msg, connection, State). %%-------------------------------------------------------------------- %% Description: Whenever a gen_fsm receives an event sent using %% gen_fsm:sync_send_all_state_event/2,3, this function is called to handle %% the event. %%-------------------------------------------------------------------- handle_sync_event({application_data, Data}, From, connection, #state{protocol_cb = Connection} = State) -> %% We should look into having a worker process to do this to %% parallize send and receive decoding and not block the receiver %% if sending is overloading the socket. try Connection:write_application_data(Data, From, State) catch throw:Error -> {reply, Error, connection, State, get_timeout(State)} end; handle_sync_event({application_data, Data}, From, StateName, #state{send_queue = Queue} = State) -> %% In renegotiation priorities handshake, send data when handshake is finished {next_state, StateName, State#state{send_queue = queue:in({From, Data}, Queue)}, get_timeout(State)}; handle_sync_event({start, Timeout}, StartFrom, hello, #state{protocol_cb = Connection} = State) -> Timer = start_or_recv_cancel_timer(Timeout, StartFrom), Connection:hello(start, State#state{start_or_recv_from = StartFrom, timer = Timer}); %% The two clauses below could happen if a server upgrades a socket in %% active mode. Note that in this case we are lucky that %% controlling_process has been evalueated before receiving handshake %% messages from client. The server should put the socket in passive %% mode before telling the client that it is willing to upgrade %% and before calling ssl:ssl_accept/2. These clauses are %% here to make sure it is the users problem and not owers if %% they upgrade an active socket. handle_sync_event({start,_}, _, connection, State) -> {reply, connected, connection, State, get_timeout(State)}; handle_sync_event({start,_}, _From, error, {Error, State = #state{}}) -> {stop, {shutdown, Error}, {error, Error}, State}; handle_sync_event({start, Timeout}, StartFrom, StateName, State) -> Timer = start_or_recv_cancel_timer(Timeout, StartFrom), {next_state, StateName, State#state{start_or_recv_from = StartFrom, timer = Timer}, get_timeout(State)}; handle_sync_event(close, _, StateName, #state{protocol_cb = Connection} = State) -> %% Run terminate before returning %% so that the reuseaddr inet-option will work %% as intended. (catch Connection:terminate(user_close, StateName, State)), {stop, normal, ok, State#state{terminated = true}}; handle_sync_event({shutdown, How0}, _, StateName, #state{transport_cb = Transport, negotiated_version = Version, connection_states = ConnectionStates, socket = Socket} = State) -> case How0 of How when How == write; How == both -> Alert = ?ALERT_REC(?WARNING, ?CLOSE_NOTIFY), {BinMsg, _} = ssl_alert:encode(Alert, Version, ConnectionStates), Transport:send(Socket, BinMsg); _ -> ok end, case Transport:shutdown(Socket, How0) of ok -> {reply, ok, StateName, State, get_timeout(State)}; Error -> {stop, normal, Error, State} end; handle_sync_event({recv, N, Timeout}, RecvFrom, connection = StateName, #state{protocol_cb = Connection} = State0) -> Timer = start_or_recv_cancel_timer(Timeout, RecvFrom), Connection:passive_receive(State0#state{bytes_to_read = N, start_or_recv_from = RecvFrom, timer = Timer}, StateName); %% Doing renegotiate wait with handling request until renegotiate is %% finished. Will be handled by next_state_is_connection/2. handle_sync_event({recv, N, Timeout}, RecvFrom, StateName, State) -> Timer = start_or_recv_cancel_timer(Timeout, RecvFrom), {next_state, StateName, State#state{bytes_to_read = N, start_or_recv_from = RecvFrom, timer = Timer}, get_timeout(State)}; handle_sync_event({new_user, User}, _From, StateName, State =#state{user_application = {OldMon, _}}) -> NewMon = erlang:monitor(process, User), erlang:demonitor(OldMon, [flush]), {reply, ok, StateName, State#state{user_application = {NewMon,User}}, get_timeout(State)}; handle_sync_event({get_opts, OptTags}, _From, StateName, #state{socket = Socket, transport_cb = Transport, socket_options = SockOpts} = State) -> OptsReply = get_socket_opts(Transport, Socket, OptTags, SockOpts, []), {reply, OptsReply, StateName, State, get_timeout(State)}; handle_sync_event(negotiated_next_protocol, _From, StateName, #state{next_protocol = undefined} = State) -> {reply, {error, next_protocol_not_negotiated}, StateName, State, get_timeout(State)}; handle_sync_event(negotiated_next_protocol, _From, StateName, #state{next_protocol = NextProtocol} = State) -> {reply, {ok, NextProtocol}, StateName, State, get_timeout(State)}; handle_sync_event({set_opts, Opts0}, _From, StateName0, #state{socket_options = Opts1, protocol_cb = Connection, socket = Socket, transport_cb = Transport, user_data_buffer = Buffer} = State0) -> {Reply, Opts} = set_socket_opts(Transport, Socket, Opts0, Opts1, []), State1 = State0#state{socket_options = Opts}, if Opts#socket_options.active =:= false -> {reply, Reply, StateName0, State1, get_timeout(State1)}; Buffer =:= <<>>, Opts1#socket_options.active =:= false -> %% Need data, set active once {Record, State2} = Connection:next_record_if_active(State1), %% Note: Renogotiation may cause StateName0 =/= StateName case Connection:next_state(StateName0, StateName0, Record, State2) of {next_state, StateName, State, Timeout} -> {reply, Reply, StateName, State, Timeout}; {stop, Reason, State} -> {stop, Reason, State} end; Buffer =:= <<>> -> %% Active once already set {reply, Reply, StateName0, State1, get_timeout(State1)}; true -> case Connection:read_application_data(<<>>, State1) of Stop = {stop,_,_} -> Stop; {Record, State2} -> %% Note: Renogotiation may cause StateName0 =/= StateName case Connection:next_state(StateName0, StateName0, Record, State2) of {next_state, StateName, State, Timeout} -> {reply, Reply, StateName, State, Timeout}; {stop, Reason, State} -> {stop, Reason, State} end end end; handle_sync_event(renegotiate, From, connection, #state{protocol_cb = Connection} = State) -> Connection:renegotiate(State#state{renegotiation = {true, From}}); handle_sync_event(renegotiate, _, StateName, State) -> {reply, {error, already_renegotiating}, StateName, State, get_timeout(State)}; handle_sync_event({prf, Secret, Label, Seed, WantedLength}, _, StateName, #state{connection_states = ConnectionStates, negotiated_version = Version} = State) -> ConnectionState = ssl_record:current_connection_state(ConnectionStates, read), SecParams = ConnectionState#connection_state.security_parameters, #security_parameters{master_secret = MasterSecret, client_random = ClientRandom, server_random = ServerRandom} = SecParams, Reply = try SecretToUse = case Secret of _ when is_binary(Secret) -> Secret; master_secret -> MasterSecret end, SeedToUse = lists:reverse( lists:foldl(fun(X, Acc) when is_binary(X) -> [X|Acc]; (client_random, Acc) -> [ClientRandom|Acc]; (server_random, Acc) -> [ServerRandom|Acc] end, [], Seed)), ssl_handshake:prf(Version, SecretToUse, Label, SeedToUse, WantedLength) catch exit:_ -> {error, badarg}; error:Reason -> {error, Reason} end, {reply, Reply, StateName, State, get_timeout(State)}; handle_sync_event(info, _, StateName, #state{negotiated_version = Version, session = #session{cipher_suite = Suite}} = State) -> AtomVersion = tls_record:protocol_version(Version), {reply, {ok, {AtomVersion, ssl:suite_definition(Suite)}}, StateName, State, get_timeout(State)}; handle_sync_event(session_info, _, StateName, #state{session = #session{session_id = Id, cipher_suite = Suite}} = State) -> {reply, [{session_id, Id}, {cipher_suite, ssl:suite_definition(Suite)}], StateName, State, get_timeout(State)}; handle_sync_event(peer_certificate, _, StateName, #state{session = #session{peer_certificate = Cert}} = State) -> {reply, {ok, Cert}, StateName, State, get_timeout(State)}. handle_info({ErrorTag, Socket, econnaborted}, StateName, #state{socket = Socket, transport_cb = Transport, start_or_recv_from = StartFrom, role = Role, protocol_cb = Connection, error_tag = ErrorTag} = State) when StateName =/= connection -> Connection:alert_user(Transport, Socket, StartFrom, ?ALERT_REC(?FATAL, ?CLOSE_NOTIFY), Role), {stop, normal, State}; handle_info({ErrorTag, Socket, Reason}, StateName, #state{socket = Socket, protocol_cb = Connection, error_tag = ErrorTag} = State) -> Report = io_lib:format("SSL: Socket error: ~p ~n", [Reason]), error_logger:info_report(Report), Connection:handle_normal_shutdown(?ALERT_REC(?FATAL, ?CLOSE_NOTIFY), StateName, State), {stop, normal, State}; handle_info({'DOWN', MonitorRef, _, _, _}, _, State = #state{user_application={MonitorRef,_Pid}}) -> {stop, normal, State}; handle_info(allow_renegotiate, StateName, State) -> {next_state, StateName, State#state{allow_renegotiate = true}, get_timeout(State)}; handle_info({cancel_start_or_recv, StartFrom}, StateName, #state{renegotiation = {false, first}} = State) when StateName =/= connection -> gen_fsm:reply(StartFrom, {error, timeout}), {stop, {shutdown, user_timeout}, State#state{timer = undefined}}; handle_info({cancel_start_or_recv, RecvFrom}, StateName, #state{start_or_recv_from = RecvFrom} = State) -> gen_fsm:reply(RecvFrom, {error, timeout}), {next_state, StateName, State#state{start_or_recv_from = undefined, bytes_to_read = undefined, timer = undefined}, get_timeout(State)}; handle_info({cancel_start_or_recv, _RecvFrom}, StateName, State) -> {next_state, StateName, State#state{timer = undefined}, get_timeout(State)}; handle_info(Msg, StateName, #state{socket = Socket, error_tag = Tag} = State) -> Report = io_lib:format("SSL: Got unexpected info: ~p ~n", [{Msg, Tag, Socket}]), error_logger:info_report(Report), {next_state, StateName, State, get_timeout(State)}. terminate(_, _, #state{terminated = true}) -> %% Happens when user closes the connection using ssl:close/1 %% we want to guarantee that Transport:close has been called %% when ssl:close/1 returns. ok; terminate({shutdown, transport_closed}, StateName, #state{send_queue = SendQueue, renegotiation = Renegotiate} = State) -> handle_unrecv_data(StateName, State), handle_trusted_certs_db(State), notify_senders(SendQueue), notify_renegotiater(Renegotiate); terminate({shutdown, own_alert}, _StateName, #state{send_queue = SendQueue, renegotiation = Renegotiate} = State) -> handle_trusted_certs_db(State), notify_senders(SendQueue), notify_renegotiater(Renegotiate); terminate(Reason, connection, #state{negotiated_version = Version, protocol_cb = Connection, connection_states = ConnectionStates, transport_cb = Transport, socket = Socket, send_queue = SendQueue, renegotiation = Renegotiate} = State) -> handle_trusted_certs_db(State), notify_senders(SendQueue), notify_renegotiater(Renegotiate), BinAlert = terminate_alert(Reason, Version, ConnectionStates), Transport:send(Socket, BinAlert), case Connection of tls_connection -> tls_connection:workaround_transport_delivery_problems(Socket, Transport); _ -> ok end; terminate(_Reason, _StateName, #state{transport_cb = Transport, socket = Socket, send_queue = SendQueue, renegotiation = Renegotiate} = State) -> handle_trusted_certs_db(State), notify_senders(SendQueue), notify_renegotiater(Renegotiate), Transport:close(Socket). %%-------------------------------------------------------------------- %%% Internal functions %%-------------------------------------------------------------------- do_server_hello(Type, #hello_extensions{next_protocol_negotiation = NextProtocols} = ServerHelloExt, #state{negotiated_version = Version, session = #session{session_id = SessId}, connection_states = ConnectionStates0} = State0, Connection) when is_atom(Type) -> ServerHello = ssl_handshake:server_hello(SessId, Version, ConnectionStates0, ServerHelloExt), State = server_hello(ServerHello, State0#state{expecting_next_protocol_negotiation = NextProtocols =/= undefined}, Connection), case Type of new -> new_server_hello(ServerHello, State, Connection); resumed -> resumed_server_hello(State, Connection) end. new_server_hello(#server_hello{cipher_suite = CipherSuite, compression_method = Compression, session_id = SessionId}, #state{session = Session0, negotiated_version = Version} = State0, Connection) -> try server_certify_and_key_exchange(State0, Connection) of #state{} = State1 -> State2 = server_hello_done(State1, Connection), Session = Session0#session{session_id = SessionId, cipher_suite = CipherSuite, compression_method = Compression}, {Record, State} = Connection:next_record(State2#state{session = Session}), Connection:next_state(hello, certify, Record, State) catch #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, hello, State0) end. resumed_server_hello(#state{session = Session, connection_states = ConnectionStates0, negotiated_version = Version} = State0, Connection) -> case ssl_handshake:master_secret(record_cb(Connection), Version, Session, ConnectionStates0, server) of {_, ConnectionStates1} -> State1 = State0#state{connection_states = ConnectionStates1, session = Session}, State2 = finalize_handshake(State1, abbreviated, Connection), {Record, State} = Connection:next_record(State2), Connection:next_state(hello, abbreviated, Record, State); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, hello, State0) end. server_hello(ServerHello, State0, Connection) -> CipherSuite = ServerHello#server_hello.cipher_suite, {KeyAlgorithm, _, _, _} = ssl_cipher:suite_definition(CipherSuite), State = Connection:send_handshake(ServerHello, State0), State#state{key_algorithm = KeyAlgorithm}. server_hello_done(State, Connection) -> HelloDone = ssl_handshake:server_hello_done(), Connection:send_handshake(HelloDone, State). handle_peer_cert(Role, PeerCert, PublicKeyInfo, #state{session = #session{cipher_suite = CipherSuite} = Session} = State0, Connection) -> State1 = State0#state{session = Session#session{peer_certificate = PeerCert}, public_key_info = PublicKeyInfo}, {KeyAlg,_,_,_} = ssl_cipher:suite_definition(CipherSuite), State2 = handle_peer_cert_key(Role, PeerCert, PublicKeyInfo, KeyAlg, State1), {Record, State} = Connection:next_record(State2), Connection:next_state(certify, certify, Record, State). handle_peer_cert_key(client, _, {?'id-ecPublicKey', #'ECPoint'{point = _ECPoint} = PublicKey, PublicKeyParams}, KeyAlg, State) when KeyAlg == ecdh_rsa; KeyAlg == ecdh_ecdsa -> ECDHKey = public_key:generate_key(PublicKeyParams), PremasterSecret = ssl_handshake:premaster_secret(PublicKey, ECDHKey), master_secret(PremasterSecret, State#state{diffie_hellman_keys = ECDHKey}); %% We do currently not support cipher suites that use fixed DH. %% If we want to implement that the following clause can be used %% to extract DH parameters form cert. %% handle_peer_cert_key(client, _PeerCert, {?dhpublicnumber, PublicKey, PublicKeyParams}, %% {_,SignAlg}, %% #state{diffie_hellman_keys = {_, MyPrivatKey}} = State) when %% SignAlg == dh_rsa; %% SignAlg == dh_dss -> %% dh_master_secret(PublicKeyParams, PublicKey, MyPrivatKey, State); handle_peer_cert_key(_, _, _, _, State) -> State. certify_client(#state{client_certificate_requested = true, role = client, cert_db = CertDbHandle, cert_db_ref = CertDbRef, session = #session{own_certificate = OwnCert}} = State, Connection) -> Certificate = ssl_handshake:certificate(OwnCert, CertDbHandle, CertDbRef, client), Connection:send_handshake(Certificate, State); certify_client(#state{client_certificate_requested = false} = State, _) -> State. verify_client_cert(#state{client_certificate_requested = true, role = client, negotiated_version = Version, private_key = PrivateKey, session = #session{master_secret = MasterSecret, own_certificate = OwnCert}, cert_hashsign_algorithm = HashSign, tls_handshake_history = Handshake0} = State, Connection) -> case ssl_handshake:client_certificate_verify(OwnCert, MasterSecret, Version, HashSign, PrivateKey, Handshake0) of #certificate_verify{} = Verified -> Connection:send_handshake(Verified, State); ignore -> State; #alert{} = Alert -> throw(Alert) end; verify_client_cert(#state{client_certificate_requested = false} = State, _) -> State. client_certify_and_key_exchange(#state{negotiated_version = Version} = State0, Connection) -> try do_client_certify_and_key_exchange(State0, Connection) of State1 = #state{} -> State2 = finalize_handshake(State1, certify, Connection), State3 = State2#state{ %% Reinitialize client_certificate_requested = false}, {Record, State} = Connection:next_record(State3), Connection:next_state(certify, cipher, Record, State) catch throw:#alert{} = Alert -> Connection:handle_own_alert(Alert, Version, certify, State0) end. do_client_certify_and_key_exchange(State0, Connection) -> State1 = certify_client(State0, Connection), State2 = key_exchange(State1, Connection), verify_client_cert(State2, Connection). server_certify_and_key_exchange(State0, Connection) -> State1 = certify_server(State0, Connection), State2 = key_exchange(State1, Connection), request_client_cert(State2, Connection). certify_client_key_exchange(#encrypted_premaster_secret{premaster_secret= EncPMS}, #state{private_key = Key} = State, Connection) -> PremasterSecret = ssl_handshake:premaster_secret(EncPMS, Key), calculate_master_secret(PremasterSecret, State, Connection, certify, cipher); certify_client_key_exchange(#client_diffie_hellman_public{dh_public = ClientPublicDhKey}, #state{diffie_hellman_params = #'DHParameter'{} = Params, diffie_hellman_keys = {_, ServerDhPrivateKey}} = State, Connection) -> PremasterSecret = ssl_handshake:premaster_secret(ClientPublicDhKey, ServerDhPrivateKey, Params), calculate_master_secret(PremasterSecret, State, Connection, certify, cipher); certify_client_key_exchange(#client_ec_diffie_hellman_public{dh_public = ClientPublicEcDhPoint}, #state{diffie_hellman_keys = ECDHKey} = State, Connection) -> PremasterSecret = ssl_handshake:premaster_secret(#'ECPoint'{point = ClientPublicEcDhPoint}, ECDHKey), calculate_master_secret(PremasterSecret, State, Connection, certify, cipher); certify_client_key_exchange(#client_psk_identity{} = ClientKey, #state{ssl_options = #ssl_options{user_lookup_fun = PSKLookup}} = State0, Connection) -> PremasterSecret = ssl_handshake:premaster_secret(ClientKey, PSKLookup), calculate_master_secret(PremasterSecret, State0, Connection, certify, cipher); certify_client_key_exchange(#client_dhe_psk_identity{} = ClientKey, #state{diffie_hellman_params = #'DHParameter'{} = Params, diffie_hellman_keys = {_, ServerDhPrivateKey}, ssl_options = #ssl_options{user_lookup_fun = PSKLookup}} = State0, Connection) -> PremasterSecret = ssl_handshake:premaster_secret(ClientKey, ServerDhPrivateKey, Params, PSKLookup), calculate_master_secret(PremasterSecret, State0, Connection, certify, cipher); certify_client_key_exchange(#client_rsa_psk_identity{} = ClientKey, #state{private_key = Key, ssl_options = #ssl_options{user_lookup_fun = PSKLookup}} = State0, Connection) -> PremasterSecret = ssl_handshake:premaster_secret(ClientKey, Key, PSKLookup), calculate_master_secret(PremasterSecret, State0, Connection, certify, cipher); certify_client_key_exchange(#client_srp_public{} = ClientKey, #state{srp_params = Params, srp_keys = Key } = State0, Connection) -> PremasterSecret = ssl_handshake:premaster_secret(ClientKey, Key, Params), calculate_master_secret(PremasterSecret, State0, Connection, certify, cipher). certify_server(#state{key_algorithm = Algo} = State, _) when Algo == dh_anon; Algo == ecdh_anon; Algo == psk; Algo == dhe_psk; Algo == srp_anon -> State; certify_server(#state{cert_db = CertDbHandle, cert_db_ref = CertDbRef, session = #session{own_certificate = OwnCert}} = State, Connection) -> case ssl_handshake:certificate(OwnCert, CertDbHandle, CertDbRef, server) of Cert = #certificate{} -> Connection:send_handshake(Cert, State); Alert = #alert{} -> throw(Alert) end. key_exchange(#state{role = server, key_algorithm = rsa} = State,_) -> State; key_exchange(#state{role = server, key_algorithm = Algo, hashsign_algorithm = HashSignAlgo, diffie_hellman_params = #'DHParameter'{} = Params, private_key = PrivateKey, connection_states = ConnectionStates0, negotiated_version = Version } = State0, Connection) when Algo == dhe_dss; Algo == dhe_rsa; Algo == dh_anon -> DHKeys = public_key:generate_key(Params), ConnectionState = ssl_record:pending_connection_state(ConnectionStates0, read), SecParams = ConnectionState#connection_state.security_parameters, #security_parameters{client_random = ClientRandom, server_random = ServerRandom} = SecParams, Msg = ssl_handshake:key_exchange(server, Version, {dh, DHKeys, Params, HashSignAlgo, ClientRandom, ServerRandom, PrivateKey}), State = Connection:send_handshake(Msg, State0), State#state{diffie_hellman_keys = DHKeys}; key_exchange(#state{role = server, private_key = Key, key_algorithm = Algo} = State, _) when Algo == ecdh_ecdsa; Algo == ecdh_rsa -> State#state{diffie_hellman_keys = Key}; key_exchange(#state{role = server, key_algorithm = Algo, hashsign_algorithm = HashSignAlgo, private_key = PrivateKey, connection_states = ConnectionStates0, negotiated_version = Version } = State0, Connection) when Algo == ecdhe_ecdsa; Algo == ecdhe_rsa; Algo == ecdh_anon -> ECDHKeys = public_key:generate_key(select_curve(State0)), ConnectionState = ssl_record:pending_connection_state(ConnectionStates0, read), SecParams = ConnectionState#connection_state.security_parameters, #security_parameters{client_random = ClientRandom, server_random = ServerRandom} = SecParams, Msg = ssl_handshake:key_exchange(server, Version, {ecdh, ECDHKeys, HashSignAlgo, ClientRandom, ServerRandom, PrivateKey}), State = Connection:send_handshake(Msg, State0), State#state{diffie_hellman_keys = ECDHKeys}; key_exchange(#state{role = server, key_algorithm = psk, ssl_options = #ssl_options{psk_identity = undefined}} = State, _) -> State; key_exchange(#state{role = server, key_algorithm = psk, ssl_options = #ssl_options{psk_identity = PskIdentityHint}, hashsign_algorithm = HashSignAlgo, private_key = PrivateKey, connection_states = ConnectionStates0, negotiated_version = Version } = State0, Connection) -> ConnectionState = ssl_record:pending_connection_state(ConnectionStates0, read), SecParams = ConnectionState#connection_state.security_parameters, #security_parameters{client_random = ClientRandom, server_random = ServerRandom} = SecParams, Msg = ssl_handshake:key_exchange(server, Version, {psk, PskIdentityHint, HashSignAlgo, ClientRandom, ServerRandom, PrivateKey}), Connection:send_handshake(Msg, State0); key_exchange(#state{role = server, key_algorithm = dhe_psk, ssl_options = #ssl_options{psk_identity = PskIdentityHint}, hashsign_algorithm = HashSignAlgo, diffie_hellman_params = #'DHParameter'{} = Params, private_key = PrivateKey, connection_states = ConnectionStates0, negotiated_version = Version } = State0, Connection) -> DHKeys = public_key:generate_key(Params), ConnectionState = ssl_record:pending_connection_state(ConnectionStates0, read), SecParams = ConnectionState#connection_state.security_parameters, #security_parameters{client_random = ClientRandom, server_random = ServerRandom} = SecParams, Msg = ssl_handshake:key_exchange(server, Version, {dhe_psk, PskIdentityHint, DHKeys, Params, HashSignAlgo, ClientRandom, ServerRandom, PrivateKey}), State = Connection:send_handshake(Msg, State0), State#state{diffie_hellman_keys = DHKeys}; key_exchange(#state{role = server, key_algorithm = rsa_psk, ssl_options = #ssl_options{psk_identity = undefined}} = State, _) -> State; key_exchange(#state{role = server, key_algorithm = rsa_psk, ssl_options = #ssl_options{psk_identity = PskIdentityHint}, hashsign_algorithm = HashSignAlgo, private_key = PrivateKey, connection_states = ConnectionStates0, negotiated_version = Version } = State0, Connection) -> ConnectionState = ssl_record:pending_connection_state(ConnectionStates0, read), SecParams = ConnectionState#connection_state.security_parameters, #security_parameters{client_random = ClientRandom, server_random = ServerRandom} = SecParams, Msg = ssl_handshake:key_exchange(server, Version, {psk, PskIdentityHint, HashSignAlgo, ClientRandom, ServerRandom, PrivateKey}), Connection:send_handshake(Msg, State0); key_exchange(#state{role = server, key_algorithm = Algo, ssl_options = #ssl_options{user_lookup_fun = LookupFun}, hashsign_algorithm = HashSignAlgo, session = #session{srp_username = Username}, private_key = PrivateKey, connection_states = ConnectionStates0, negotiated_version = Version } = State0, Connection) when Algo == srp_dss; Algo == srp_rsa; Algo == srp_anon -> SrpParams = handle_srp_identity(Username, LookupFun), Keys = case generate_srp_server_keys(SrpParams, 0) of Alert = #alert{} -> throw(Alert); Keys0 = {_,_} -> Keys0 end, ConnectionState = ssl_record:pending_connection_state(ConnectionStates0, read), SecParams = ConnectionState#connection_state.security_parameters, #security_parameters{client_random = ClientRandom, server_random = ServerRandom} = SecParams, Msg = ssl_handshake:key_exchange(server, Version, {srp, Keys, SrpParams, HashSignAlgo, ClientRandom, ServerRandom, PrivateKey}), State = Connection:send_handshake(Msg, State0), State#state{srp_params = SrpParams, srp_keys = Keys}; key_exchange(#state{role = client, key_algorithm = rsa, public_key_info = PublicKeyInfo, negotiated_version = Version, premaster_secret = PremasterSecret} = State0, Connection) -> Msg = rsa_key_exchange(Version, PremasterSecret, PublicKeyInfo), Connection:send_handshake(Msg, State0); key_exchange(#state{role = client, key_algorithm = Algorithm, negotiated_version = Version, diffie_hellman_keys = {DhPubKey, _} } = State0, Connection) when Algorithm == dhe_dss; Algorithm == dhe_rsa; Algorithm == dh_anon -> Msg = ssl_handshake:key_exchange(client, Version, {dh, DhPubKey}), Connection:send_handshake(Msg, State0); key_exchange(#state{role = client, key_algorithm = Algorithm, negotiated_version = Version, diffie_hellman_keys = Keys} = State0, Connection) when Algorithm == ecdhe_ecdsa; Algorithm == ecdhe_rsa; Algorithm == ecdh_ecdsa; Algorithm == ecdh_rsa; Algorithm == ecdh_anon -> Msg = ssl_handshake:key_exchange(client, Version, {ecdh, Keys}), Connection:send_handshake(Msg, State0); key_exchange(#state{role = client, ssl_options = SslOpts, key_algorithm = psk, negotiated_version = Version} = State0, Connection) -> Msg = ssl_handshake:key_exchange(client, Version, {psk, SslOpts#ssl_options.psk_identity}), Connection:send_handshake(Msg, State0); key_exchange(#state{role = client, ssl_options = SslOpts, key_algorithm = dhe_psk, negotiated_version = Version, diffie_hellman_keys = {DhPubKey, _}} = State0, Connection) -> Msg = ssl_handshake:key_exchange(client, Version, {dhe_psk, SslOpts#ssl_options.psk_identity, DhPubKey}), Connection:send_handshake(Msg, State0); key_exchange(#state{role = client, ssl_options = SslOpts, key_algorithm = rsa_psk, public_key_info = PublicKeyInfo, negotiated_version = Version, premaster_secret = PremasterSecret} = State0, Connection) -> Msg = rsa_psk_key_exchange(Version, SslOpts#ssl_options.psk_identity, PremasterSecret, PublicKeyInfo), Connection:send_handshake(Msg, State0); key_exchange(#state{role = client, key_algorithm = Algorithm, negotiated_version = Version, srp_keys = {ClientPubKey, _}} = State0, Connection) when Algorithm == srp_dss; Algorithm == srp_rsa; Algorithm == srp_anon -> Msg = ssl_handshake:key_exchange(client, Version, {srp, ClientPubKey}), Connection:send_handshake(Msg, State0). rsa_key_exchange(Version, PremasterSecret, PublicKeyInfo = {Algorithm, _, _}) when Algorithm == ?rsaEncryption; Algorithm == ?md2WithRSAEncryption; Algorithm == ?md5WithRSAEncryption; Algorithm == ?sha1WithRSAEncryption; Algorithm == ?sha224WithRSAEncryption; Algorithm == ?sha256WithRSAEncryption; Algorithm == ?sha384WithRSAEncryption; Algorithm == ?sha512WithRSAEncryption -> ssl_handshake:key_exchange(client, Version, {premaster_secret, PremasterSecret, PublicKeyInfo}); rsa_key_exchange(_, _, _) -> throw (?ALERT_REC(?FATAL,?HANDSHAKE_FAILURE)). rsa_psk_key_exchange(Version, PskIdentity, PremasterSecret, PublicKeyInfo = {Algorithm, _, _}) when Algorithm == ?rsaEncryption; Algorithm == ?md2WithRSAEncryption; Algorithm == ?md5WithRSAEncryption; Algorithm == ?sha1WithRSAEncryption; Algorithm == ?sha224WithRSAEncryption; Algorithm == ?sha256WithRSAEncryption; Algorithm == ?sha384WithRSAEncryption; Algorithm == ?sha512WithRSAEncryption -> ssl_handshake:key_exchange(client, Version, {psk_premaster_secret, PskIdentity, PremasterSecret, PublicKeyInfo}); rsa_psk_key_exchange(_, _, _, _) -> throw (?ALERT_REC(?FATAL,?HANDSHAKE_FAILURE)). request_client_cert(#state{ssl_options = #ssl_options{verify = verify_peer}, connection_states = ConnectionStates0, cert_db = CertDbHandle, cert_db_ref = CertDbRef, negotiated_version = Version} = State0, Connection) -> #connection_state{security_parameters = #security_parameters{cipher_suite = CipherSuite}} = ssl_record:pending_connection_state(ConnectionStates0, read), Msg = ssl_handshake:certificate_request(CipherSuite, CertDbHandle, CertDbRef, Version), State = Connection:send_handshake(Msg, State0), State#state{client_certificate_requested = true}; request_client_cert(#state{ssl_options = #ssl_options{verify = verify_none}} = State, _) -> State. calculate_master_secret(PremasterSecret, #state{negotiated_version = Version, connection_states = ConnectionStates0, session = Session0} = State0, Connection, Current, Next) -> case ssl_handshake:master_secret(record_cb(Connection), Version, PremasterSecret, ConnectionStates0, server) of {MasterSecret, ConnectionStates} -> Session = Session0#session{master_secret = MasterSecret}, State1 = State0#state{connection_states = ConnectionStates, session = Session}, {Record, State} = Connection:next_record(State1), Connection:next_state(Current, Next, Record, State); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, certify, State0) end. finalize_handshake(State0, StateName, Connection) -> #state{connection_states = ConnectionStates0} = State1 = cipher_protocol(State0, Connection), ConnectionStates = ssl_record:activate_pending_connection_state(ConnectionStates0, write), State2 = State1#state{connection_states = ConnectionStates}, State = next_protocol(State2, Connection), finished(State, StateName, Connection). next_protocol(#state{role = server} = State, _) -> State; next_protocol(#state{next_protocol = undefined} = State, _) -> State; next_protocol(#state{expecting_next_protocol_negotiation = false} = State, _) -> State; next_protocol(#state{next_protocol = NextProtocol} = State0, Connection) -> NextProtocolMessage = ssl_handshake:next_protocol(NextProtocol), Connection:send_handshake(NextProtocolMessage, State0). cipher_protocol(State, Connection) -> Connection:send_change_cipher(#change_cipher_spec{}, State). finished(#state{role = Role, negotiated_version = Version, session = Session, connection_states = ConnectionStates0, tls_handshake_history = Handshake0} = State0, StateName, Connection) -> MasterSecret = Session#session.master_secret, Finished = ssl_handshake:finished(Version, Role, get_current_prf(ConnectionStates0, write), MasterSecret, Handshake0), ConnectionStates = save_verify_data(Role, Finished, ConnectionStates0, StateName), Connection:send_handshake(Finished, State0#state{connection_states = ConnectionStates}). save_verify_data(client, #finished{verify_data = Data}, ConnectionStates, certify) -> ssl_record:set_client_verify_data(current_write, Data, ConnectionStates); save_verify_data(server, #finished{verify_data = Data}, ConnectionStates, cipher) -> ssl_record:set_server_verify_data(current_both, Data, ConnectionStates); save_verify_data(client, #finished{verify_data = Data}, ConnectionStates, abbreviated) -> ssl_record:set_client_verify_data(current_both, Data, ConnectionStates); save_verify_data(server, #finished{verify_data = Data}, ConnectionStates, abbreviated) -> ssl_record:set_server_verify_data(current_write, Data, ConnectionStates). calculate_secret(#server_dh_params{dh_p = Prime, dh_g = Base, dh_y = ServerPublicDhKey} = Params, State, Connection) -> Keys = {_, PrivateDhKey} = crypto:generate_key(dh, [Prime, Base]), PremasterSecret = ssl_handshake:premaster_secret(ServerPublicDhKey, PrivateDhKey, Params), calculate_master_secret(PremasterSecret, State#state{diffie_hellman_keys = Keys}, Connection, certify, certify); calculate_secret(#server_ecdh_params{curve = ECCurve, public = ECServerPubKey}, State, Connection) -> ECDHKeys = public_key:generate_key(ECCurve), PremasterSecret = ssl_handshake:premaster_secret(#'ECPoint'{point = ECServerPubKey}, ECDHKeys), calculate_master_secret(PremasterSecret, State#state{diffie_hellman_keys = ECDHKeys}, Connection, certify, certify); calculate_secret(#server_psk_params{ hint = IdentityHint}, State0, Connection) -> %% store for later use {Record, State} = Connection:next_record(State0#state{psk_identity = IdentityHint}), Connection:next_state(certify, certify, Record, State); calculate_secret(#server_dhe_psk_params{ dh_params = #server_dh_params{dh_p = Prime, dh_g = Base}} = ServerKey, #state{ssl_options = #ssl_options{user_lookup_fun = PSKLookup}} = State, Connection) -> Keys = {_, PrivateDhKey} = crypto:generate_key(dh, [Prime, Base]), PremasterSecret = ssl_handshake:premaster_secret(ServerKey, PrivateDhKey, PSKLookup), calculate_master_secret(PremasterSecret, State#state{diffie_hellman_keys = Keys}, Connection, certify, certify); calculate_secret(#server_srp_params{srp_n = Prime, srp_g = Generator} = ServerKey, #state{ssl_options = #ssl_options{srp_identity = SRPId}} = State, Connection) -> Keys = generate_srp_client_keys(Generator, Prime, 0), PremasterSecret = ssl_handshake:premaster_secret(ServerKey, Keys, SRPId), calculate_master_secret(PremasterSecret, State#state{srp_keys = Keys}, Connection, certify, certify). master_secret(#alert{} = Alert, _) -> Alert; master_secret(PremasterSecret, #state{session = Session, negotiated_version = Version, role = Role, connection_states = ConnectionStates0} = State) -> case ssl_handshake:master_secret(tls_record, Version, PremasterSecret, ConnectionStates0, Role) of {MasterSecret, ConnectionStates} -> State#state{ session = Session#session{master_secret = MasterSecret}, connection_states = ConnectionStates}; #alert{} = Alert -> Alert end. generate_srp_server_keys(_SrpParams, 10) -> ?ALERT_REC(?FATAL, ?ILLEGAL_PARAMETER); generate_srp_server_keys(SrpParams = #srp_user{generator = Generator, prime = Prime, verifier = Verifier}, N) -> case crypto:generate_key(srp, {host, [Verifier, Generator, Prime, '6a']}) of error -> generate_srp_server_keys(SrpParams, N+1); Keys -> Keys end. generate_srp_client_keys(_Generator, _Prime, 10) -> ?ALERT_REC(?FATAL, ?ILLEGAL_PARAMETER); generate_srp_client_keys(Generator, Prime, N) -> case crypto:generate_key(srp, {user, [Generator, Prime, '6a']}) of error -> generate_srp_client_keys(Generator, Prime, N+1); Keys -> Keys end. handle_srp_identity(Username, {Fun, UserState}) -> case Fun(srp, Username, UserState) of {ok, {SRPParams, Salt, DerivedKey}} when is_atom(SRPParams), is_binary(Salt), is_binary(DerivedKey) -> {Generator, Prime} = ssl_srp_primes:get_srp_params(SRPParams), Verifier = crypto:mod_pow(Generator, DerivedKey, Prime), #srp_user{generator = Generator, prime = Prime, salt = Salt, verifier = Verifier}; #alert{} = Alert -> throw(Alert); _ -> throw(?ALERT_REC(?FATAL, ?ILLEGAL_PARAMETER)) end. cipher_role(client, Data, Session, #state{connection_states = ConnectionStates0} = State, Connection) -> ConnectionStates = ssl_record:set_server_verify_data(current_both, Data, ConnectionStates0), Connection:next_state_connection(cipher, ack_connection( State#state{session = Session, connection_states = ConnectionStates})); cipher_role(server, Data, Session, #state{connection_states = ConnectionStates0} = State0, Connection) -> ConnectionStates1 = ssl_record:set_client_verify_data(current_read, Data, ConnectionStates0), State = finalize_handshake(State0#state{connection_states = ConnectionStates1, session = Session}, cipher, Connection), Connection:next_state_connection(cipher, ack_connection(State#state{session = Session})). negotiated_hashsign(undefined, Algo, Version) -> default_hashsign(Version, Algo); negotiated_hashsign(HashSign = {_, _}, _, _) -> HashSign. %% RFC 5246, Sect. 7.4.1.4.1. Signature Algorithms %% If the client does not send the signature_algorithms extension, the %% server MUST do the following: %% %% - If the negotiated key exchange algorithm is one of (RSA, DHE_RSA, %% DH_RSA, RSA_PSK, ECDH_RSA, ECDHE_RSA), behave as if client had %% sent the value {sha1,rsa}. %% %% - If the negotiated key exchange algorithm is one of (DHE_DSS, %% DH_DSS), behave as if the client had sent the value {sha1,dsa}. %% %% - If the negotiated key exchange algorithm is one of (ECDH_ECDSA, %% ECDHE_ECDSA), behave as if the client had sent value {sha1,ecdsa}. default_hashsign(_Version = {Major, Minor}, KeyExchange) when Major >= 3 andalso Minor >= 3 andalso (KeyExchange == rsa orelse KeyExchange == dhe_rsa orelse KeyExchange == dh_rsa orelse KeyExchange == ecdhe_rsa orelse KeyExchange == ecdh_rsa orelse KeyExchange == srp_rsa) -> {sha, rsa}; default_hashsign(_Version, KeyExchange) when KeyExchange == rsa; KeyExchange == dhe_rsa; KeyExchange == dh_rsa; KeyExchange == ecdhe_rsa; KeyExchange == ecdh_rsa; KeyExchange == srp_rsa -> {md5sha, rsa}; default_hashsign(_Version, KeyExchange) when KeyExchange == ecdhe_ecdsa; KeyExchange == ecdh_ecdsa -> {sha, ecdsa}; default_hashsign(_Version, KeyExchange) when KeyExchange == dhe_dss; KeyExchange == dh_dss; KeyExchange == srp_dss -> {sha, dsa}; default_hashsign(_Version, KeyExchange) when KeyExchange == dh_anon; KeyExchange == ecdh_anon; KeyExchange == psk; KeyExchange == dhe_psk; KeyExchange == rsa_psk; KeyExchange == srp_anon -> {null, anon}. select_curve(#state{client_ecc = {[Curve|_], _}}) -> {namedCurve, Curve}; select_curve(_) -> {namedCurve, ?secp256k1}. is_anonymous(Algo) when Algo == dh_anon; Algo == ecdh_anon; Algo == psk; Algo == dhe_psk; Algo == rsa_psk; Algo == srp_anon -> true; is_anonymous(_) -> false. get_current_prf(CStates, Direction) -> CS = ssl_record:current_connection_state(CStates, Direction), CS#connection_state.security_parameters#security_parameters.prf_algorithm. get_pending_prf(CStates, Direction) -> CS = ssl_record:pending_connection_state(CStates, Direction), CS#connection_state.security_parameters#security_parameters.prf_algorithm. opposite_role(client) -> server; opposite_role(server) -> client. record_cb(tls_connection) -> tls_record; record_cb(dtls_connection) -> dtls_record. sync_send_all_state_event(FsmPid, Event) -> try gen_fsm:sync_send_all_state_event(FsmPid, Event, infinity) catch exit:{noproc, _} -> {error, closed}; exit:{normal, _} -> {error, closed}; exit:{{shutdown, _},_} -> {error, closed} end. get_socket_opts(_,_,[], _, Acc) -> {ok, Acc}; get_socket_opts(Transport, Socket, [mode | Tags], SockOpts, Acc) -> get_socket_opts(Transport, Socket, Tags, SockOpts, [{mode, SockOpts#socket_options.mode} | Acc]); get_socket_opts(Transport, Socket, [packet | Tags], SockOpts, Acc) -> case SockOpts#socket_options.packet of {Type, headers} -> get_socket_opts(Transport, Socket, Tags, SockOpts, [{packet, Type} | Acc]); Type -> get_socket_opts(Transport, Socket, Tags, SockOpts, [{packet, Type} | Acc]) end; get_socket_opts(Transport, Socket, [header | Tags], SockOpts, Acc) -> get_socket_opts(Transport, Socket, Tags, SockOpts, [{header, SockOpts#socket_options.header} | Acc]); get_socket_opts(Transport, Socket, [active | Tags], SockOpts, Acc) -> get_socket_opts(Transport, Socket, Tags, SockOpts, [{active, SockOpts#socket_options.active} | Acc]); get_socket_opts(Transport, Socket, [Tag | Tags], SockOpts, Acc) -> try ssl_socket:getopts(Transport, Socket, [Tag]) of {ok, [Opt]} -> get_socket_opts(Transport, Socket, Tags, SockOpts, [Opt | Acc]); {error, Error} -> {error, {options, {socket_options, Tag, Error}}} catch %% So that inet behavior does not crash our process _:Error -> {error, {options, {socket_options, Tag, Error}}} end; get_socket_opts(_, _,Opts, _,_) -> {error, {options, {socket_options, Opts, function_clause}}}. set_socket_opts(_,_, [], SockOpts, []) -> {ok, SockOpts}; set_socket_opts(Transport, Socket, [], SockOpts, Other) -> %% Set non emulated options try ssl_socket:setopts(Transport, Socket, Other) of ok -> {ok, SockOpts}; {error, InetError} -> {{error, {options, {socket_options, Other, InetError}}}, SockOpts} catch _:Error -> %% So that inet behavior does not crash our process {{error, {options, {socket_options, Other, Error}}}, SockOpts} end; set_socket_opts(Transport,Socket, [{mode, Mode}| Opts], SockOpts, Other) when Mode == list; Mode == binary -> set_socket_opts(Transport, Socket, Opts, SockOpts#socket_options{mode = Mode}, Other); set_socket_opts(_, _, [{mode, _} = Opt| _], SockOpts, _) -> {{error, {options, {socket_options, Opt}}}, SockOpts}; set_socket_opts(Transport,Socket, [{packet, Packet}| Opts], SockOpts, Other) when Packet == raw; Packet == 0; Packet == 1; Packet == 2; Packet == 4; Packet == asn1; Packet == cdr; Packet == sunrm; Packet == fcgi; Packet == tpkt; Packet == line; Packet == http; Packet == httph; Packet == http_bin; Packet == httph_bin -> set_socket_opts(Transport, Socket, Opts, SockOpts#socket_options{packet = Packet}, Other); set_socket_opts(_, _, [{packet, _} = Opt| _], SockOpts, _) -> {{error, {options, {socket_options, Opt}}}, SockOpts}; set_socket_opts(Transport, Socket, [{header, Header}| Opts], SockOpts, Other) when is_integer(Header) -> set_socket_opts(Transport, Socket, Opts, SockOpts#socket_options{header = Header}, Other); set_socket_opts(_, _, [{header, _} = Opt| _], SockOpts, _) -> {{error,{options, {socket_options, Opt}}}, SockOpts}; set_socket_opts(Transport, Socket, [{active, Active}| Opts], SockOpts, Other) when Active == once; Active == true; Active == false -> set_socket_opts(Transport, Socket, Opts, SockOpts#socket_options{active = Active}, Other); set_socket_opts(_, _, [{active, _} = Opt| _], SockOpts, _) -> {{error, {options, {socket_options, Opt}} }, SockOpts}; set_socket_opts(Transport, Socket, [Opt | Opts], SockOpts, Other) -> set_socket_opts(Transport, Socket, Opts, SockOpts, [Opt | Other]). start_or_recv_cancel_timer(infinity, _RecvFrom) -> undefined; start_or_recv_cancel_timer(Timeout, RecvFrom) -> erlang:send_after(Timeout, self(), {cancel_start_or_recv, RecvFrom}). get_timeout(#state{ssl_options=#ssl_options{hibernate_after = undefined}}) -> infinity; get_timeout(#state{ssl_options=#ssl_options{hibernate_after = HibernateAfter}}) -> HibernateAfter. terminate_alert(Reason, Version, ConnectionStates) when Reason == normal; Reason == user_close -> {BinAlert, _} = ssl_alert:encode(?ALERT_REC(?WARNING, ?CLOSE_NOTIFY), Version, ConnectionStates), BinAlert; terminate_alert({shutdown, _}, Version, ConnectionStates) -> {BinAlert, _} = ssl_alert:encode(?ALERT_REC(?WARNING, ?CLOSE_NOTIFY), Version, ConnectionStates), BinAlert; terminate_alert(_, Version, ConnectionStates) -> {BinAlert, _} = ssl_alert:encode(?ALERT_REC(?FATAL, ?INTERNAL_ERROR), Version, ConnectionStates), BinAlert. handle_unrecv_data(StateName, #state{socket = Socket, transport_cb = Transport, protocol_cb = Connection} = State) -> ssl_socket:setopts(Transport, Socket, [{active, false}]), case Transport:recv(Socket, 0, 0) of {error, closed} -> ok; {ok, Data} -> Connection:handle_close_alert(Data, StateName, State) end. handle_trusted_certs_db(#state{ssl_options = #ssl_options{cacertfile = <<>>}}) -> %% No trusted certs specified ok; handle_trusted_certs_db(#state{cert_db_ref = Ref, cert_db = CertDb, ssl_options = #ssl_options{cacertfile = undefined}}) -> %% Certs provided as DER directly can not be shared %% with other connections and it is safe to delete them when the connection ends. ssl_pkix_db:remove_trusted_certs(Ref, CertDb); handle_trusted_certs_db(#state{file_ref_db = undefined}) -> %% Something went wrong early (typically cacertfile does not exist) so there is nothing to handle ok; handle_trusted_certs_db(#state{cert_db_ref = Ref, file_ref_db = RefDb, ssl_options = #ssl_options{cacertfile = File}}) -> case ssl_pkix_db:ref_count(Ref, RefDb, -1) of 0 -> ssl_manager:clean_cert_db(Ref, File); _ -> ok end. notify_senders(SendQueue) -> lists:foreach(fun({From, _}) -> gen_fsm:reply(From, {error, closed}) end, queue:to_list(SendQueue)). notify_renegotiater({true, From}) when not is_atom(From) -> gen_fsm:reply(From, {error, closed}); notify_renegotiater(_) -> ok. ack_connection(#state{renegotiation = {true, Initiater}} = State) when Initiater == internal; Initiater == peer -> State#state{renegotiation = undefined}; ack_connection(#state{renegotiation = {true, From}} = State) -> gen_fsm:reply(From, ok), State#state{renegotiation = undefined}; ack_connection(#state{renegotiation = {false, first}, start_or_recv_from = StartFrom, timer = Timer} = State) when StartFrom =/= undefined -> gen_fsm:reply(StartFrom, connected), cancel_timer(Timer), State#state{renegotiation = undefined, start_or_recv_from = undefined, timer = undefined}; ack_connection(State) -> State. cancel_timer(undefined) -> ok; cancel_timer(Timer) -> erlang:cancel_timer(Timer), ok. register_session(client, Host, Port, #session{is_resumable = new} = Session0) -> Session = Session0#session{is_resumable = true}, ssl_manager:register_session(Host, Port, Session), Session; register_session(server, _, Port, #session{is_resumable = new} = Session0) -> Session = Session0#session{is_resumable = true}, ssl_manager:register_session(Port, Session), Session; register_session(_, _, _, Session) -> Session. %% Already registered handle_new_session(NewId, CipherSuite, Compression, #state{session = Session0, protocol_cb = Connection} = State0) -> Session = Session0#session{session_id = NewId, cipher_suite = CipherSuite, compression_method = Compression}, {Record, State} = Connection:next_record(State0#state{session = Session}), Connection:next_state(hello, certify, Record, State). handle_resumed_session(SessId, #state{connection_states = ConnectionStates0, negotiated_version = Version, host = Host, port = Port, protocol_cb = Connection, session_cache = Cache, session_cache_cb = CacheCb} = State0) -> Session = CacheCb:lookup(Cache, {{Host, Port}, SessId}), case ssl_handshake:master_secret(tls_record, Version, Session, ConnectionStates0, client) of {_, ConnectionStates} -> {Record, State} = Connection:next_record(State0#state{ connection_states = ConnectionStates, session = Session}), Connection:next_state(hello, abbreviated, Record, State); #alert{} = Alert -> Connection:handle_own_alert(Alert, Version, hello, State0) end. make_premaster_secret({MajVer, MinVer}, rsa) -> Rand = ssl:random_bytes(?NUM_OF_PREMASTERSECRET_BYTES-2), <>; make_premaster_secret(_, _) -> undefined.