%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2008-2017. All Rights Reserved.
%%
%% Licensed under the Apache License, Version 2.0 (the "License");
%% you may not use this file except in compliance with the License.
%% You may obtain a copy of the License at
%%
%% http://www.apache.org/licenses/LICENSE-2.0
%%
%% Unless required by applicable law or agreed to in writing, software
%% distributed under the License is distributed on an "AS IS" BASIS,
%% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
%% See the License for the specific language governing permissions and
%% limitations under the License.
%%
%% %CopyrightEnd%
%%
%%
-module(ssl_test_lib).
-include_lib("common_test/include/ct.hrl").
-include_lib("public_key/include/public_key.hrl").
%% Note: This directive should only be used in test suites.
-compile(export_all).
-record(sslsocket, { fd = nil, pid = nil}).
-define(SLEEP, 1000).
%% For now always run locally
run_where(_) ->
ClientNode = node(),
ServerNode = node(),
Host = rpc:call(ServerNode, net_adm, localhost, []),
{ClientNode, ServerNode, Host}.
run_where(_, ipv6) ->
ClientNode = node(),
ServerNode = node(),
Host = rpc:call(ServerNode, net_adm, localhost, []),
{ClientNode, ServerNode, Host}.
node_to_hostip(Node) ->
[_ , Host] = string:tokens(atom_to_list(Node), "@"),
{ok, Address} = inet:getaddr(Host, inet),
Address.
start_server(Args) ->
Result = spawn_link(?MODULE, run_server, [Args]),
receive
{listen, up} ->
Result
end.
run_server(Opts) ->
Node = proplists:get_value(node, Opts),
Port = proplists:get_value(port, Opts),
Options = proplists:get_value(options, Opts),
Pid = proplists:get_value(from, Opts),
Transport = proplists:get_value(transport, Opts, ssl),
ct:log("~p:~p~nssl:listen(~p, ~p)~n", [?MODULE,?LINE, Port, Options]),
{ok, ListenSocket} = rpc:call(Node, Transport, listen, [Port, Options]),
Pid ! {listen, up},
send_selected_port(Pid, Port, ListenSocket),
run_server(ListenSocket, Opts).
run_server(ListenSocket, Opts) ->
Accepters = proplists:get_value(accepters, Opts, 1),
run_server(ListenSocket, Opts, Accepters).
run_server(ListenSocket, Opts, 1) ->
do_run_server(ListenSocket, connect(ListenSocket, Opts), Opts);
run_server(ListenSocket, Opts, N) ->
Pid = proplists:get_value(from, Opts),
Server = spawn(?MODULE, run_server, [ListenSocket, Opts, 1]),
Pid ! {accepter, N, Server},
run_server(ListenSocket, Opts, N-1).
do_run_server(_, {error, timeout} = Result, Opts) ->
Pid = proplists:get_value(from, Opts),
Pid ! {self(), Result};
do_run_server(ListenSocket, AcceptSocket, Opts) ->
Node = proplists:get_value(node, Opts),
Pid = proplists:get_value(from, Opts),
Transport = proplists:get_value(transport, Opts, ssl),
{Module, Function, Args} = proplists:get_value(mfa, Opts),
ct:log("~p:~p~nServer: apply(~p,~p,~p)~n",
[?MODULE,?LINE, Module, Function, [AcceptSocket | Args]]),
case rpc:call(Node, Module, Function, [AcceptSocket | Args]) of
no_result_msg ->
ok;
Msg ->
ct:log("~p:~p~nServer Msg: ~p ~n", [?MODULE,?LINE, Msg]),
Pid ! {self(), Msg}
end,
receive
listen ->
run_server(ListenSocket, Opts);
{listen, MFA} ->
run_server(ListenSocket, [MFA | proplists:delete(mfa, Opts)]);
close ->
ct:log("~p:~p~nServer closing ~p ~n", [?MODULE,?LINE, self()]),
Result = rpc:call(Node, Transport, close, [AcceptSocket], 500),
Result1 = rpc:call(Node, Transport, close, [ListenSocket], 500),
ct:log("~p:~p~nResult ~p : ~p ~n", [?MODULE,?LINE, Result, Result1]);
{ssl_closed, _} ->
ok
end.
%%% To enable to test with s_client -reconnect
connect(#sslsocket{} = ListenSocket, Opts) ->
Node = proplists:get_value(node, Opts),
ReconnectTimes = proplists:get_value(reconnect_times, Opts, 0),
Timeout = proplists:get_value(timeout, Opts, infinity),
SslOpts = proplists:get_value(ssl_extra_opts, Opts, []),
AcceptSocket = connect(ListenSocket, Node, 1 + ReconnectTimes, dummy, Timeout, SslOpts),
case ReconnectTimes of
0 ->
AcceptSocket;
_ ->
remove_close_msg(ReconnectTimes),
AcceptSocket
end;
connect(ListenSocket, Opts) ->
Node = proplists:get_value(node, Opts),
ct:log("~p:~p~ngen_tcp:accept(~p)~n", [?MODULE,?LINE, ListenSocket]),
{ok, AcceptSocket} = rpc:call(Node, gen_tcp, accept,
[ListenSocket]),
AcceptSocket.
connect(_, _, 0, AcceptSocket, _, _) ->
AcceptSocket;
connect(ListenSocket, Node, N, _, Timeout, []) ->
ct:log("ssl:transport_accept(~p)~n", [ListenSocket]),
{ok, AcceptSocket} = rpc:call(Node, ssl, transport_accept,
[ListenSocket]),
ct:log("~p:~p~nssl:ssl_accept(~p, ~p)~n", [?MODULE,?LINE, AcceptSocket, Timeout]),
case rpc:call(Node, ssl, ssl_accept, [AcceptSocket, Timeout]) of
ok ->
connect(ListenSocket, Node, N-1, AcceptSocket, Timeout, []);
Result ->
ct:log("~p:~p~nssl:ssl_accept@~p ret ~p",[?MODULE,?LINE, Node,Result]),
Result
end;
connect(ListenSocket, Node, _, _, Timeout, Opts) ->
ct:log("ssl:transport_accept(~p)~n", [ListenSocket]),
{ok, AcceptSocket} = rpc:call(Node, ssl, transport_accept,
[ListenSocket]),
ct:log("ssl:ssl_accept(~p,~p, ~p)~n", [AcceptSocket, Opts, Timeout]),
rpc:call(Node, ssl, ssl_accept, [AcceptSocket, Opts, Timeout]),
AcceptSocket.
remove_close_msg(0) ->
ok;
remove_close_msg(ReconnectTimes) ->
receive
{ssl_closed, _} ->
remove_close_msg(ReconnectTimes -1)
end.
start_client(Args) ->
Result = spawn_link(?MODULE, run_client_init, [lists:delete(return_socket, Args)]),
receive
{connected, Socket} ->
case lists:member(return_socket, Args) of
true -> {Result, Socket};
false -> Result
end;
{connect_failed, Reason} ->
{connect_failed, Reason}
end.
run_client_init(Opts) ->
put(retries, 0),
run_client(Opts).
run_client(Opts) ->
Node = proplists:get_value(node, Opts),
Host = proplists:get_value(host, Opts),
Port = proplists:get_value(port, Opts),
Pid = proplists:get_value(from, Opts),
Transport = proplists:get_value(transport, Opts, ssl),
Options = proplists:get_value(options, Opts),
ct:log("~p:~p~n~p:connect(~p, ~p)@~p~n", [?MODULE,?LINE, Transport, Host, Port, Node]),
ct:log("SSLOpts: ~p", [Options]),
case rpc:call(Node, Transport, connect, [Host, Port, Options]) of
{ok, Socket} ->
Pid ! {connected, Socket},
ct:log("~p:~p~nClient: connected~n", [?MODULE,?LINE]),
%% In special cases we want to know the client port, it will
%% be indicated by sending {port, 0} in options list!
send_selected_port(Pid, proplists:get_value(port, Options), Socket),
{Module, Function, Args} = proplists:get_value(mfa, Opts),
ct:log("~p:~p~nClient: apply(~p,~p,~p)~n",
[?MODULE,?LINE, Module, Function, [Socket | Args]]),
case rpc:call(Node, Module, Function, [Socket | Args]) of
no_result_msg ->
ok;
Msg ->
ct:log("~p:~p~nClient Msg: ~p ~n", [?MODULE,?LINE, Msg]),
Pid ! {self(), Msg}
end,
receive
close ->
ct:log("~p:~p~nClient closing~n", [?MODULE,?LINE]),
rpc:call(Node, Transport, close, [Socket]);
{ssl_closed, Socket} ->
ok;
{gen_tcp, closed} ->
ok
end;
{error, econnrefused = Reason} ->
case get(retries) of
N when N < 5 ->
ct:log("~p:~p~neconnrefused retries=~p sleep ~p",[?MODULE,?LINE, N,?SLEEP]),
put(retries, N+1),
ct:sleep(?SLEEP),
run_client(Opts);
_ ->
ct:log("~p:~p~nClient faild several times: connection failed: ~p ~n", [?MODULE,?LINE, Reason]),
Pid ! {self(), {error, Reason}}
end;
{error, econnreset = Reason} ->
case get(retries) of
N when N < 5 ->
ct:log("~p:~p~neconnreset retries=~p sleep ~p",[?MODULE,?LINE, N,?SLEEP]),
put(retries, N+1),
ct:sleep(?SLEEP),
run_client(Opts);
_ ->
ct:log("~p:~p~nClient faild several times: connection failed: ~p ~n", [?MODULE,?LINE, Reason]),
Pid ! {self(), {error, Reason}}
end;
{error, Reason} ->
ct:log("~p:~p~nClient: connection failed: ~p ~n", [?MODULE,?LINE, Reason]),
Pid ! {connect_failed, Reason};
{badrpc,BadRPC} ->
ct:log("~p:~p~nBad rpc: ~p",[?MODULE,?LINE, BadRPC]),
Pid ! {connect_failed, {badrpc,BadRPC}}
end.
close(Pid) ->
ct:log("~p:~p~nClose ~p ~n", [?MODULE,?LINE, Pid]),
Monitor = erlang:monitor(process, Pid),
Pid ! close,
receive
{'DOWN', Monitor, process, Pid, Reason} ->
erlang:demonitor(Monitor),
ct:log("~p:~p~nPid: ~p down due to:~p ~n", [?MODULE,?LINE, Pid, Reason])
end.
close(Pid, Timeout) ->
ct:log("~p:~p~n Close ~p ~n", [?MODULE,?LINE, Pid]),
Monitor = erlang:monitor(process, Pid),
Pid ! close,
receive
{'DOWN', Monitor, process, Pid, Reason} ->
erlang:demonitor(Monitor),
ct:log("~p:~p~nPid: ~p down due to:~p ~n", [?MODULE,?LINE, Pid, Reason])
after
Timeout ->
exit(Pid, kill)
end.
check_result(Server, ServerMsg, Client, ClientMsg) ->
receive
{Server, ServerMsg} ->
check_result(Client, ClientMsg);
{Client, ClientMsg} ->
check_result(Server, ServerMsg);
{Port, {data,Debug}} when is_port(Port) ->
ct:log("~p:~p~n Openssl ~s~n",[?MODULE,?LINE, Debug]),
check_result(Server, ServerMsg, Client, ClientMsg);
{Port,closed} when is_port(Port) ->
ct:log("~p:~p~n Openssl port ~n",[?MODULE,?LINE]),
check_result(Server, ServerMsg, Client, ClientMsg);
Unexpected ->
Reason = {{expected, {Client, ClientMsg}},
{expected, {Server, ServerMsg}}, {got, Unexpected}},
ct:fail(Reason)
end.
check_result(Pid, Msg) ->
receive
{Pid, Msg} ->
ok;
{Port, {data,Debug}} when is_port(Port) ->
ct:log("~p:~p~n Openssl ~s~n",[?MODULE,?LINE, Debug]),
check_result(Pid,Msg);
{Port,closed} when is_port(Port)->
ct:log("~p:~p Openssl port closed ~n",[?MODULE,?LINE]),
check_result(Pid, Msg);
Unexpected ->
Reason = {{expected, {Pid, Msg}},
{got, Unexpected}},
ct:fail(Reason)
end.
wait_for_result(Server, ServerMsg, Client, ClientMsg) ->
receive
{Server, ServerMsg} ->
receive
{Client, ClientMsg} ->
ok
%% Unexpected ->
%% Unexpected
end;
{Client, ClientMsg} ->
receive
{Server, ServerMsg} ->
ok
%% Unexpected ->
%% Unexpected
end;
{Port, {data,Debug}} when is_port(Port) ->
ct:log("~p:~p~nopenssl ~s~n",[?MODULE,?LINE, Debug]),
wait_for_result(Server, ServerMsg, Client, ClientMsg)
%% Unexpected ->
%% Unexpected
end.
check_ok([]) ->
ok;
check_ok(Pids) ->
receive
{Pid, ok} ->
check_ok(lists:delete(Pid, Pids));
Other ->
ct:fail({expected, {"pid()", ok}, got, Other})
end.
wait_for_result(Pid, Msg) ->
receive
{Pid, Msg} ->
ok;
{Port, {data,Debug}} when is_port(Port) ->
ct:log("~p:~p~nopenssl ~s~n",[?MODULE,?LINE, Debug]),
wait_for_result(Pid,Msg)
%% Unexpected ->
%% Unexpected
end.
user_lookup(psk, _Identity, UserState) ->
{ok, UserState};
user_lookup(srp, Username, _UserState) ->
Salt = ssl_cipher:random_bytes(16),
UserPassHash = crypto:hash(sha, [Salt, crypto:hash(sha, [Username, <<$:>>, <<"secret">>])]),
{ok, {srp_1024, Salt, UserPassHash}}.
cert_options(Config) ->
ClientCaCertFile = filename:join([proplists:get_value(priv_dir, Config),
"client", "cacerts.pem"]),
ClientCertFile = filename:join([proplists:get_value(priv_dir, Config),
"client", "cert.pem"]),
ClientCertFileDigitalSignatureOnly = filename:join([proplists:get_value(priv_dir, Config),
"client", "digital_signature_only_cert.pem"]),
ServerCaCertFile = filename:join([proplists:get_value(priv_dir, Config),
"server", "cacerts.pem"]),
ServerCertFile = filename:join([proplists:get_value(priv_dir, Config),
"server", "cert.pem"]),
ServerKeyFile = filename:join([proplists:get_value(priv_dir, Config),
"server", "key.pem"]),
ClientKeyFile = filename:join([proplists:get_value(priv_dir, Config),
"client", "key.pem"]),
ServerKeyCertFile = filename:join([proplists:get_value(priv_dir, Config),
"server", "keycert.pem"]),
ClientKeyCertFile = filename:join([proplists:get_value(priv_dir, Config),
"client", "keycert.pem"]),
BadCaCertFile = filename:join([proplists:get_value(priv_dir, Config),
"badcacert.pem"]),
BadCertFile = filename:join([proplists:get_value(priv_dir, Config),
"badcert.pem"]),
BadKeyFile = filename:join([proplists:get_value(priv_dir, Config),
"badkey.pem"]),
PskSharedSecret = <<1,2,3,4,5,6,7,8,9,10,11,12,13,14,15>>,
[{client_opts, [{cacertfile, ClientCaCertFile},
{certfile, ClientCertFile},
{keyfile, ClientKeyFile}]},
{client_verification_opts, [{cacertfile, ServerCaCertFile},
{certfile, ClientCertFile},
{keyfile, ClientKeyFile},
{ssl_imp, new}]},
{client_verification_opts_digital_signature_only, [{cacertfile, ServerCaCertFile},
{certfile, ClientCertFileDigitalSignatureOnly},
{keyfile, ClientKeyFile},
{ssl_imp, new}]},
{server_opts, [{ssl_imp, new},{reuseaddr, true}, {cacertfile, ServerCaCertFile},
{certfile, ServerCertFile}, {keyfile, ServerKeyFile}]},
{client_psk, [{ssl_imp, new},
{psk_identity, "Test-User"},
{user_lookup_fun, {fun user_lookup/3, PskSharedSecret}}]},
{server_psk, [{ssl_imp, new},{reuseaddr, true},
{certfile, ServerCertFile}, {keyfile, ServerKeyFile},
{user_lookup_fun, {fun user_lookup/3, PskSharedSecret}}]},
{server_psk_hint, [{ssl_imp, new},{reuseaddr, true},
{certfile, ServerCertFile}, {keyfile, ServerKeyFile},
{psk_identity, "HINT"},
{user_lookup_fun, {fun user_lookup/3, PskSharedSecret}}]},
{server_psk_anon, [{ssl_imp, new},{reuseaddr, true},
{user_lookup_fun, {fun user_lookup/3, PskSharedSecret}}]},
{server_psk_anon_hint, [{ssl_imp, new},{reuseaddr, true},
{psk_identity, "HINT"},
{user_lookup_fun, {fun user_lookup/3, PskSharedSecret}}]},
{client_srp, [{ssl_imp, new},
{srp_identity, {"Test-User", "secret"}}]},
{server_srp, [{ssl_imp, new},{reuseaddr, true},
{certfile, ServerCertFile}, {keyfile, ServerKeyFile},
{user_lookup_fun, {fun user_lookup/3, undefined}},
{ciphers, srp_suites()}]},
{server_srp_anon, [{ssl_imp, new},{reuseaddr, true},
{user_lookup_fun, {fun user_lookup/3, undefined}},
{ciphers, srp_anon_suites()}]},
{server_verification_opts, [{ssl_imp, new},{reuseaddr, true},
{cacertfile, ClientCaCertFile},
{certfile, ServerCertFile}, {keyfile, ServerKeyFile}]},
{client_kc_opts, [{certfile, ClientKeyCertFile}, {ssl_imp, new}]},
{server_kc_opts, [{ssl_imp, new},{reuseaddr, true},
{certfile, ServerKeyCertFile}]},
{client_bad_ca, [{cacertfile, BadCaCertFile},
{certfile, ClientCertFile},
{keyfile, ClientKeyFile},
{ssl_imp, new}]},
{client_bad_cert, [{cacertfile, ClientCaCertFile},
{certfile, BadCertFile},
{keyfile, ClientKeyFile},
{ssl_imp, new}]},
{server_bad_ca, [{ssl_imp, new},{cacertfile, BadCaCertFile},
{certfile, ServerCertFile},
{keyfile, ServerKeyFile}]},
{server_bad_cert, [{ssl_imp, new},{cacertfile, ServerCaCertFile},
{certfile, BadCertFile}, {keyfile, ServerKeyFile}]},
{server_bad_key, [{ssl_imp, new},{cacertfile, ServerCaCertFile},
{certfile, ServerCertFile}, {keyfile, BadKeyFile}]}
| Config].
make_dsa_cert(Config) ->
CryptoSupport = crypto:supports(),
case proplists:get_bool(dss, proplists:get_value(public_keys, CryptoSupport)) of
true ->
ClientChain = proplists:get_value(client_chain, Config, default_cert_chain_conf()),
ServerChain = proplists:get_value(server_chain, Config, default_cert_chain_conf()),
CertChainConf = gen_conf(dsa, dsa, ClientChain, ServerChain),
ClientFileBase = filename:join([proplists:get_value(priv_dir, Config), "dsa"]),
ServerFileBase = filename:join([proplists:get_value(priv_dir, Config), "dsa"]),
GenCertData = public_key:pkix_test_data(CertChainConf),
[{server_config, ServerConf},
{client_config, ClientConf}] =
x509_test:gen_pem_config_files(GenCertData, ClientFileBase, ServerFileBase),
[{server_dsa_opts, ServerConf},
{server_dsa_verify_opts, [{verify, verify_peer} | ServerConf]},
{client_dsa_opts, ClientConf},
{server_srp_dsa, [{user_lookup_fun, {fun user_lookup/3, undefined}},
{ciphers, srp_dss_suites()} | ServerConf]},
{client_srp_dsa, [{srp_identity, {"Test-User", "secret"}}
| ClientConf]}
| Config];
false ->
Config
end.
make_rsa_cert_chains(UserConf, Config, Suffix) ->
ClientChain = proplists:get_value(client_chain, UserConf, default_cert_chain_conf()),
ServerChain = proplists:get_value(server_chain, UserConf, default_cert_chain_conf()),
CertChainConf = gen_conf(rsa, rsa, ClientChain, ServerChain),
ClientFileBase = filename:join([proplists:get_value(priv_dir, Config), "rsa" ++ Suffix]),
ServerFileBase = filename:join([proplists:get_value(priv_dir, Config), "rsa" ++ Suffix]),
GenCertData = public_key:pkix_test_data(CertChainConf),
[{server_config, ServerConf},
{client_config, ClientConf}] =
x509_test:gen_pem_config_files(GenCertData, ClientFileBase, ServerFileBase),
{[{verify, verify_peer} | ClientConf],
[{reuseaddr, true}, {verify, verify_peer} | ServerConf]
}.
make_ec_cert_chains(UserConf, ClientChainType, ServerChainType, Config) ->
ClientChain = proplists:get_value(client_chain, UserConf, default_cert_chain_conf()),
ServerChain = proplists:get_value(server_chain, UserConf, default_cert_chain_conf()),
CertChainConf = gen_conf(ClientChainType, ServerChainType, ClientChain, ServerChain),
ClientFileBase = filename:join([proplists:get_value(priv_dir, Config), atom_to_list(ClientChainType)]),
ServerFileBase = filename:join([proplists:get_value(priv_dir, Config), atom_to_list(ServerChainType)]),
GenCertData = public_key:pkix_test_data(CertChainConf),
[{server_config, ServerConf},
{client_config, ClientConf}] =
x509_test:gen_pem_config_files(GenCertData, ClientFileBase, ServerFileBase),
{[{verify, verify_peer} | ClientConf],
[{reuseaddr, true}, {verify, verify_peer} | ServerConf]
}.
default_cert_chain_conf() ->
%% Use only default options
[[],[],[]].
gen_conf(mix, mix, UserClient, UserServer) ->
ClientTag = conf_tag("client"),
ServerTag = conf_tag("server"),
DefaultClient = default_cert_chain_conf(),
DefaultServer = default_cert_chain_conf(),
ClientConf = merge_chain_spec(UserClient, DefaultClient, []),
ServerConf = merge_chain_spec(UserServer, DefaultServer, []),
new_format([{ClientTag, ClientConf}, {ServerTag, ServerConf}]);
gen_conf(ClientChainType, ServerChainType, UserClient, UserServer) ->
ClientTag = conf_tag("client"),
ServerTag = conf_tag("server"),
DefaultClient = chain_spec(client, ClientChainType),
DefaultServer = chain_spec(server, ServerChainType),
ClientConf = merge_chain_spec(UserClient, DefaultClient, []),
ServerConf = merge_chain_spec(UserServer, DefaultServer, []),
new_format([{ClientTag, ClientConf}, {ServerTag, ServerConf}]).
new_format(Conf) ->
CConf = proplists:get_value(client_chain, Conf),
SConf = proplists:get_value(server_chain, Conf),
#{server_chain => proplist_to_map(SConf),
client_chain => proplist_to_map(CConf)}.
proplist_to_map([Head | Rest]) ->
[Last | Tail] = lists:reverse(Rest),
#{root => Head,
intermediates => lists:reverse(Tail),
peer => Last}.
conf_tag(Role) ->
list_to_atom(Role ++ "_chain").
chain_spec(_Role, ecdh_rsa) ->
Digest = {digest, appropriate_sha(crypto:supports())},
CurveOid = hd(tls_v1:ecc_curves(0)),
[[Digest, {key, {namedCurve, CurveOid}}],
[Digest, {key, hardcode_rsa_key(1)}],
[Digest, {key, {namedCurve, CurveOid}}]];
chain_spec(_Role, ecdhe_ecdsa) ->
Digest = {digest, appropriate_sha(crypto:supports())},
CurveOid = hd(tls_v1:ecc_curves(0)),
[[Digest, {key, {namedCurve, CurveOid}}],
[Digest, {key, {namedCurve, CurveOid}}],
[Digest, {key, {namedCurve, CurveOid}}]];
chain_spec(_Role, ecdh_ecdsa) ->
Digest = {digest, appropriate_sha(crypto:supports())},
CurveOid = hd(tls_v1:ecc_curves(0)),
[[Digest, {key, {namedCurve, CurveOid}}],
[Digest, {key, {namedCurve, CurveOid}}],
[Digest, {key, {namedCurve, CurveOid}}]];
chain_spec(_Role, ecdhe_rsa) ->
Digest = {digest, appropriate_sha(crypto:supports())},
[[Digest, {key, hardcode_rsa_key(1)}],
[Digest, {key, hardcode_rsa_key(2)}],
[Digest, {key, hardcode_rsa_key(3)}]];
chain_spec(_Role, ecdsa) ->
Digest = {digest, appropriate_sha(crypto:supports())},
CurveOid = hd(tls_v1:ecc_curves(0)),
[[Digest, {key, {namedCurve, CurveOid}}],
[Digest, {key, {namedCurve, CurveOid}}],
[Digest, {key, {namedCurve, CurveOid}}]];
chain_spec(_Role, rsa) ->
Digest = {digest, appropriate_sha(crypto:supports())},
[[Digest, {key, hardcode_rsa_key(1)}],
[Digest, {key, hardcode_rsa_key(2)}],
[Digest, {key, hardcode_rsa_key(3)}]];
chain_spec(_Role, dsa) ->
Digest = {digest, appropriate_sha(crypto:supports())},
[[Digest, {key, hardcode_dsa_key(1)}],
[Digest, {key, hardcode_dsa_key(2)}],
[Digest, {key, hardcode_dsa_key(3)}]].
merge_chain_spec([], [], Acc)->
lists:reverse(Acc);
merge_chain_spec([User| UserRest], [Default | DefaultRest], Acc) ->
Merge = merge_spec(User, Default, confs(), []),
merge_chain_spec(UserRest, DefaultRest, [Merge | Acc]).
confs() ->
[key, digest, validity, extensions].
merge_spec(_, _, [], Acc) ->
Acc;
merge_spec(User, Default, [Conf | Rest], Acc) ->
case proplists:get_value(Conf, User, undefined) of
undefined ->
case proplists:get_value(Conf, Default, undefined) of
undefined ->
merge_spec(User, Default, Rest, Acc);
Value ->
merge_spec(User, Default, Rest, [{Conf, Value} | Acc])
end;
Value ->
merge_spec(User, Default, Rest, [{Conf, Value} | Acc])
end.
make_mix_cert(Config) ->
Ext = x509_test:extensions([{key_usage, [digitalSignature]}]),
Digest = {digest, appropriate_sha(crypto:supports())},
CurveOid = hd(tls_v1:ecc_curves(0)),
ClientFileBase = filename:join([proplists:get_value(priv_dir, Config), "mix"]),
ServerFileBase = filename:join([proplists:get_value(priv_dir, Config), "mix"]),
ClientChain = [[Digest, {key, {namedCurve, CurveOid}}],
[Digest, {key, hardcode_rsa_key(1)}],
[Digest, {key, {namedCurve, CurveOid}}, {extensions, Ext}]
],
ServerChain = [[Digest, {key, {namedCurve, CurveOid}}],
[Digest, {key, hardcode_rsa_key(2)}],
[Digest, {key, {namedCurve, CurveOid}},{extensions, Ext}]
],
ClientChainType =ServerChainType = mix,
CertChainConf = gen_conf(ClientChainType, ServerChainType, ClientChain, ServerChain),
ClientFileBase = filename:join([proplists:get_value(priv_dir, Config), atom_to_list(ClientChainType)]),
ServerFileBase = filename:join([proplists:get_value(priv_dir, Config), atom_to_list(ServerChainType)]),
GenCertData = public_key:pkix_test_data(CertChainConf),
[{server_config, ServerConf},
{client_config, ClientConf}] =
x509_test:gen_pem_config_files(GenCertData, ClientFileBase, ServerFileBase),
{[{verify, verify_peer} | ClientConf],
[{reuseaddr, true}, {verify, verify_peer} | ServerConf]
}.
make_ecdsa_cert(Config) ->
CryptoSupport = crypto:supports(),
case proplists:get_bool(ecdsa, proplists:get_value(public_keys, CryptoSupport)) of
true ->
ClientFileBase = filename:join([proplists:get_value(priv_dir, Config), "ecdsa"]),
ServerFileBase = filename:join([proplists:get_value(priv_dir, Config), "ecdsa"]),
ClientChain = proplists:get_value(client_chain, Config, default_cert_chain_conf()),
ServerChain = proplists:get_value(server_chain, Config, default_cert_chain_conf()),
CertChainConf = gen_conf(ecdsa, ecdsa, ClientChain, ServerChain),
GenCertData = public_key:pkix_test_data(CertChainConf),
[{server_config, ServerConf},
{client_config, ClientConf}] =
x509_test:gen_pem_config_files(GenCertData, ClientFileBase, ServerFileBase),
[{server_ecdsa_opts, [{ssl_imp, new},{reuseaddr, true} | ServerConf]},
{server_ecdsa_verify_opts, [{ssl_imp, new}, {reuseaddr, true},
{verify, verify_peer} | ServerConf]},
{client_ecdsa_opts, ClientConf}
| Config];
false ->
Config
end.
make_rsa_cert(Config) ->
CryptoSupport = crypto:supports(),
case proplists:get_bool(rsa, proplists:get_value(public_keys, CryptoSupport)) of
true ->
ClientFileBase = filename:join([proplists:get_value(priv_dir, Config), "rsa"]),
ServerFileBase = filename:join([proplists:get_value(priv_dir, Config), "rsa"]),
ClientChain = proplists:get_value(client_chain, Config, default_cert_chain_conf()),
ServerChain = proplists:get_value(server_chain, Config, default_cert_chain_conf()),
CertChainConf = gen_conf(rsa, rsa, ClientChain, ServerChain),
GenCertData = public_key:pkix_test_data(CertChainConf),
[{server_config, ServerConf},
{client_config, ClientConf}] =
x509_test:gen_pem_config_files(GenCertData, ClientFileBase, ServerFileBase),
[{server_rsa_opts, [{ssl_imp, new},{reuseaddr, true} | ServerConf]},
{server_rsa_verify_opts, [{ssl_imp, new}, {reuseaddr, true},
{verify, verify_peer} | ServerConf]},
{client_rsa_opts, ClientConf},
{client_rsa_verify_opts, [{verify, verify_peer} |ClientConf]}
| Config];
false ->
Config
end.
appropriate_sha(CryptoSupport) ->
case proplists:get_bool(sha256, CryptoSupport) of
true ->
sha256;
false ->
sha1
end.
%% RFC 4492, Sect. 2.3. ECDH_RSA
%%
%% This key exchange algorithm is the same as ECDH_ECDSA except that the
%% server's certificate MUST be signed with RSA rather than ECDSA.
make_ecdh_rsa_cert(Config) ->
CryptoSupport = crypto:supports(),
case proplists:get_bool(ecdh, proplists:get_value(public_keys, CryptoSupport)) of
true ->
ClientFileBase = filename:join([proplists:get_value(priv_dir, Config), "ecdh_rsa"]),
ServerFileBase = filename:join([proplists:get_value(priv_dir, Config), "ecdh_rsa"]),
ClientChain = proplists:get_value(client_chain, Config, default_cert_chain_conf()),
ServerChain = proplists:get_value(server_chain, Config, default_cert_chain_conf()),
CertChainConf = gen_conf(ecdh_rsa, ecdh_rsa, ClientChain, ServerChain),
GenCertData = public_key:pkix_test_data(CertChainConf),
[{server_config, ServerConf},
{client_config, ClientConf}] =
x509_test:gen_pem_config_files(GenCertData, ClientFileBase, ServerFileBase),
[{server_ecdh_rsa_opts, [{ssl_imp, new},{reuseaddr, true} | ServerConf]},
{server_ecdh_rsa_verify_opts, [{ssl_imp, new},{reuseaddr, true},
{verify, verify_peer} | ServerConf]},
{client_ecdh_rsa_opts, ClientConf}
| Config];
_ ->
Config
end.
start_upgrade_server(Args) ->
Result = spawn_link(?MODULE, run_upgrade_server, [Args]),
receive
{listen, up} ->
Result
end.
run_upgrade_server(Opts) ->
Node = proplists:get_value(node, Opts),
Port = proplists:get_value(port, Opts),
TimeOut = proplists:get_value(timeout, Opts, infinity),
TcpOptions = proplists:get_value(tcp_options, Opts),
SslOptions = proplists:get_value(ssl_options, Opts),
Pid = proplists:get_value(from, Opts),
ct:log("~p:~p~ngen_tcp:listen(~p, ~p)~n", [?MODULE,?LINE, Port, TcpOptions]),
{ok, ListenSocket} = rpc:call(Node, gen_tcp, listen, [Port, TcpOptions]),
Pid ! {listen, up},
send_selected_port(Pid, Port, ListenSocket),
ct:log("~p:~p~ngen_tcp:accept(~p)~n", [?MODULE,?LINE, ListenSocket]),
{ok, AcceptSocket} = rpc:call(Node, gen_tcp, accept, [ListenSocket]),
try
{ok, SslAcceptSocket} = case TimeOut of
infinity ->
ct:log("~p:~p~nssl:ssl_accept(~p, ~p)~n",
[?MODULE,?LINE, AcceptSocket, SslOptions]),
rpc:call(Node, ssl, ssl_accept,
[AcceptSocket, SslOptions]);
_ ->
ct:log("~p:~p~nssl:ssl_accept(~p, ~p, ~p)~n",
[?MODULE,?LINE, AcceptSocket, SslOptions, TimeOut]),
rpc:call(Node, ssl, ssl_accept,
[AcceptSocket, SslOptions, TimeOut])
end,
{Module, Function, Args} = proplists:get_value(mfa, Opts),
Msg = rpc:call(Node, Module, Function, [SslAcceptSocket | Args]),
ct:log("~p:~p~nUpgrade Server Msg: ~p ~n", [?MODULE,?LINE, Msg]),
Pid ! {self(), Msg},
receive
close ->
ct:log("~p:~p~nUpgrade Server closing~n", [?MODULE,?LINE]),
rpc:call(Node, ssl, close, [SslAcceptSocket])
end
catch error:{badmatch, Error} ->
Pid ! {self(), Error}
end.
start_upgrade_client(Args) ->
spawn_link(?MODULE, run_upgrade_client, [Args]).
run_upgrade_client(Opts) ->
Node = proplists:get_value(node, Opts),
Host = proplists:get_value(host, Opts),
Port = proplists:get_value(port, Opts),
Pid = proplists:get_value(from, Opts),
TcpOptions = proplists:get_value(tcp_options, Opts),
SslOptions = proplists:get_value(ssl_options, Opts),
ct:log("~p:~p~ngen_tcp:connect(~p, ~p, ~p)~n",
[?MODULE,?LINE, Host, Port, TcpOptions]),
{ok, Socket} = rpc:call(Node, gen_tcp, connect, [Host, Port, TcpOptions]),
send_selected_port(Pid, Port, Socket),
ct:log("~p:~p~nssl:connect(~p, ~p)~n", [?MODULE,?LINE, Socket, SslOptions]),
{ok, SslSocket} = rpc:call(Node, ssl, connect, [Socket, SslOptions]),
{Module, Function, Args} = proplists:get_value(mfa, Opts),
ct:log("~p:~p~napply(~p, ~p, ~p)~n",
[?MODULE,?LINE, Module, Function, [SslSocket | Args]]),
Msg = rpc:call(Node, Module, Function, [SslSocket | Args]),
ct:log("~p:~p~nUpgrade Client Msg: ~p ~n", [?MODULE,?LINE, Msg]),
Pid ! {self(), Msg},
receive
close ->
ct:log("~p:~p~nUpgrade Client closing~n", [?MODULE,?LINE]),
rpc:call(Node, ssl, close, [SslSocket])
end.
start_upgrade_server_error(Args) ->
Result = spawn_link(?MODULE, run_upgrade_server_error, [Args]),
receive
{listen, up} ->
Result
end.
run_upgrade_server_error(Opts) ->
Node = proplists:get_value(node, Opts),
Port = proplists:get_value(port, Opts),
TimeOut = proplists:get_value(timeout, Opts, infinity),
TcpOptions = proplists:get_value(tcp_options, Opts),
SslOptions = proplists:get_value(ssl_options, Opts),
Pid = proplists:get_value(from, Opts),
ct:log("~p:~p~ngen_tcp:listen(~p, ~p)~n", [?MODULE,?LINE, Port, TcpOptions]),
{ok, ListenSocket} = rpc:call(Node, gen_tcp, listen, [Port, TcpOptions]),
Pid ! {listen, up},
send_selected_port(Pid, Port, ListenSocket),
ct:log("~p:~p~ngen_tcp:accept(~p)~n", [?MODULE,?LINE, ListenSocket]),
{ok, AcceptSocket} = rpc:call(Node, gen_tcp, accept, [ListenSocket]),
Error = case TimeOut of
infinity ->
ct:log("~p:~p~nssl:ssl_accept(~p, ~p)~n",
[?MODULE,?LINE, AcceptSocket, SslOptions]),
rpc:call(Node, ssl, ssl_accept,
[AcceptSocket, SslOptions]);
_ ->
ct:log("~p:~p~nssl:ssl_accept(~p, ~p, ~p)~n",
[?MODULE,?LINE, AcceptSocket, SslOptions, TimeOut]),
rpc:call(Node, ssl, ssl_accept,
[AcceptSocket, SslOptions, TimeOut])
end,
Pid ! {self(), Error}.
start_server_error(Args) ->
Result = spawn_link(?MODULE, run_server_error, [Args]),
receive
{listen, up} ->
Result
end.
run_server_error(Opts) ->
Node = proplists:get_value(node, Opts),
Port = proplists:get_value(port, Opts),
Options = proplists:get_value(options, Opts),
Pid = proplists:get_value(from, Opts),
Transport = proplists:get_value(transport, Opts, ssl),
ct:log("~p:~p~nssl:listen(~p, ~p)~n", [?MODULE,?LINE, Port, Options]),
case rpc:call(Node, Transport, listen, [Port, Options]) of
{ok, #sslsocket{} = ListenSocket} ->
%% To make sure error_client will
%% get {error, closed} and not {error, connection_refused}
Pid ! {listen, up},
send_selected_port(Pid, Port, ListenSocket),
ct:log("~p:~p~nssl:transport_accept(~p)~n", [?MODULE,?LINE, ListenSocket]),
case rpc:call(Node, Transport, transport_accept, [ListenSocket]) of
{error, _} = Error ->
Pid ! {self(), Error};
{ok, AcceptSocket} ->
ct:log("~p:~p~nssl:ssl_accept(~p)~n", [?MODULE,?LINE, AcceptSocket]),
Error = rpc:call(Node, ssl, ssl_accept, [AcceptSocket]),
Pid ! {self(), Error}
end;
{ok, ListenSocket} ->
Pid ! {listen, up},
send_selected_port(Pid, Port, ListenSocket),
ct:log("~p:~p~n~p:accept(~p)~n", [?MODULE,?LINE, Transport, ListenSocket]),
case rpc:call(Node, Transport, accept, [ListenSocket]) of
{error, _} = Error ->
Pid ! {self(), Error}
end;
Error ->
%% Not really true but as this is an error test
%% this is what we want.
Pid ! {listen, up},
Pid ! {self(), Error}
end.
start_client_error(Args) ->
spawn_link(?MODULE, run_client_error, [Args]).
run_client_error(Opts) ->
Node = proplists:get_value(node, Opts),
Host = proplists:get_value(host, Opts),
Port = proplists:get_value(port, Opts),
Pid = proplists:get_value(from, Opts),
Transport = proplists:get_value(transport, Opts, ssl),
Options = proplists:get_value(options, Opts),
ct:log("~p:~p~nssl:connect(~p, ~p, ~p)~n", [?MODULE,?LINE, Host, Port, Options]),
Error = rpc:call(Node, Transport, connect, [Host, Port, Options]),
Pid ! {self(), Error}.
accepters(N) ->
accepters([], N).
accepters(Acc, 0) ->
Acc;
accepters(Acc, N) ->
receive
{accepter, _, Server} ->
accepters([Server| Acc], N-1)
end.
basic_test(COpts, SOpts, Config) ->
SType = proplists:get_value(server_type, Config),
CType = proplists:get_value(client_type, Config),
{Server, Port} = start_server(SType, SOpts, Config),
Client = start_client(CType, Port, COpts, Config),
gen_check_result(Server, SType, Client, CType),
stop(Server, Client).
ecc_test(Expect, COpts, SOpts, CECCOpts, SECCOpts, Config) ->
{Server, Port} = start_server_ecc(erlang, SOpts, Expect, SECCOpts, Config),
Client = start_client_ecc(erlang, Port, COpts, Expect, CECCOpts, Config),
check_result(Server, ok, Client, ok),
stop(Server, Client).
ecc_test_error(COpts, SOpts, CECCOpts, SECCOpts, Config) ->
{Server, Port} = start_server_ecc_error(erlang, SOpts, SECCOpts, Config),
Client = start_client_ecc_error(erlang, Port, COpts, CECCOpts, Config),
Error = {error, {tls_alert, "insufficient security"}},
check_result(Server, Error, Client, Error).
start_client(openssl, Port, ClientOpts, Config) ->
Cert = proplists:get_value(certfile, ClientOpts),
Key = proplists:get_value(keyfile, ClientOpts),
CA = proplists:get_value(cacertfile, ClientOpts),
Version = ssl_test_lib:protocol_version(Config),
Exe = "openssl",
Args = ["s_client", "-verify", "2", "-port", integer_to_list(Port),
ssl_test_lib:version_flag(Version),
"-cert", Cert, "-CAfile", CA,
"-key", Key, "-host","localhost", "-msg", "-debug"],
OpenSslPort = ssl_test_lib:portable_open_port(Exe, Args),
true = port_command(OpenSslPort, "Hello world"),
OpenSslPort;
start_client(erlang, Port, ClientOpts, Config) ->
{ClientNode, _, Hostname} = ssl_test_lib:run_where(Config),
KeyEx = proplists:get_value(check_keyex, Config, false),
ssl_test_lib:start_client([{node, ClientNode}, {port, Port},
{host, Hostname},
{from, self()},
{mfa, {ssl_test_lib, check_key_exchange_send_active, [KeyEx]}},
{options, [{verify, verify_peer} | ClientOpts]}]).
start_client_ecc(erlang, Port, ClientOpts, Expect, ECCOpts, Config) ->
{ClientNode, _, Hostname} = ssl_test_lib:run_where(Config),
ssl_test_lib:start_client([{node, ClientNode}, {port, Port},
{host, Hostname},
{from, self()},
{mfa, {?MODULE, check_ecc, [client, Expect]}},
{options,
ECCOpts ++
[{verify, verify_peer} | ClientOpts]}]).
start_client_ecc_error(erlang, Port, ClientOpts, ECCOpts, Config) ->
{ClientNode, _, Hostname} = ssl_test_lib:run_where(Config),
ssl_test_lib:start_client_error([{node, ClientNode}, {port, Port},
{host, Hostname},
{from, self()},
{options,
ECCOpts ++
[{verify, verify_peer} | ClientOpts]}]).
start_server(openssl, ServerOpts, Config) ->
Cert = proplists:get_value(certfile, ServerOpts),
Key = proplists:get_value(keyfile, ServerOpts),
CA = proplists:get_value(cacertfile, ServerOpts),
Port = inet_port(node()),
Version = protocol_version(Config),
Exe = "openssl",
Args = ["s_server", "-accept", integer_to_list(Port), ssl_test_lib:version_flag(Version),
"-verify", "2", "-cert", Cert, "-CAfile", CA,
"-key", Key, "-msg", "-debug"],
OpenSslPort = portable_open_port(Exe, Args),
true = port_command(OpenSslPort, "Hello world"),
{OpenSslPort, Port};
start_server(erlang, ServerOpts, Config) ->
{_, ServerNode, _} = ssl_test_lib:run_where(Config),
KeyEx = proplists:get_value(check_keyex, Config, false),
Server = start_server([{node, ServerNode}, {port, 0},
{from, self()},
{mfa, {ssl_test_lib,
check_key_exchange_send_active,
[KeyEx]}},
{options, [{verify, verify_peer} | ServerOpts]}]),
{Server, inet_port(Server)}.
start_server_with_raw_key(erlang, ServerOpts, Config) ->
{_, ServerNode, _} = ssl_test_lib:run_where(Config),
Server = start_server([{node, ServerNode}, {port, 0},
{from, self()},
{mfa, {ssl_test_lib,
send_recv_result_active,
[]}},
{options,
[{verify, verify_peer} | ServerOpts]}]),
{Server, inet_port(Server)}.
start_server_ecc(erlang, ServerOpts, Expect, ECCOpts, Config) ->
{_, ServerNode, _} = run_where(Config),
Server = start_server([{node, ServerNode}, {port, 0},
{from, self()},
{mfa, {?MODULE, check_ecc, [server, Expect]}},
{options,
ECCOpts ++
[{verify, verify_peer} | ServerOpts]}]),
{Server, inet_port(Server)}.
start_server_ecc_error(erlang, ServerOpts, ECCOpts, Config) ->
{_, ServerNode, _} = run_where(Config),
Server = start_server_error([{node, ServerNode}, {port, 0},
{from, self()},
{options,
ECCOpts ++
[{verify, verify_peer} | ServerOpts]}]),
{Server, inet_port(Server)}.
gen_check_result(Server, erlang, Client, erlang) ->
check_result(Server, ok, Client, ok);
gen_check_result(Server, erlang, _, _) ->
check_result(Server, ok);
gen_check_result(_, _, Client, erlang) ->
check_result(Client, ok);
gen_check_result(_,openssl, _, openssl) ->
ok.
stop(Port1, Port2) when is_port(Port1), is_port(Port2) ->
close_port(Port1),
close_port(Port2);
stop(Port, Pid) when is_port(Port) ->
close_port(Port),
close(Pid);
stop(Pid, Port) when is_port(Port) ->
close_port(Port),
close(Pid);
stop(Client, Server) ->
close(Server),
close(Client).
supported_eccs(Opts) ->
ToCheck = proplists:get_value(eccs, Opts, []),
Supported = ssl:eccs(),
lists:all(fun(Curve) -> lists:member(Curve, Supported) end, ToCheck).
check_ecc(SSL, Role, Expect) ->
{ok, Data} = ssl:connection_information(SSL),
case lists:keyfind(ecc, 1, Data) of
{ecc, {named_curve, Expect}} -> ok;
Other -> {error, Role, Expect, Other}
end.
inet_port(Pid) when is_pid(Pid)->
receive
{Pid, {port, Port}} ->
Port
end;
inet_port(Node) ->
{Port, Socket} = do_inet_port(Node),
rpc:call(Node, gen_tcp, close, [Socket]),
Port.
do_inet_port(Node) ->
{ok, Socket} = rpc:call(Node, gen_tcp, listen, [0, [{reuseaddr, true}]]),
{ok, Port} = rpc:call(Node, inet, port, [Socket]),
{Port, Socket}.
no_result(_) ->
no_result_msg.
trigger_renegotiate(Socket, [ErlData, N]) ->
{ok, [{session_id, Id}]} = ssl:connection_information(Socket, [session_id]),
trigger_renegotiate(Socket, ErlData, N, Id).
trigger_renegotiate(Socket, _, 0, Id) ->
ct:sleep(1000),
case ssl:connection_information(Socket, [session_id]) of
{ok, [{session_id, Id}]} ->
fail_session_not_renegotiated;
%% Tests that uses this function will not reuse
%% sessions so if we get a new session id the
%% renegotiation has succeeded.
{ok, [{session_id, _}]} ->
ok;
{error, closed} ->
fail_session_fatal_alert_during_renegotiation;
{error, timeout} ->
fail_timeout
end;
trigger_renegotiate(Socket, ErlData, N, Id) ->
ssl:send(Socket, ErlData),
trigger_renegotiate(Socket, ErlData, N-1, Id).
send_selected_port(Pid, 0, #sslsocket{} = Socket) ->
{ok, {_, NewPort}} = ssl:sockname(Socket),
Pid ! {self(), {port, NewPort}};
send_selected_port(Pid, 0, Socket) ->
{ok, {_, NewPort}} = inet:sockname(Socket),
Pid ! {self(), {port, NewPort}};
send_selected_port(_,_,_) ->
ok.
rsa_suites(CounterPart) ->
ECC = is_sane_ecc(CounterPart),
FIPS = is_fips(CounterPart),
CryptoSupport = crypto:supports(),
Ciphers = proplists:get_value(ciphers, CryptoSupport),
lists:filter(fun({rsa, des_cbc, sha}) when FIPS == true ->
false;
({dhe_rsa, des_cbc, sha}) when FIPS == true ->
false;
({rsa, Cipher, _}) ->
lists:member(cipher_atom(Cipher), Ciphers);
({dhe_rsa, Cipher, _}) ->
lists:member(cipher_atom(Cipher), Ciphers);
({ecdhe_rsa, Cipher, _}) when ECC == true ->
lists:member(cipher_atom(Cipher), Ciphers);
({rsa, Cipher, _, _}) ->
lists:member(cipher_atom(Cipher), Ciphers);
({dhe_rsa, Cipher, _,_}) ->
lists:member(cipher_atom(Cipher), Ciphers);
({ecdhe_rsa, Cipher, _,_}) when ECC == true ->
lists:member(cipher_atom(Cipher), Ciphers);
(_) ->
false
end,
common_ciphers(CounterPart)).
common_ciphers(crypto) ->
ssl:cipher_suites();
common_ciphers(openssl) ->
OpenSslSuites =
string:tokens(string:strip(os:cmd("openssl ciphers"), right, $\n), ":"),
[ssl_cipher:erl_suite_definition(S)
|| S <- ssl_cipher:suites(tls_record:highest_protocol_version([])),
lists:member(ssl_cipher:openssl_suite_name(S), OpenSslSuites)
].
available_suites(Version) ->
[ssl_cipher:erl_suite_definition(Suite) ||
Suite <- ssl_cipher:filter_suites(ssl_cipher:suites(Version))].
rsa_non_signed_suites(Version) ->
lists:filter(fun({rsa, _, _}) ->
false;
(_) ->
true
end,
available_suites(Version)).
dsa_suites(Version) ->
lists:filter(fun({dhe_dss, _, _}) ->
true;
(_) ->
false
end,
available_suites(Version)).
ecdsa_suites(Version) ->
lists:filter(fun({ecdhe_ecdsa, _, _}) ->
true;
(_) ->
false
end,
available_suites(Version)).
ecdh_rsa_suites(Version) ->
lists:filter(fun({ecdh_rsa, _, _}) ->
true;
(_) ->
false
end,
available_suites(Version)).
openssl_rsa_suites() ->
Ciphers = ssl:cipher_suites(openssl),
lists:filter(fun(Str) -> string_regex_filter(Str, "RSA")
end, Ciphers) -- openssl_ecdh_rsa_suites().
openssl_dsa_suites() ->
Ciphers = ssl:cipher_suites(openssl),
lists:filter(fun(Str) -> string_regex_filter(Str, "DSS")
end, Ciphers).
openssl_ecdsa_suites() ->
Ciphers = ssl:cipher_suites(openssl),
lists:filter(fun(Str) -> string_regex_filter(Str, "ECDHE-ECDSA")
end, Ciphers).
openssl_ecdh_rsa_suites() ->
Ciphers = ssl:cipher_suites(openssl),
lists:filter(fun(Str) -> string_regex_filter(Str, "ECDH-RSA")
end, Ciphers).
openssl_filter(FilterStr) ->
Ciphers = string:tokens(os:cmd("openssl ciphers"), ":"),
lists:filter(fun(Str) -> string_regex_filter(Str, FilterStr)
end, Ciphers).
string_regex_filter(Str, Search) when is_list(Str) ->
case re:run(Str, Search, []) of
nomatch ->
false;
_ ->
true
end;
string_regex_filter(_Str, _Search) ->
false.
ecdh_dh_anonymous_suites(Version) ->
ssl:filter_cipher_suites([ssl_cipher:suite_definition(S) || S <- ssl_cipher:anonymous_suites(Version)],
[{key_exchange,
fun(dh_anon) ->
true;
(ecdh_anon) ->
true;
(_) ->
false
end}]).
psk_suites(Version) ->
ssl:filter_cipher_suites([ssl_cipher:suite_definition(S) || S <- ssl_cipher:psk_suites(Version)], []).
psk_anon_suites(Version) ->
ssl:filter_cipher_suites([ssl_cipher:suite_definition(S) || S <- ssl_cipher:psk_suites_anon(Version)],
[{key_exchange,
fun(psk) ->
true;
(psk_dhe) ->
true;
(_) ->
false
end}]).
srp_suites() ->
ssl:filter_cipher_suites([ssl_cipher:suite_definition(S) || S <- ssl_cipher:srp_suites()],
[{key_exchange,
fun(srp_rsa) ->
true;
(_) ->
false
end}]).
srp_anon_suites() ->
ssl:filter_cipher_suites([ssl_cipher:suite_definition(S) || S <- ssl_cipher:srp_suites_anon()],
[]).
srp_dss_suites() ->
ssl:filter_cipher_suites([ssl_cipher:suite_definition(S) || S <- ssl_cipher:srp_suites()],
[{key_exchange,
fun(srp_dss) ->
true;
(_) ->
false
end}]).
rc4_suites(Version) ->
ssl:filter_cipher_suites([ssl_cipher:suite_definition(S) || S <-ssl_cipher:rc4_suites(Version)], []).
des_suites(Version) ->
ssl:filter_cipher_suites([ssl_cipher:suite_definition(S) || S <-ssl_cipher:des_suites(Version)], []).
tuple_to_map({Kex, Cipher, Mac}) ->
#{key_exchange => Kex,
cipher => Cipher,
mac => Mac,
prf => default_prf};
tuple_to_map({Kex, Cipher, Mac, Prf}) ->
#{key_exchange => Kex,
cipher => Cipher,
mac => Mac,
prf => Prf}.
pem_to_der(File) ->
{ok, PemBin} = file:read_file(File),
public_key:pem_decode(PemBin).
der_to_pem(File, Entries) ->
PemBin = public_key:pem_encode(Entries),
file:write_file(File, PemBin).
cipher_result(Socket, Result) ->
{ok, Info} = ssl:connection_information(Socket),
Result = {ok, {proplists:get_value(protocol, Info), proplists:get_value(cipher_suite, Info)}},
ct:log("~p:~p~nSuccessfull connect: ~p~n", [?MODULE,?LINE, Result]),
%% Importante to send two packets here
%% to properly test "cipher state" handling
ssl:send(Socket, "Hello\n"),
receive
{ssl, Socket, "H"} ->
ssl:send(Socket, " world\n"),
receive_rizzo_duong_beast();
{ssl, Socket, "Hello\n"} ->
ssl:send(Socket, " world\n"),
receive
{ssl, Socket, " world\n"} ->
ok
end;
Other ->
{unexpected, Other}
end.
session_info_result(Socket) ->
{ok, Info} = ssl:connection_information(Socket, [session_id, cipher_suite]),
Info.
public_key(#'PrivateKeyInfo'{privateKeyAlgorithm =
#'PrivateKeyInfo_privateKeyAlgorithm'{algorithm = ?rsaEncryption},
privateKey = Key}) ->
public_key:der_decode('RSAPrivateKey', iolist_to_binary(Key));
public_key(#'PrivateKeyInfo'{privateKeyAlgorithm =
#'PrivateKeyInfo_privateKeyAlgorithm'{algorithm = ?'id-dsa'},
privateKey = Key}) ->
public_key:der_decode('DSAPrivateKey', iolist_to_binary(Key));
public_key(Key) ->
Key.
receive_rizzo_duong_beast() ->
receive
{ssl, _, "ello\n"} ->
receive
{ssl, _, " "} ->
receive
{ssl, _, "world\n"} ->
ok
end
end
end.
state([{data,[{"State", {_StateName, StateData}}]} | _]) -> %% gen_statem
StateData;
state([{data,[{"State", State}]} | _]) -> %% gen_server
State;
state([{data,[{"StateData", State}]} | _]) -> %% gen_fsm
State;
state([_ | Rest]) ->
state(Rest).
is_tls_version('dtlsv1.2') ->
true;
is_tls_version('dtlsv1') ->
true;
is_tls_version('tlsv1.2') ->
true;
is_tls_version('tlsv1.1') ->
true;
is_tls_version('tlsv1') ->
true;
is_tls_version('sslv3') ->
true;
is_tls_version(_) ->
false.
init_tls_version(Version, Config)
when Version == 'dtlsv1.2'; Version == 'dtlsv1' ->
ssl:stop(),
application:load(ssl),
application:set_env(ssl, dtls_protocol_version, Version),
ssl:start(),
NewConfig = proplists:delete(protocol_opts, proplists:delete(protocol, Config)),
[{protocol, dtls}, {protocol_opts, [{protocol, dtls}]} | NewConfig];
init_tls_version(Version, Config) ->
ssl:stop(),
application:load(ssl),
application:set_env(ssl, protocol_version, Version),
ssl:start(),
NewConfig = proplists:delete(protocol_opts, proplists:delete(protocol, Config)),
[{protocol, tls} | NewConfig].
clean_tls_version(Config) ->
proplists:delete(protocol_opts, proplists:delete(protocol, Config)).
sufficient_crypto_support(Version)
when Version == 'tlsv1.2'; Version == 'dtlsv1.2' ->
CryptoSupport = crypto:supports(),
proplists:get_bool(sha256, proplists:get_value(hashs, CryptoSupport));
sufficient_crypto_support(cipher_ec) ->
CryptoSupport = crypto:supports(),
proplists:get_bool(ecdh, proplists:get_value(public_keys, CryptoSupport));
sufficient_crypto_support(_) ->
true.
check_key_exchange_send_active(Socket, false) ->
send_recv_result_active(Socket);
check_key_exchange_send_active(Socket, KeyEx) ->
{ok, Info} =
ssl:connection_information(Socket, [cipher_suite, protocol]),
Suite = proplists:get_value(cipher_suite, Info),
Version = proplists:get_value(protocol, Info),
true = check_key_exchange(Suite, KeyEx, Version),
send_recv_result_active(Socket).
check_key_exchange({KeyEx,_, _}, KeyEx, _) ->
ct:pal("Kex: ~p", [KeyEx]),
true;
check_key_exchange({KeyEx,_,_,_}, KeyEx, _) ->
ct:pal("Kex: ~p", [KeyEx]),
true;
check_key_exchange(KeyEx1, KeyEx2, Version) ->
ct:pal("Kex: ~p ~p", [KeyEx1, KeyEx2]),
case Version of
'tlsv1.2' ->
v_1_2_check(element(1, KeyEx1), KeyEx2);
'dtlsv1.2' ->
v_1_2_check(element(1, KeyEx1), KeyEx2);
_ ->
ct:pal("Negotiated ~p Expected ~p", [KeyEx1, KeyEx2]),
false
end.
v_1_2_check(ecdh_ecdsa, ecdh_rsa) ->
true;
v_1_2_check(ecdh_rsa, ecdh_ecdsa) ->
true;
v_1_2_check(ecdhe_ecdsa, ecdhe_rsa) ->
true;
v_1_2_check(ecdhe_rsa, ecdhe_ecdsa) ->
true;
v_1_2_check(_, _) ->
false.
send_recv_result_active(Socket) ->
ssl:send(Socket, "Hello world"),
receive
{ssl, Socket, "H"} ->
receive
{ssl, Socket, "ello world"} ->
ok
end;
{ssl, Socket, "Hello world"} ->
ok
end.
send_recv_result(Socket) ->
ssl:send(Socket, "Hello world"),
{ok,"Hello world"} = ssl:recv(Socket, 11),
ok.
send_recv_result_active_once(Socket) ->
ssl:send(Socket, "Hello world"),
receive
{ssl, Socket, "H"} ->
ssl:setopts(Socket, [{active, once}]),
receive
{ssl, Socket, "ello world"} ->
ok
end;
{ssl, Socket, "Hello world"} ->
ok
end.
is_sane_ecc(openssl) ->
case os:cmd("openssl version") of
"OpenSSL 1.0.0a" ++ _ -> % Known bug in openssl
%% manifests as SSL_CHECK_SERVERHELLO_TLSEXT:tls invalid ecpointformat list
false;
"OpenSSL 1.0.0" ++ _ -> % Known bug in openssl
%% manifests as SSL_CHECK_SERVERHELLO_TLSEXT:tls invalid ecpointformat list
false;
"OpenSSL 1.0.1l" ++ _ ->
%% Breaks signature verification
false;
"OpenSSL 0.9.8" ++ _ -> % Does not support ECC
false;
"OpenSSL 0.9.7" ++ _ -> % Does not support ECC
false;
_ ->
true
end;
is_sane_ecc(crypto) ->
[{_,_, Bin}] = crypto:info_lib(),
case binary_to_list(Bin) of
"OpenSSL 0.9.8" ++ _ -> % Does not support ECC
false;
"OpenSSL 0.9.7" ++ _ -> % Does not support ECC
false;
_ ->
true
end;
is_sane_ecc(_) ->
true.
is_fips(openssl) ->
VersionStr = os:cmd("openssl version"),
case re:split(VersionStr, "fips") of
[_] ->
false;
_ ->
true
end;
is_fips(crypto) ->
[{_,_, Bin}] = crypto:info_lib(),
case re:split(Bin, <<"fips">>) of
[_] ->
false;
_ ->
true
end;
is_fips(_) ->
false.
cipher_restriction(Config0) ->
Version = protocol_version(Config0, tuple),
case is_sane_ecc(openssl) of
false ->
Opts = proplists:get_value(server_opts, Config0),
Config1 = proplists:delete(server_opts, Config0),
VerOpts = proplists:get_value(server_verification_opts, Config1),
Config = proplists:delete(server_verification_opts, Config1),
Restricted0 = ssl:cipher_suites() -- ecdsa_suites(Version),
Restricted = Restricted0 -- ecdh_rsa_suites(Version),
[{server_opts, [{ciphers, Restricted} | Opts]}, {server_verification_opts, [{ciphers, Restricted} | VerOpts] } | Config];
true ->
Config0
end.
openssl_dsa_support() ->
case os:cmd("openssl version") of
"LibreSSL 2.6.1" ++ _ ->
true;
"LibreSSL 2.6.2" ++ _ ->
true;
"LibreSSL 2.6" ++ _ ->
false;
"LibreSSL 2.4" ++ _ ->
true;
"LibreSSL 2.3" ++ _ ->
true;
"LibreSSL 2.2" ++ _ ->
true;
"LibreSSL 2.1" ++ _ ->
true;
"LibreSSL 2.0" ++ _ ->
true;
"LibreSSL" ++ _ ->
false;
"OpenSSL 1.0.1" ++ Rest ->
hd(Rest) >= s;
_ ->
true
end.
%% Acctual support is tested elsewhere, this is to exclude some LibreSSL and OpenSSL versions
openssl_sane_dtls() ->
case os:cmd("openssl version") of
"OpenSSL 0." ++ _ ->
false;
"OpenSSL 1.0.1s-freebsd" ++ _ ->
false;
"OpenSSL 1.0.2k-freebsd" ++ _ ->
false;
"OpenSSL 1.0.2d" ++ _ ->
false;
"OpenSSL 1.0.2n" ++ _ ->
false;
"OpenSSL 1.0.0" ++ _ ->
false;
"OpenSSL" ++ _ ->
true;
"LibreSSL 2.7" ++ _ ->
true;
_ ->
false
end.
openssl_sane_client_cert() ->
case os:cmd("openssl version") of
"LibreSSL 2.5.2" ++ _ ->
true;
"LibreSSL 2.4" ++ _ ->
false;
"LibreSSL 2.3" ++ _ ->
false;
"LibreSSL 2.1" ++ _ ->
false;
"LibreSSL 2.0" ++ _ ->
false;
"LibreSSL 2.0" ++ _ ->
false;
"OpenSSL 1.0.1s-freebsd" ->
false;
"OpenSSL 1.0.0" ++ _ ->
false;
_ ->
true
end.
check_sane_openssl_version(Version) ->
case supports_ssl_tls_version(Version) of
true ->
case {Version, os:cmd("openssl version")} of
{'sslv3', "OpenSSL 1.0.2" ++ _} ->
false;
{'dtlsv1', _} ->
not is_fips(openssl);
{'dtlsv1.2', _} ->
not is_fips(openssl);
{_, "OpenSSL 1.0.2" ++ _} ->
true;
{_, "OpenSSL 1.0.1" ++ _} ->
true;
{'tlsv1.2', "OpenSSL 1.0.0" ++ _} ->
false;
{'tlsv1.1', "OpenSSL 1.0.0" ++ _} ->
false;
{'dtlsv1.2', "OpenSSL 1.0.2" ++ _} ->
false;
{'dtlsv1', "OpenSSL 1.0.0" ++ _} ->
false;
{'tlsv1.2', "OpenSSL 0" ++ _} ->
false;
{'tlsv1.1', "OpenSSL 0" ++ _} ->
false;
{'dtlsv1', "OpenSSL 0" ++ _} ->
false;
{'dtlsv1.2', "OpenSSL 0" ++ _} ->
false;
{_, _} ->
true
end;
false ->
false
end.
enough_openssl_crl_support("OpenSSL 0." ++ _) -> false;
enough_openssl_crl_support(_) -> true.
wait_for_openssl_server(Port, tls) ->
do_wait_for_openssl_tls_server(Port, 10);
wait_for_openssl_server(_Port, dtls) ->
ok. %% No need to wait for DTLS over UDP server
%% client will retransmitt until it is up.
do_wait_for_openssl_tls_server(_, 0) ->
exit(failed_to_connect_to_openssl);
do_wait_for_openssl_tls_server(Port, N) ->
case gen_tcp:connect("localhost", Port, []) of
{ok, S} ->
gen_tcp:close(S);
_ ->
ct:sleep(?SLEEP),
do_wait_for_openssl_tls_server(Port, N-1)
end.
version_flag(tlsv1) ->
"-tls1";
version_flag('tlsv1.1') ->
"-tls1_1";
version_flag('tlsv1.2') ->
"-tls1_2";
version_flag(sslv3) ->
"-ssl3";
version_flag(sslv2) ->
"-ssl2";
version_flag('dtlsv1.2') ->
"-dtls1_2";
version_flag('dtlsv1') ->
"-dtls1".
filter_suites([Cipher | _] = Ciphers, AtomVersion) when is_list(Cipher)->
filter_suites([ssl_cipher:openssl_suite(S) || S <- Ciphers],
AtomVersion);
filter_suites([Cipher | _] = Ciphers, AtomVersion) when is_binary(Cipher)->
filter_suites([ssl_cipher:erl_suite_definition(S) || S <- Ciphers],
AtomVersion);
filter_suites(Ciphers0, AtomVersion) ->
Version = tls_version(AtomVersion),
Supported0 = ssl_cipher:suites(Version)
++ ssl_cipher:anonymous_suites(Version)
++ ssl_cipher:psk_suites(Version)
++ ssl_cipher:psk_suites_anon(Version)
++ ssl_cipher:srp_suites()
++ ssl_cipher:srp_suites_anon()
++ ssl_cipher:rc4_suites(Version),
Supported1 = ssl_cipher:filter_suites(Supported0),
Supported2 = [ssl_cipher:erl_suite_definition(S) || S <- Supported1],
[Cipher || Cipher <- Ciphers0, lists:member(Cipher, Supported2)].
-define(OPENSSL_QUIT, "Q\n").
close_port(Port) ->
catch port_command(Port, ?OPENSSL_QUIT),
close_loop(Port, 500, false).
close_loop(Port, Time, SentClose) ->
receive
{Port, {data,Debug}} when is_port(Port) ->
ct:log("openssl ~s~n",[Debug]),
close_loop(Port, Time, SentClose);
{ssl,_,Msg} ->
ct:log("ssl Msg ~s~n",[Msg]),
close_loop(Port, Time, SentClose);
{Port, closed} ->
ct:log("Port Closed~n",[]),
ok;
{'EXIT', Port, Reason} ->
ct:log("Port Closed ~p~n",[Reason]),
ok;
Msg ->
ct:log("Port Msg ~p~n",[Msg]),
close_loop(Port, Time, SentClose)
after Time ->
case SentClose of
false ->
ct:log("Closing port ~n",[]),
catch erlang:port_close(Port),
close_loop(Port, Time, true);
true ->
ct:log("Timeout~n",[])
end
end.
portable_open_port(Exe, Args) ->
AbsPath = os:find_executable(Exe),
ct:pal("open_port({spawn_executable, ~p}, [{args, ~p}, stderr_to_stdout]).", [AbsPath, Args]),
open_port({spawn_executable, AbsPath},
[{args, Args}, stderr_to_stdout]).
supports_ssl_tls_version(sslv2 = Version) ->
case os:cmd("openssl version") of
"OpenSSL 1" ++ _ ->
false;
%% Appears to be broken
"OpenSSL 0.9.8.o" ++ _ ->
false;
_ ->
VersionFlag = version_flag(Version),
Exe = "openssl",
Args = ["s_client", VersionFlag],
Port = ssl_test_lib:portable_open_port(Exe, Args),
do_supports_ssl_tls_version(Port, "")
end;
supports_ssl_tls_version(Version) ->
VersionFlag = version_flag(Version),
Exe = "openssl",
Args = ["s_client", VersionFlag],
Port = ssl_test_lib:portable_open_port(Exe, Args),
do_supports_ssl_tls_version(Port, "").
do_supports_ssl_tls_version(Port, Acc) ->
receive
{Port, {data, Data}} ->
case Acc ++ Data of
"unknown option" ++ _ ->
false;
Error when length(Error) >= 11 ->
case lists:member("error", string:tokens(Data, ":")) of
true ->
false;
false ->
do_supports_ssl_tls_version(Port, Error)
end;
_ ->
do_supports_ssl_tls_version(Port, Acc ++ Data)
end
after 1000 ->
true
end.
ssl_options(Option, Config) when is_atom(Option) ->
ProtocolOpts = proplists:get_value(protocol_opts, Config, []),
Opts = proplists:get_value(Option, Config, []),
Opts ++ ProtocolOpts;
ssl_options(Options, Config) ->
ProtocolOpts = proplists:get_value(protocol_opts, Config, []),
Options ++ ProtocolOpts.
protocol_version(Config) ->
protocol_version(Config, atom).
protocol_version(Config, tuple) ->
case proplists:get_value(protocol, Config) of
dtls ->
dtls_record:highest_protocol_version(dtls_record:supported_protocol_versions());
_ ->
tls_record:highest_protocol_version(tls_record:supported_protocol_versions())
end;
protocol_version(Config, atom) ->
case proplists:get_value(protocol, Config) of
dtls ->
dtls_record:protocol_version(protocol_version(Config, tuple));
_ ->
tls_record:protocol_version(protocol_version(Config, tuple))
end.
protocol_options(Config, Options) ->
Protocol = proplists:get_value(protocol, Config, tls),
{Protocol, Opts} = lists:keyfind(Protocol, 1, Options),
Opts.
ct_log_supported_protocol_versions(Config) ->
case proplists:get_value(protocol, Config) of
dtls ->
ct:log("DTLS version ~p~n ", [dtls_record:supported_protocol_versions()]);
_ ->
ct:log("TLS/SSL version ~p~n ", [tls_record:supported_protocol_versions()])
end.
clean_env() ->
application:unset_env(ssl, protocol_version),
application:unset_env(ssl, dtls_protocol_version),
application:unset_env(ssl, session_lifetime),
application:unset_env(ssl, session_cb),
application:unset_env(ssl, session_cb_init_args),
application:unset_env(ssl, session_cache_client_max),
application:unset_env(ssl, session_cache_server_max),
application:unset_env(ssl, ssl_pem_cache_clean),
application:unset_env(ssl, bypass_pem_cache),
application:unset_env(ssl, alert_timeout).
clean_start() ->
ssl:stop(),
application:load(ssl),
clean_env(),
ssl:start().
is_psk_anon_suite({psk, _,_}) ->
true;
is_psk_anon_suite({dhe_psk,_,_}) ->
true;
is_psk_anon_suite({psk, _,_,_}) ->
true;
is_psk_anon_suite({dhe_psk, _,_,_}) ->
true;
is_psk_anon_suite(_) ->
false.
cipher_atom(aes_256_cbc) ->
aes_cbc256;
cipher_atom(aes_128_cbc) ->
aes_cbc128;
cipher_atom('3des_ede_cbc') ->
des_ede3;
cipher_atom(Atom) ->
Atom.
tls_version('dtlsv1' = Atom) ->
dtls_v1:corresponding_tls_version(dtls_record:protocol_version(Atom));
tls_version('dtlsv1.2' = Atom) ->
dtls_v1:corresponding_tls_version(dtls_record:protocol_version(Atom));
tls_version(Atom) ->
tls_record:protocol_version(Atom).
hardcode_rsa_key(1) ->
#'RSAPrivateKey'{
version = 'two-prime',
modulus = 23995666614853919027835084074500048897452890537492185072956789802729257783422306095699263934587064480357348855732149402060270996295002843755712064937715826848741191927820899197493902093529581182351132392364214171173881547273475904587683433713767834856230531387991145055273426806331200574039205571401702219159773947658558490957010003143162250693492642996408861265758000254664396313741422909188635443907373976005987612936763564996605457102336549804831742940035613780926178523017685712710473543251580072875247250504243621640157403744718833162626193206685233710319205099867303242759099560438381385658382486042995679707669,
publicExponent = 17,
privateExponent = 11292078406990079542510627799764728892919007311761028269626724613049062486316379339152594792746853873109340637991599718616598115903530750002688030558925094987642913848386305504703012749896273497577003478759630198199473669305165131570674557041773098755873191241407597673069847908861741446606684974777271632545629600685952292605647052193819136445675100211504432575554351515262198132231537860917084269870590492135731720141577986787033006338680118008484613510063003323516659048210893001173583018220214626635609151105287049126443102976056146630518124476470236027123782297108342869049542023328584384300970694412006494684657,
prime1 = 169371138592582642967021557955633494538845517070305333860805485424261447791289944610138334410987654265476540480228705481960508520379619587635662291973699651583489223555422528867090299996446070521801757353675026048850480903160224210802452555900007597342687137394192939372218903554801584969667104937092080815197,
prime2 = 141675062317286527042995673340952251894209529891636708844197799307963834958115010129693036021381525952081167155681637592199810112261679449166276939178032066869788822014115556349519329537177920752776047051833616197615329017439297361972726138285974555338480581117881706656603857310337984049152655480389797687577,
exponent1 = 119556097830058336212015217380447172615655659108450823901745048534772786676204666783627059584226579481512852103690850928442711896738555003036938088452023283470698275450886490965004917644550167427154181661417665446247398284583687678213495921811770068712485038160606780733330990744565824684470897602653233516609,
exponent2 = 41669135975672507953822256864985956439473391144599032012999352737636422046504414744027363535700448809435637398729893409470532385959317485048904982111185902020526124121798693043976273393287623750816484427009887116945685005129205106462566511260580751570141347387612266663707016855981760014456663376585234613993,
coefficient = 76837684977089699359024365285678488693966186052769523357232308621548155587515525857011429902602352279058920284048929101483304120686557782043616693940283344235057989514310975192908256494992960578961614059245280827077951132083993754797053182279229469590276271658395444955906108899267024101096069475145863928441,
otherPrimeInfos = asn1_NOVALUE};
hardcode_rsa_key(2) ->
#'RSAPrivateKey'{
version = 'two-prime',
modulus = 21343679768589700771839799834197557895311746244621307033143551583788179817796325695589283169969489517156931770973490560582341832744966317712674900833543896521418422508485833901274928542544381247956820115082240721897193055368570146764204557110415281995205343662628196075590438954399631753508888358737971039058298703003743872818150364935790613286541190842600031570570099801682794056444451081563070538409720109449780410837763602317050353477918147758267825417201591905091231778937606362076129350476690460157227101296599527319242747999737801698427160817755293383890373574621116766934110792127739174475029121017282777887777,
publicExponent = 17,
privateExponent = 18832658619343853622211588088997845201745658451136447382185486691577805721584993260814073385267196632785528033211903435807948675951440868570007265441362261636545666919252206383477878125774454042314841278013741813438699754736973658909592256273895837054592950290554290654932740253882028017801960316533503857992358685308186680144968293076156011747178275038098868263178095174694099811498968993700538293188879611375604635940554394589807673542938082281934965292051746326331046224291377703201248790910007232374006151098976879987912446997911775904329728563222485791845480864283470332826504617837402078265424772379987120023773,
prime1 = 146807662748886761089048448970170315054939768171908279335181627815919052012991509112344782731265837727551849787333310044397991034789843793140419387740928103541736452627413492093463231242466386868459637115999163097726153692593711599245170083315894262154838974616739452594203727376460632750934355508361223110419,
prime2 = 145385325050081892763917667176962991350872697916072592966410309213561884732628046256782356731057378829876640317801978404203665761131810712267778698468684631707642938779964806354584156202882543264893826268426566901882487709510744074274965029453915224310656287149777603803201831202222853023280023478269485417083,
exponent1 = 51814469205489445090252393754177758254684624060673510353593515699736136004585238510239335081623236845018299924941168250963996835808180162284853901555621683602965806809675350150634081614988136541809283687999704622726877773856604093851236499993845033701707873394143336209718962603456693912094478414715725803677,
exponent2 = 51312467664734785681382706062457526359131540440966797517556579722433606376221663384746714140373192528191755406283051201483646739222992016094510128871300458249756331334105225772206172777487956446433115153562317730076172132768497908567634716277852432109643395464627389577600646306666889302334125933506877206029,
coefficient = 30504662229874176232343608562807118278893368758027179776313787938167236952567905398252901545019583024374163153775359371298239336609182249464886717948407152570850677549297935773605431024166978281486607154204888016179709037883348099374995148481968169438302456074511782717758301581202874062062542434218011141540,
otherPrimeInfos = asn1_NOVALUE};
hardcode_rsa_key(3) ->
#'RSAPrivateKey'{
version = 'two-prime',
modulus = 25089040456112869869472694987833070928503703615633809313972554887193090845137746668197820419383804666271752525807484521370419854590682661809972833718476098189250708650325307850184923546875260207894844301992963978994451844985784504212035958130279304082438876764367292331581532569155681984449177635856426023931875082020262146075451989132180409962870105455517050416234175675478291534563995772675388370042873175344937421148321291640477650173765084699931690748536036544188863178325887393475703801759010864779559318631816411493486934507417755306337476945299570726975433250753415110141783026008347194577506976486290259135429,
publicExponent = 17,
privateExponent = 8854955455098659953931539407470495621824836570223697404931489960185796768872145882893348383311931058684147950284994536954265831032005645344696294253579799360912014817761873358888796545955974191021709753644575521998041827642041589721895044045980930852625485916835514940558187965584358347452650930302268008446431977397918214293502821599497633970075862760001650736520566952260001423171553461362588848929781360590057040212831994258783694027013289053834376791974167294527043946669963760259975273650548116897900664646809242902841107022557239712438496384819445301703021164043324282687280801738470244471443835900160721870265,
prime1 = 171641816401041100605063917111691927706183918906535463031548413586331728772311589438043965564336865070070922328258143588739626712299625805650832695450270566547004154065267940032684307994238248203186986569945677705100224518137694769557564475390859269797990555863306972197736879644001860925483629009305104925823,
prime2 =146170909759497809922264016492088453282310383272504533061020897155289106805616042710009332510822455269704884883705830985184223718261139908416790475825625309815234508695722132706422885088219618698987115562577878897003573425367881351537506046253616435685549396767356003663417208105346307649599145759863108910523,
exponent1 = 60579464612132153154728441333538327425711971378777222246428851853999433684345266860486105493295364142377972586444050678378691780811632637288529186629507258781295583787741625893888579292084087601124818789392592131211843947578009918667375697196773859928702549128225990187436545756706539150170692591519448797349,
exponent2 = 137572620950115585809189662580789132500998007785886619351549079675566218169991569609420548245479957900898715184664311515467504676010484619686391036071176762179044243478326713135456833024206699951987873470661533079532774988581535389682358631768109586527575902839864474036157372334443583670210960715165278974609,
coefficient = 15068630434698373319269196003209754243798959461311186548759287649485250508074064775263867418602372588394608558985183294561315208336731894947137343239541687540387209051236354318837334154993136528453613256169847839789803932725339395739618592522865156272771578671216082079933457043120923342632744996962853951612,
otherPrimeInfos = asn1_NOVALUE};
hardcode_rsa_key(4) ->
#'RSAPrivateKey'{
version ='two-prime',
modulus = 28617237755030755643854803617273584643843067580642149032833640135949799721163782522787597288521902619948688786051081993247908700824196122780349730169173433743054172191054872553484065655968335396052034378669869864779940355219732200954630251223541048434478476115391643898092650304645086338265930608997389611376417609043761464100338332976874588396803891301015812818307951159858145399281035705713082131199940309445719678087542976246147777388465712394062188801177717719764254900022006288880246925156931391594131839991579403409541227225173269459173129377291869028712271737734702830877034334838181789916127814298794576266389,
publicExponent = 17,
privateExponent = 26933870828264240605980991639786903194205240075898493207372837775011576208154148256741268036255908348187001210401018346586267012540419880263858569570986761169933338532757527109161473558558433313931326474042230460969355628442100895016122589386862163232450330461545076609969553227901257730132640573174013751883368376011370428995523268034111482031427024082719896108094847702954695363285832195666458915142143884210891427766607838346722974883433132513540317964796373298134261669479023445911856492129270184781873446960437310543998533283339488055776892320162032014809906169940882070478200435536171854883284366514852906334641,
prime1 = 177342190816702392178883147766999616783253285436834252111702533617098994535049411784501174309695427674025956656849179054202187436663487378682303508229883753383891163725167367039879190685255046547908384208614573353917213168937832054054779266431207529839577747601879940934691505396807977946728204814969824442867,
prime2 = 161367340863680900415977542864139121629424927689088951345472941851682581254789586032968359551717004797621579428672968948552429138154521719743297455351687337112710712475376510559020211584326773715482918387500187602625572442687231345855402020688502483137168684570635690059254866684191216155909970061793538842967,
exponent1 = 62591361464718491357252875682470452982324688977706206627659717747211409835899792394529826226951327414362102349476180842659595565881230839534930649963488383547255704844176717778780890830090016428673547367746320007264898765507470136725216211681602657590439205035957626212244060728285168687080542875871702744541,
exponent2 = 28476589564178982426348978152495139111074987239250991413906989738532220221433456358759122273832412611344984605059935696803369847909621479954699550944415412431654831613301737157474154985469430655673456186029444871051571607533040825739188591886206320553618003159523945304574388238386685203984112363845918619347,
coefficient = 34340318160575773065401929915821192439103777558577109939078671096408836197675640654693301707202885840826672396546056002756167635035389371579540325327619480512374920136684787633921441576901246290213545161954865184290700344352088099063404416346968182170720521708773285279884132629954461545103181082503707725012,
otherPrimeInfos = asn1_NOVALUE};
hardcode_rsa_key(5) ->
#'RSAPrivateKey'{
version= 'two-prime',
modulus = 26363170152814518327068346871197765236382539835597898797762992537312221863402655353436079974302838986536256364057947538018476963115004626096654613827403121905035011992899481598437933532388248462251770039307078647864188314916665766359828262009578648593031111569685489178543405615478739906285223620987558499488359880003693226535420421293716164794046859453204135383236667988765227190694994861629971618548127529849059769249520775574008363789050621665120207265361610436965088511042779948238320901918522125988916609088415989475825860046571847719492980547438560049874493788767083330042728150253120940100665370844282489982633,
publicExponent = 17,
privateExponent = 10855423004100095781734025182257903332628104638187370093196526338893267826106975733767797636477639582691399679317978398007608161282648963686857782164224814902073240232370374775827384395689278778574258251479385325591136364965685903795223402003944149420659869469870495544106108194608892902588033255700759382142132115013969680562678811046675523365751498355532768935784747314021422035957153013494814430893022253205880275287307995039363642554998244274484818208792520243113824379110193356010059999642946040953102866271737127640405568982049887176990990501963784502429481034227543991366980671390566584211881030995602076468001,
prime1 =163564135568104310461344551909369650951960301778977149705601170951529791054750122905880591964737953456660497440730575925978769763154927541340839715938951226089095007207042122512586007411328664679011914120351043948122025612160733403945093961374276707993674792189646478659304624413958625254578122842556295400709,
prime2 = 161179405627326572739107057023381254841260287988433675196680483761672455172873134522398837271764104320975746111042211695289319249471386600030523328069395763313848583139553961129874895374324504709512019736703349829576024049432816885712623938437949550266365056310544300920756181033500610331519029869549723159637,
exponent1 = 115457036871603042678596154288966812436677860079277988027483179495197499568058910286503947269226790675289762899339230065396778656344654735064122152427494983121714122734382674714766593466820233891067233496718383963380253373289929461608301619793607087995535147427985749641862087821617853120878674947686796753441,
exponent2 = 142217122612346975946270932667689342506994371754500301644129838613240401623123353990351915239791856753802128921507833848784693455415929352968108818884760967629866396887841730408713142977345151214275311532385308673155315337734838428569962298621720191411498579097539089047726042088382891468987379296661520434973,
coefficient = 40624877259097915043489529504071755460170951428490878553842519165800720914888257733191322215286203357356050737713125202129282154441426952501134581314792133018830748896123382106683994268028624341502298766844710276939303555637478596035491641473828661569958212421472263269629366559343208764012473880251174832392,
otherPrimeInfos = asn1_NOVALUE};
hardcode_rsa_key(6) ->
#'RSAPrivateKey'{
version = 'two-prime',
modulus = 22748888494866396715768692484866595111939200209856056370972713870125588774286266397044592487895293134537316190976192161177144143633669641697309689280475257429554879273045671863645233402796222694405634510241820106743648116753479926387434021380537483429927516962909367257212902212159798399531316965145618774905828756510318897899298783143203190245236381440043169622358239226123652592179006905016804587837199618842875361941208299410035232803124113612082221121192550063791073372276763648926636149384299189072950588522522800393261949880796214514243704858378436010975184294077063518776479282353562934591448646412389762167039,
publicExponent = 17,
privateExponent = 6690849557313646092873144848490175032923294179369428344403739373566349639495960705013115437616262686628622409110644753287395336362844012263914614494257428655751435080307550548130951000822418439531068973600535325512837681398082331290421770994275730420566916753796872722709677121223470117509210872101652580854566448661533030419787125312956120661097410038933324613372774190658239039998357548275441758790939430824924502690997433186652165055694361752689819209062683281242276039100201318203707142383491769671330743466041394101421674581185260900666085723130684175548215193875544802254923825103844262661010117443222587769713,
prime1 = 164748737139489923768181260808494855987398781964531448608652166632780898215212977127034263859971474195908846263894581556691971503119888726148555271179103885786024920582830105413607436718060544856016793981261118694063993837665813285582095833772675610567592660039821387740255651489996976698808018635344299728063,
prime2 = 138082323967104548254375818343885141517788525705334488282154811252858957969378263753268344088034079842223206527922445018725900110643394926788280539200323021781309918753249061620424428562366627334409266756720941754364262467100514166396917565961434203543659974860389803369482625510495464845206228470088664021953,
exponent1 = 19382204369351755737433089506881747763223386113474288071606137250915399790025056132592266336467232258342217207517009594904937823896457497193947678962247515974826461245038835931012639613889475865413740468383661022831058098548919210068481862796785365949128548239978986792971253116470232552800943368864035262125,
exponent2 = 48734937870742781736838524121371226418043009072470995864289933383361985165662916618800592031070851709019955245149098241903258862580021738866451955011878713569874088971734962924855680669070574353320917678842685325069739694270769705787147376221682660074232932303666989424523279591939575827719845342384234360689,
coefficient = 81173034184183681160439870161505779100040258708276674532866007896310418779840630960490793104541748007902477778658270784073595697910785917474138815202903114440800310078464142273778315781957021015333260021813037604142367434117205299831740956310682461174553260184078272196958146289378701001596552915990080834227,
otherPrimeInfos = asn1_NOVALUE}.
hardcode_dsa_key(1) ->
{'DSAPrivateKey',0,
99438313664986922963487511141216248076486724382260996073922424025828494981416579966171753999204426907349400798052572573634137057487829150578821328280864500098312146772602202702021153757550650696224643730869835650674962433068943942837519621267815961566259265204876799778977478160416743037274938277357237615491,
1454908511695148818053325447108751926908854531909,
20302424198893709525243209250470907105157816851043773596964076323184805650258390738340248469444700378962907756890306095615785481696522324901068493502141775433048117442554163252381401915027666416630898618301033737438756165023568220631119672502120011809327566543827706483229480417066316015458225612363927682579,
48598545580251057979126570873881530215432219542526130654707948736559463436274835406081281466091739849794036308281564299754438126857606949027748889019480936572605967021944405048011118039171039273602705998112739400664375208228641666852589396502386172780433510070337359132965412405544709871654840859752776060358,
1457508827177594730669011716588605181448418352823};
hardcode_dsa_key(2) ->
#'DSAPrivateKey'{
version = 0,
p = 145447354557382582722944332987784622105075065624518040072393858097520305927329240484963764783346271194321683798321743658303478090647837211867389721684646254999291098347011037298359107547264573476540026676832159205689428125157386525591130716464335426605521884822982379206842523670736739023467072341958074788151,
q = 742801637799670234315651916144768554943688916729,
g = 79727684678125120155622004643594683941478642656111969487719464672433839064387954070113655822700268007902716505761008423792735229036965034283173483862273639257533568978482104785033927768441235063983341565088899599358397638308472931049309161811156189887217888328371767967629005149630676763492409067382020352505,
y = 35853727034965131665219275925554159789667905059030049940938124723126925435403746979702929280654735557166864135215989313820464108440192507913554896358611966877432546584986661291483639036057475682547385322659469460385785257933737832719745145778223672383438466035853830832837226950912832515496378486927322864228,
x = 801315110178350279541885862867982846569980443911};
hardcode_dsa_key(3) ->
#'DSAPrivateKey'{
version = 0,
p = 99438313664986922963487511141216248076486724382260996073922424025828494981416579966171753999204426907349400798052572573634137057487829150578821328280864500098312146772602202702021153757550650696224643730869835650674962433068943942837519621267815961566259265204876799778977478160416743037274938277357237615491,
q = 1454908511695148818053325447108751926908854531909,
g = 20302424198893709525243209250470907105157816851043773596964076323184805650258390738340248469444700378962907756890306095615785481696522324901068493502141775433048117442554163252381401915027666416630898618301033737438756165023568220631119672502120011809327566543827706483229480417066316015458225612363927682579,
y = 48598545580251057979126570873881530215432219542526130654707948736559463436274835406081281466091739849794036308281564299754438126857606949027748889019480936572605967021944405048011118039171039273602705998112739400664375208228641666852589396502386172780433510070337359132965412405544709871654840859752776060358,
x = 1457508827177594730669011716588605181448418352823}.