%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2007-2013. 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: Help functions for handling the SSL-Record protocol
%%
%%----------------------------------------------------------------------
-module(ssl_record).
-include("ssl_record.hrl").
-include("ssl_internal.hrl").
-include("ssl_alert.hrl").
-include("ssl_handshake.hrl").
-include("ssl_cipher.hrl").
%% Connection state handling
-export([init_connection_states/1,
current_connection_state/2, pending_connection_state/2,
update_security_params/3,
set_mac_secret/4,
set_master_secret/2,
activate_pending_connection_state/2,
set_pending_cipher_state/4,
set_renegotiation_flag/2,
set_client_verify_data/3,
set_server_verify_data/3]).
%% Handling of incoming data
-export([get_tls_records/2]).
%% Encoding records
-export([encode_handshake/3, encode_alert_record/3,
encode_change_cipher_spec/2, encode_data/3]).
%% Decoding
-export([decode_cipher_text/2]).
%% Misc.
-export([protocol_version/1, lowest_protocol_version/2,
highest_protocol_version/1, supported_protocol_versions/0,
is_acceptable_version/1, is_acceptable_version/2]).
-export([compressions/0]).
-compile(inline).
-define(INITIAL_BYTES, 5).
%%====================================================================
%% Internal application API
%%====================================================================
%%--------------------------------------------------------------------
-spec init_connection_states(client | server) -> #connection_states{}.
%%
%% Description: Creates a connection_states record with appropriate
%% values for the initial SSL connection setup.
%%--------------------------------------------------------------------
init_connection_states(Role) ->
ConnectionEnd = record_protocol_role(Role),
Current = initial_connection_state(ConnectionEnd),
Pending = empty_connection_state(ConnectionEnd),
#connection_states{current_read = Current,
pending_read = Pending,
current_write = Current,
pending_write = Pending
}.
%%--------------------------------------------------------------------
-spec current_connection_state(#connection_states{}, read | write) ->
#connection_state{}.
%%
%% Description: Returns the instance of the connection_state record
%% that is currently defined as the current conection state.
%%--------------------------------------------------------------------
current_connection_state(#connection_states{current_read = Current},
read) ->
Current;
current_connection_state(#connection_states{current_write = Current},
write) ->
Current.
%%--------------------------------------------------------------------
-spec pending_connection_state(#connection_states{}, read | write) ->
#connection_state{}.
%%
%% Description: Returns the instance of the connection_state record
%% that is currently defined as the pending conection state.
%%--------------------------------------------------------------------
pending_connection_state(#connection_states{pending_read = Pending},
read) ->
Pending;
pending_connection_state(#connection_states{pending_write = Pending},
write) ->
Pending.
%%--------------------------------------------------------------------
-spec update_security_params(#security_parameters{}, #security_parameters{},
#connection_states{}) -> #connection_states{}.
%%
%% Description: Creates a new instance of the connection_states record
%% where the pending states gets its security parameters updated.
%%--------------------------------------------------------------------
update_security_params(ReadParams, WriteParams, States =
#connection_states{pending_read = Read,
pending_write = Write}) ->
States#connection_states{pending_read =
Read#connection_state{security_parameters =
ReadParams},
pending_write =
Write#connection_state{security_parameters =
WriteParams}
}.
%%--------------------------------------------------------------------
-spec set_mac_secret(binary(), binary(), client | server,
#connection_states{}) -> #connection_states{}.
%%
%% Description: update the mac_secret field in pending connection states
%%--------------------------------------------------------------------
set_mac_secret(ClientWriteMacSecret, ServerWriteMacSecret, client, States) ->
set_mac_secret(ServerWriteMacSecret, ClientWriteMacSecret, States);
set_mac_secret(ClientWriteMacSecret, ServerWriteMacSecret, server, States) ->
set_mac_secret(ClientWriteMacSecret, ServerWriteMacSecret, States).
set_mac_secret(ReadMacSecret, WriteMacSecret,
States = #connection_states{pending_read = Read,
pending_write = Write}) ->
States#connection_states{
pending_read = Read#connection_state{mac_secret = ReadMacSecret},
pending_write = Write#connection_state{mac_secret = WriteMacSecret}
}.
%%--------------------------------------------------------------------
-spec set_master_secret(binary(), #connection_states{}) -> #connection_states{}.
%%
%% Description: Set master_secret in pending connection states
%%--------------------------------------------------------------------
set_master_secret(MasterSecret,
States = #connection_states{pending_read = Read,
pending_write = Write}) ->
ReadSecPar = Read#connection_state.security_parameters,
Read1 = Read#connection_state{
security_parameters = ReadSecPar#security_parameters{
master_secret = MasterSecret}},
WriteSecPar = Write#connection_state.security_parameters,
Write1 = Write#connection_state{
security_parameters = WriteSecPar#security_parameters{
master_secret = MasterSecret}},
States#connection_states{pending_read = Read1, pending_write = Write1}.
%%--------------------------------------------------------------------
-spec set_renegotiation_flag(boolean(), #connection_states{}) -> #connection_states{}.
%%
%% Description: Set secure_renegotiation in pending connection states
%%--------------------------------------------------------------------
set_renegotiation_flag(Flag, #connection_states{
current_read = CurrentRead0,
current_write = CurrentWrite0,
pending_read = PendingRead0,
pending_write = PendingWrite0}
= ConnectionStates) ->
CurrentRead = CurrentRead0#connection_state{secure_renegotiation = Flag},
CurrentWrite = CurrentWrite0#connection_state{secure_renegotiation = Flag},
PendingRead = PendingRead0#connection_state{secure_renegotiation = Flag},
PendingWrite = PendingWrite0#connection_state{secure_renegotiation = Flag},
ConnectionStates#connection_states{current_read = CurrentRead,
current_write = CurrentWrite,
pending_read = PendingRead,
pending_write = PendingWrite}.
%%--------------------------------------------------------------------
-spec set_client_verify_data(current_read | current_write | current_both,
binary(), #connection_states{})->
#connection_states{}.
%%
%% Description: Set verify data in connection states.
%%--------------------------------------------------------------------
set_client_verify_data(current_read, Data,
#connection_states{current_read = CurrentRead0,
pending_write = PendingWrite0}
= ConnectionStates) ->
CurrentRead = CurrentRead0#connection_state{client_verify_data = Data},
PendingWrite = PendingWrite0#connection_state{client_verify_data = Data},
ConnectionStates#connection_states{current_read = CurrentRead,
pending_write = PendingWrite};
set_client_verify_data(current_write, Data,
#connection_states{pending_read = PendingRead0,
current_write = CurrentWrite0}
= ConnectionStates) ->
PendingRead = PendingRead0#connection_state{client_verify_data = Data},
CurrentWrite = CurrentWrite0#connection_state{client_verify_data = Data},
ConnectionStates#connection_states{pending_read = PendingRead,
current_write = CurrentWrite};
set_client_verify_data(current_both, Data,
#connection_states{current_read = CurrentRead0,
current_write = CurrentWrite0}
= ConnectionStates) ->
CurrentRead = CurrentRead0#connection_state{client_verify_data = Data},
CurrentWrite = CurrentWrite0#connection_state{client_verify_data = Data},
ConnectionStates#connection_states{current_read = CurrentRead,
current_write = CurrentWrite}.
%%--------------------------------------------------------------------
-spec set_server_verify_data(current_read | current_write | current_both,
binary(), #connection_states{})->
#connection_states{}.
%%
%% Description: Set verify data in pending connection states.
%%--------------------------------------------------------------------
set_server_verify_data(current_write, Data,
#connection_states{pending_read = PendingRead0,
current_write = CurrentWrite0}
= ConnectionStates) ->
PendingRead = PendingRead0#connection_state{server_verify_data = Data},
CurrentWrite = CurrentWrite0#connection_state{server_verify_data = Data},
ConnectionStates#connection_states{pending_read = PendingRead,
current_write = CurrentWrite};
set_server_verify_data(current_read, Data,
#connection_states{current_read = CurrentRead0,
pending_write = PendingWrite0}
= ConnectionStates) ->
CurrentRead = CurrentRead0#connection_state{server_verify_data = Data},
PendingWrite = PendingWrite0#connection_state{server_verify_data = Data},
ConnectionStates#connection_states{current_read = CurrentRead,
pending_write = PendingWrite};
set_server_verify_data(current_both, Data,
#connection_states{current_read = CurrentRead0,
current_write = CurrentWrite0}
= ConnectionStates) ->
CurrentRead = CurrentRead0#connection_state{server_verify_data = Data},
CurrentWrite = CurrentWrite0#connection_state{server_verify_data = Data},
ConnectionStates#connection_states{current_read = CurrentRead,
current_write = CurrentWrite}.
%%--------------------------------------------------------------------
-spec activate_pending_connection_state(#connection_states{}, read | write) ->
#connection_states{}.
%%
%% Description: Creates a new instance of the connection_states record
%% where the pending state of <Type> has been activated.
%%--------------------------------------------------------------------
activate_pending_connection_state(States =
#connection_states{pending_read = Pending},
read) ->
NewCurrent = Pending#connection_state{sequence_number = 0},
SecParams = Pending#connection_state.security_parameters,
ConnectionEnd = SecParams#security_parameters.connection_end,
EmptyPending = empty_connection_state(ConnectionEnd),
SecureRenegotation = NewCurrent#connection_state.secure_renegotiation,
NewPending = EmptyPending#connection_state{secure_renegotiation = SecureRenegotation},
States#connection_states{current_read = NewCurrent,
pending_read = NewPending
};
activate_pending_connection_state(States =
#connection_states{pending_write = Pending},
write) ->
NewCurrent = Pending#connection_state{sequence_number = 0},
SecParams = Pending#connection_state.security_parameters,
ConnectionEnd = SecParams#security_parameters.connection_end,
EmptyPending = empty_connection_state(ConnectionEnd),
SecureRenegotation = NewCurrent#connection_state.secure_renegotiation,
NewPending = EmptyPending#connection_state{secure_renegotiation = SecureRenegotation},
States#connection_states{current_write = NewCurrent,
pending_write = NewPending
}.
%%--------------------------------------------------------------------
-spec set_pending_cipher_state(#connection_states{}, #cipher_state{},
#cipher_state{}, client | server) ->
#connection_states{}.
%%
%% Description: Set the cipher state in the specified pending connection state.
%%--------------------------------------------------------------------
set_pending_cipher_state(#connection_states{pending_read = Read,
pending_write = Write} = States,
ClientState, ServerState, server) ->
States#connection_states{
pending_read = Read#connection_state{cipher_state = ClientState},
pending_write = Write#connection_state{cipher_state = ServerState}};
set_pending_cipher_state(#connection_states{pending_read = Read,
pending_write = Write} = States,
ClientState, ServerState, client) ->
States#connection_states{
pending_read = Read#connection_state{cipher_state = ServerState},
pending_write = Write#connection_state{cipher_state = ClientState}}.
%%--------------------------------------------------------------------
-spec get_tls_records(binary(), binary()) -> {[binary()], binary()} | #alert{}.
%%
%% Description: Given old buffer and new data from TCP, packs up a records
%% and returns it as a list of tls_compressed binaries also returns leftover
%% data
%%--------------------------------------------------------------------
get_tls_records(Data, <<>>) ->
get_tls_records_aux(Data, []);
get_tls_records(Data, Buffer) ->
get_tls_records_aux(list_to_binary([Buffer, Data]), []).
get_tls_records_aux(<<?BYTE(?APPLICATION_DATA),?BYTE(MajVer),?BYTE(MinVer),
?UINT16(Length), Data:Length/binary, Rest/binary>>,
Acc) ->
get_tls_records_aux(Rest, [#ssl_tls{type = ?APPLICATION_DATA,
version = {MajVer, MinVer},
fragment = Data} | Acc]);
get_tls_records_aux(<<?BYTE(?HANDSHAKE),?BYTE(MajVer),?BYTE(MinVer),
?UINT16(Length),
Data:Length/binary, Rest/binary>>, Acc) ->
get_tls_records_aux(Rest, [#ssl_tls{type = ?HANDSHAKE,
version = {MajVer, MinVer},
fragment = Data} | Acc]);
get_tls_records_aux(<<?BYTE(?ALERT),?BYTE(MajVer),?BYTE(MinVer),
?UINT16(Length), Data:Length/binary,
Rest/binary>>, Acc) ->
get_tls_records_aux(Rest, [#ssl_tls{type = ?ALERT,
version = {MajVer, MinVer},
fragment = Data} | Acc]);
get_tls_records_aux(<<?BYTE(?CHANGE_CIPHER_SPEC),?BYTE(MajVer),?BYTE(MinVer),
?UINT16(Length), Data:Length/binary, Rest/binary>>,
Acc) ->
get_tls_records_aux(Rest, [#ssl_tls{type = ?CHANGE_CIPHER_SPEC,
version = {MajVer, MinVer},
fragment = Data} | Acc]);
%% Matches an ssl v2 client hello message.
%% 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.
get_tls_records_aux(<<1:1, Length0:15, Data0:Length0/binary, Rest/binary>>,
Acc) ->
case Data0 of
<<?BYTE(?CLIENT_HELLO), ?BYTE(MajVer), ?BYTE(MinVer), _/binary>> ->
Length = Length0-1,
<<?BYTE(_), Data1:Length/binary>> = Data0,
Data = <<?BYTE(?CLIENT_HELLO), ?UINT24(Length), Data1/binary>>,
get_tls_records_aux(Rest, [#ssl_tls{type = ?HANDSHAKE,
version = {MajVer, MinVer},
fragment = Data} | Acc]);
_ ->
?ALERT_REC(?FATAL, ?HANDSHAKE_FAILURE)
end;
get_tls_records_aux(<<0:1, _CT:7, ?BYTE(_MajVer), ?BYTE(_MinVer),
?UINT16(Length), _/binary>>,
_Acc) when Length > ?MAX_CIPHER_TEXT_LENGTH ->
?ALERT_REC(?FATAL, ?RECORD_OVERFLOW);
get_tls_records_aux(<<1:1, Length0:15, _/binary>>,_Acc)
when Length0 > ?MAX_CIPHER_TEXT_LENGTH ->
?ALERT_REC(?FATAL, ?RECORD_OVERFLOW);
get_tls_records_aux(Data, Acc) ->
case size(Data) =< ?MAX_CIPHER_TEXT_LENGTH + ?INITIAL_BYTES of
true ->
{lists:reverse(Acc), Data};
false ->
?ALERT_REC(?FATAL, ?UNEXPECTED_MESSAGE)
end.
%%--------------------------------------------------------------------
-spec protocol_version(tls_atom_version() | tls_version()) ->
tls_version() | tls_atom_version().
%%
%% Description: Creates a protocol version record from a version atom
%% or vice versa.
%%--------------------------------------------------------------------
protocol_version('tlsv1.2') ->
{3, 3};
protocol_version('tlsv1.1') ->
{3, 2};
protocol_version(tlsv1) ->
{3, 1};
protocol_version(sslv3) ->
{3, 0};
protocol_version(sslv2) -> %% Backwards compatibility
{2, 0};
protocol_version({3, 3}) ->
'tlsv1.2';
protocol_version({3, 2}) ->
'tlsv1.1';
protocol_version({3, 1}) ->
tlsv1;
protocol_version({3, 0}) ->
sslv3.
%%--------------------------------------------------------------------
-spec lowest_protocol_version(tls_version(), tls_version()) -> tls_version().
%%
%% Description: Lowes protocol version of two given versions
%%--------------------------------------------------------------------
lowest_protocol_version(Version = {M, N}, {M, O}) when N < O ->
Version;
lowest_protocol_version({M, _},
Version = {M, _}) ->
Version;
lowest_protocol_version(Version = {M,_},
{N, _}) when M < N ->
Version;
lowest_protocol_version(_,Version) ->
Version.
%%--------------------------------------------------------------------
-spec highest_protocol_version([tls_version()]) -> tls_version().
%%
%% Description: Highest protocol version present in a list
%%--------------------------------------------------------------------
highest_protocol_version([]) ->
highest_protocol_version();
highest_protocol_version(Versions) ->
[Ver | Vers] = Versions,
highest_protocol_version(Ver, Vers).
highest_protocol_version(Version, []) ->
Version;
highest_protocol_version(Version = {N, M}, [{N, O} | Rest]) when M > O ->
highest_protocol_version(Version, Rest);
highest_protocol_version({M, _}, [Version = {M, _} | Rest]) ->
highest_protocol_version(Version, Rest);
highest_protocol_version(Version = {M,_}, [{N,_} | Rest]) when M > N ->
highest_protocol_version(Version, Rest);
highest_protocol_version(_, [Version | Rest]) ->
highest_protocol_version(Version, Rest).
%%--------------------------------------------------------------------
-spec supported_protocol_versions() -> [tls_version()].
%%
%% Description: Protocol versions supported
%%--------------------------------------------------------------------
supported_protocol_versions() ->
Fun = fun(Version) ->
protocol_version(Version)
end,
case application:get_env(ssl, protocol_version) of
undefined ->
lists:map(Fun, supported_protocol_versions([]));
{ok, []} ->
lists:map(Fun, supported_protocol_versions([]));
{ok, Vsns} when is_list(Vsns) ->
Versions = lists:filter(fun is_acceptable_version/1, lists:map(Fun, Vsns)),
supported_protocol_versions(Versions);
{ok, Vsn} ->
Versions = lists:filter(fun is_acceptable_version/1, [Fun(Vsn)]),
supported_protocol_versions(Versions)
end.
supported_protocol_versions([]) ->
Vsns = case sufficient_tlsv1_2_crypto_support() of
true ->
?ALL_SUPPORTED_VERSIONS;
false ->
?MIN_SUPPORTED_VERSIONS
end,
application:set_env(ssl, protocol_version, Vsns),
Vsns;
supported_protocol_versions([_|_] = Vsns) ->
Vsns.
%%--------------------------------------------------------------------
-spec is_acceptable_version(tls_version()) -> boolean().
-spec is_acceptable_version(tls_version(), Supported :: [tls_version()]) -> boolean().
%%
%% Description: ssl version 2 is not acceptable security risks are too big.
%%
%%--------------------------------------------------------------------
is_acceptable_version({N,_})
when N >= ?LOWEST_MAJOR_SUPPORTED_VERSION ->
true;
is_acceptable_version(_) ->
false.
is_acceptable_version({N,_} = Version, Versions)
when N >= ?LOWEST_MAJOR_SUPPORTED_VERSION ->
lists:member(Version, Versions);
is_acceptable_version(_,_) ->
false.
%%--------------------------------------------------------------------
-spec compressions() -> [binary()].
%%
%% Description: return a list of compressions supported (currently none)
%%--------------------------------------------------------------------
compressions() ->
[?byte(?NULL)].
%%--------------------------------------------------------------------
-spec decode_cipher_text(#ssl_tls{}, #connection_states{}) ->
{#ssl_tls{}, #connection_states{}}| #alert{}.
%%
%% Description: Decode cipher text
%%--------------------------------------------------------------------
decode_cipher_text(CipherText, ConnnectionStates0) ->
ReadState0 = ConnnectionStates0#connection_states.current_read,
#connection_state{compression_state = CompressionS0,
security_parameters = SecParams} = ReadState0,
CompressAlg = SecParams#security_parameters.compression_algorithm,
case decipher(CipherText, ReadState0) of
{Compressed, ReadState1} ->
{Plain, CompressionS1} = uncompress(CompressAlg,
Compressed, CompressionS0),
ConnnectionStates = ConnnectionStates0#connection_states{
current_read = ReadState1#connection_state{
compression_state = CompressionS1}},
{Plain, ConnnectionStates};
#alert{} = Alert ->
Alert
end.
%%--------------------------------------------------------------------
-spec encode_data(binary(), tls_version(), #connection_states{}) ->
{iolist(), #connection_states{}}.
%%
%% Description: Encodes data to send on the ssl-socket.
%%--------------------------------------------------------------------
encode_data(Frag, Version,
#connection_states{current_write = #connection_state{
security_parameters =
#security_parameters{bulk_cipher_algorithm = BCA}}} =
ConnectionStates) ->
Data = split_bin(Frag, ?MAX_PLAIN_TEXT_LENGTH, Version, BCA),
encode_iolist(?APPLICATION_DATA, Data, Version, ConnectionStates).
%%--------------------------------------------------------------------
-spec encode_handshake(iolist(), tls_version(), #connection_states{}) ->
{iolist(), #connection_states{}}.
%%
%% Description: Encodes a handshake message to send on the ssl-socket.
%%--------------------------------------------------------------------
encode_handshake(Frag, Version, ConnectionStates) ->
encode_plain_text(?HANDSHAKE, Version, Frag, ConnectionStates).
%%--------------------------------------------------------------------
-spec encode_alert_record(#alert{}, tls_version(), #connection_states{}) ->
{iolist(), #connection_states{}}.
%%
%% Description: Encodes an alert message to send on the ssl-socket.
%%--------------------------------------------------------------------
encode_alert_record(#alert{level = Level, description = Description},
Version, ConnectionStates) ->
encode_plain_text(?ALERT, Version, <<?BYTE(Level), ?BYTE(Description)>>,
ConnectionStates).
%%--------------------------------------------------------------------
-spec encode_change_cipher_spec(tls_version(), #connection_states{}) ->
{iolist(), #connection_states{}}.
%%
%% Description: Encodes a change_cipher_spec-message to send on the ssl socket.
%%--------------------------------------------------------------------
encode_change_cipher_spec(Version, ConnectionStates) ->
encode_plain_text(?CHANGE_CIPHER_SPEC, Version, <<1:8>>, ConnectionStates).
%%--------------------------------------------------------------------
%%% Internal functions
%%--------------------------------------------------------------------
encode_iolist(Type, Data, Version, ConnectionStates0) ->
{ConnectionStates, EncodedMsg} =
lists:foldl(fun(Text, {CS0, Encoded}) ->
{Enc, CS1} = encode_plain_text(Type, Version, Text, CS0),
{CS1, [Enc | Encoded]}
end, {ConnectionStates0, []}, Data),
{lists:reverse(EncodedMsg), ConnectionStates}.
highest_protocol_version() ->
highest_protocol_version(supported_protocol_versions()).
initial_connection_state(ConnectionEnd) ->
#connection_state{security_parameters =
initial_security_params(ConnectionEnd),
sequence_number = 0
}.
initial_security_params(ConnectionEnd) ->
SecParams = #security_parameters{connection_end = ConnectionEnd,
compression_algorithm = ?NULL},
ssl_cipher:security_parameters(highest_protocol_version(), ?TLS_NULL_WITH_NULL_NULL,
SecParams).
empty_connection_state(ConnectionEnd) ->
SecParams = empty_security_params(ConnectionEnd),
#connection_state{security_parameters = SecParams}.
empty_security_params(ConnectionEnd = ?CLIENT) ->
#security_parameters{connection_end = ConnectionEnd,
client_random = random()};
empty_security_params(ConnectionEnd = ?SERVER) ->
#security_parameters{connection_end = ConnectionEnd,
server_random = random()}.
random() ->
Secs_since_1970 = calendar:datetime_to_gregorian_seconds(
calendar:universal_time()) - 62167219200,
Random_28_bytes = crypto:rand_bytes(28),
<<?UINT32(Secs_since_1970), Random_28_bytes/binary>>.
record_protocol_role(client) ->
?CLIENT;
record_protocol_role(server) ->
?SERVER.
%% 1/n-1 splitting countermeasure Rizzo/Duong-Beast, RC4 chiphers are not vulnerable to this attack.
split_bin(<<FirstByte:8, Rest/binary>>, ChunkSize, Version, BCA) when BCA =/= ?RC4 andalso ({3, 1} == Version orelse
{3, 0} == Version) ->
do_split_bin(Rest, ChunkSize, [[FirstByte]]);
split_bin(Bin, ChunkSize, _, _) ->
do_split_bin(Bin, ChunkSize, []).
do_split_bin(<<>>, _, Acc) ->
lists:reverse(Acc);
do_split_bin(Bin, ChunkSize, Acc) ->
case Bin of
<<Chunk:ChunkSize/binary, Rest/binary>> ->
do_split_bin(Rest, ChunkSize, [Chunk | Acc]);
_ ->
lists:reverse(Acc, [Bin])
end.
encode_plain_text(Type, Version, Data, ConnectionStates) ->
#connection_states{current_write=#connection_state{
compression_state=CompS0,
security_parameters=
#security_parameters{compression_algorithm=CompAlg}
}=CS0} = ConnectionStates,
{Comp, CompS1} = compress(CompAlg, Data, CompS0),
CS1 = CS0#connection_state{compression_state = CompS1},
{CipherText, CS2} = cipher(Type, Version, Comp, CS1),
CTBin = encode_tls_cipher_text(Type, Version, CipherText),
{CTBin, ConnectionStates#connection_states{current_write = CS2}}.
encode_tls_cipher_text(Type, {MajVer, MinVer}, Fragment) ->
Length = erlang:iolist_size(Fragment),
[<<?BYTE(Type), ?BYTE(MajVer), ?BYTE(MinVer), ?UINT16(Length)>>, Fragment].
cipher(Type, Version, Fragment, CS0) ->
Length = erlang:iolist_size(Fragment),
{MacHash, CS1=#connection_state{cipher_state = CipherS0,
security_parameters=
#security_parameters{bulk_cipher_algorithm =
BCA}
}} =
hash_and_bump_seqno(CS0, Type, Version, Length, Fragment),
{Ciphered, CipherS1} = ssl_cipher:cipher(BCA, CipherS0, MacHash, Fragment, Version),
CS2 = CS1#connection_state{cipher_state=CipherS1},
{Ciphered, CS2}.
decipher(TLS=#ssl_tls{type=Type, version=Version, fragment=Fragment}, CS0) ->
SP = CS0#connection_state.security_parameters,
BCA = SP#security_parameters.bulk_cipher_algorithm,
HashSz = SP#security_parameters.hash_size,
CipherS0 = CS0#connection_state.cipher_state,
case ssl_cipher:decipher(BCA, HashSz, CipherS0, Fragment, Version) of
{T, Mac, CipherS1} ->
CS1 = CS0#connection_state{cipher_state = CipherS1},
TLength = size(T),
{MacHash, CS2} = hash_and_bump_seqno(CS1, Type, Version, TLength, T),
case is_correct_mac(Mac, MacHash) of
true ->
{TLS#ssl_tls{fragment = T}, CS2};
false ->
?ALERT_REC(?FATAL, ?BAD_RECORD_MAC)
end;
#alert{} = Alert ->
Alert
end.
uncompress(?NULL, Data = #ssl_tls{type = _Type,
version = _Version,
fragment = _Fragment}, CS) ->
{Data, CS}.
compress(?NULL, Data, CS) ->
{Data, CS}.
hash_and_bump_seqno(#connection_state{sequence_number = SeqNo,
mac_secret = MacSecret,
security_parameters =
SecPars} = CS0,
Type, Version, Length, Fragment) ->
Hash = mac_hash(Version,
SecPars#security_parameters.mac_algorithm,
MacSecret, SeqNo, Type,
Length, Fragment),
{Hash, CS0#connection_state{sequence_number = SeqNo+1}}.
is_correct_mac(Mac, Mac) ->
true;
is_correct_mac(_M,_H) ->
false.
mac_hash({_,_}, ?NULL, _MacSecret, _SeqNo, _Type,
_Length, _Fragment) ->
<<>>;
mac_hash({3, 0}, MacAlg, MacSecret, SeqNo, Type, Length, Fragment) ->
ssl_ssl3:mac_hash(MacAlg, MacSecret, SeqNo, Type, Length, Fragment);
mac_hash({3, N} = Version, MacAlg, MacSecret, SeqNo, Type, Length, Fragment)
when N =:= 1; N =:= 2; N =:= 3 ->
ssl_tls1:mac_hash(MacAlg, MacSecret, SeqNo, Type, Version,
Length, Fragment).
sufficient_tlsv1_2_crypto_support() ->
Data = "Sampl",
Data2 = "e #1",
Key = <<0,1,2,3,16,17,18,19,32,33,34,35,48,49,50,51,4,5,6,7,20,21,22,23,36,37,38,39,
52,53,54,55,8,9,10,11,24,25,26,27,40,41,42,43,56,57,58,59>>,
try
crypto:sha256_mac(Key, lists:flatten([Data, Data2])),
true
catch _:_ -> false
end.