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/*
* TLS Handshaking
* (C) 2004-2006,2011,2012,2015,2016 Jack Lloyd
* 2017 Harry Reimann, Rohde & Schwarz Cybersecurity
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#include <botan/internal/tls_handshake_state.h>
#include <botan/internal/tls_record.h>
#include <botan/tls_messages.h>
#include <botan/kdf.h>
#include <sstream>
namespace Botan {
namespace TLS {
std::string Handshake_Message::type_string() const
{
return handshake_type_to_string(type());
}
const char* handshake_type_to_string(Handshake_Type type)
{
switch(type)
{
case HELLO_VERIFY_REQUEST:
return "hello_verify_request";
case HELLO_REQUEST:
return "hello_request";
case CLIENT_HELLO:
return "client_hello";
case SERVER_HELLO:
return "server_hello";
case CERTIFICATE:
return "certificate";
case CERTIFICATE_URL:
return "certificate_url";
case CERTIFICATE_STATUS:
return "certificate_status";
case SERVER_KEX:
return "server_key_exchange";
case CERTIFICATE_REQUEST:
return "certificate_request";
case SERVER_HELLO_DONE:
return "server_hello_done";
case CERTIFICATE_VERIFY:
return "certificate_verify";
case CLIENT_KEX:
return "client_key_exchange";
case NEW_SESSION_TICKET:
return "new_session_ticket";
case HANDSHAKE_CCS:
return "change_cipher_spec";
case FINISHED:
return "finished";
case HANDSHAKE_NONE:
return "invalid";
}
throw TLS_Exception(Alert::UNEXPECTED_MESSAGE,
"Unknown TLS handshake message type " + std::to_string(type));
}
namespace {
uint32_t bitmask_for_handshake_type(Handshake_Type type)
{
switch(type)
{
case HELLO_VERIFY_REQUEST:
return (1 << 0);
case HELLO_REQUEST:
return (1 << 1);
case CLIENT_HELLO:
return (1 << 2);
case SERVER_HELLO:
return (1 << 3);
case CERTIFICATE:
return (1 << 4);
case CERTIFICATE_URL:
return (1 << 5);
case CERTIFICATE_STATUS:
return (1 << 6);
case SERVER_KEX:
return (1 << 7);
case CERTIFICATE_REQUEST:
return (1 << 8);
case SERVER_HELLO_DONE:
return (1 << 9);
case CERTIFICATE_VERIFY:
return (1 << 10);
case CLIENT_KEX:
return (1 << 11);
case NEW_SESSION_TICKET:
return (1 << 12);
case HANDSHAKE_CCS:
return (1 << 13);
case FINISHED:
return (1 << 14);
// allow explicitly disabling new handshakes
case HANDSHAKE_NONE:
return 0;
}
throw TLS_Exception(Alert::UNEXPECTED_MESSAGE,
"Unknown TLS handshake message type " + std::to_string(type));
}
std::string handshake_mask_to_string(uint32_t mask)
{
const Handshake_Type types[] = {
HELLO_VERIFY_REQUEST,
HELLO_REQUEST,
CLIENT_HELLO,
CERTIFICATE,
CERTIFICATE_URL,
CERTIFICATE_STATUS,
SERVER_KEX,
CERTIFICATE_REQUEST,
SERVER_HELLO_DONE,
CERTIFICATE_VERIFY,
CLIENT_KEX,
NEW_SESSION_TICKET,
HANDSHAKE_CCS,
FINISHED
};
std::ostringstream o;
bool empty = true;
for(auto&& t : types)
{
if(mask & bitmask_for_handshake_type(t))
{
if(!empty)
o << ",";
o << handshake_type_to_string(t);
empty = false;
}
}
return o.str();
}
}
/*
* Initialize the SSL/TLS Handshake State
*/
Handshake_State::Handshake_State(Handshake_IO* io, Callbacks& cb) :
m_callbacks(cb),
m_handshake_io(io),
m_version(m_handshake_io->initial_record_version())
{
}
void Handshake_State::note_message(const Handshake_Message& msg)
{
m_callbacks.tls_inspect_handshake_msg(msg);
}
void Handshake_State::hello_verify_request(const Hello_Verify_Request& hello_verify)
{
note_message(hello_verify);
m_client_hello->update_hello_cookie(hello_verify);
hash().reset();
hash().update(handshake_io().send(*m_client_hello));
note_message(*m_client_hello);
}
void Handshake_State::client_hello(Client_Hello* client_hello)
{
m_client_hello.reset(client_hello);
note_message(*m_client_hello);
}
void Handshake_State::server_hello(Server_Hello* server_hello)
{
m_server_hello.reset(server_hello);
m_ciphersuite = Ciphersuite::by_id(m_server_hello->ciphersuite());
note_message(*m_server_hello);
}
void Handshake_State::server_certs(Certificate* server_certs)
{
m_server_certs.reset(server_certs);
note_message(*m_server_certs);
}
void Handshake_State::server_cert_status(Certificate_Status* server_cert_status)
{
m_server_cert_status.reset(server_cert_status);
note_message(*m_server_cert_status);
}
void Handshake_State::server_kex(Server_Key_Exchange* server_kex)
{
m_server_kex.reset(server_kex);
note_message(*m_server_kex);
}
void Handshake_State::cert_req(Certificate_Req* cert_req)
{
m_cert_req.reset(cert_req);
note_message(*m_cert_req);
}
void Handshake_State::server_hello_done(Server_Hello_Done* server_hello_done)
{
m_server_hello_done.reset(server_hello_done);
note_message(*m_server_hello_done);
}
void Handshake_State::client_certs(Certificate* client_certs)
{
m_client_certs.reset(client_certs);
note_message(*m_client_certs);
}
void Handshake_State::client_kex(Client_Key_Exchange* client_kex)
{
m_client_kex.reset(client_kex);
note_message(*m_client_kex);
}
void Handshake_State::client_verify(Certificate_Verify* client_verify)
{
m_client_verify.reset(client_verify);
note_message(*m_client_verify);
}
void Handshake_State::new_session_ticket(New_Session_Ticket* new_session_ticket)
{
m_new_session_ticket.reset(new_session_ticket);
note_message(*m_new_session_ticket);
}
void Handshake_State::server_finished(Finished* server_finished)
{
m_server_finished.reset(server_finished);
note_message(*m_server_finished);
}
void Handshake_State::client_finished(Finished* client_finished)
{
m_client_finished.reset(client_finished);
note_message(*m_client_finished);
}
void Handshake_State::set_version(const Protocol_Version& version)
{
m_version = version;
}
void Handshake_State::compute_session_keys()
{
m_session_keys = Session_Keys(this, client_kex()->pre_master_secret(), false);
}
void Handshake_State::compute_session_keys(const secure_vector<uint8_t>& resume_master_secret)
{
m_session_keys = Session_Keys(this, resume_master_secret, true);
}
void Handshake_State::confirm_transition_to(Handshake_Type handshake_msg)
{
const uint32_t mask = bitmask_for_handshake_type(handshake_msg);
m_hand_received_mask |= mask;
const bool ok = (m_hand_expecting_mask & mask) != 0; // overlap?
if(!ok)
throw Unexpected_Message("Unexpected state transition in handshake, got type " +
std::to_string(handshake_msg) +
" expected " + handshake_mask_to_string(m_hand_expecting_mask) +
" received " + handshake_mask_to_string(m_hand_received_mask));
/* We don't know what to expect next, so force a call to
set_expected_next; if it doesn't happen, the next transition
check will always fail which is what we want.
*/
m_hand_expecting_mask = 0;
}
void Handshake_State::set_expected_next(Handshake_Type handshake_msg)
{
m_hand_expecting_mask |= bitmask_for_handshake_type(handshake_msg);
}
bool Handshake_State::received_handshake_msg(Handshake_Type handshake_msg) const
{
const uint32_t mask = bitmask_for_handshake_type(handshake_msg);
return (m_hand_received_mask & mask) != 0;
}
std::pair<Handshake_Type, std::vector<uint8_t>>
Handshake_State::get_next_handshake_msg()
{
const bool expecting_ccs =
(bitmask_for_handshake_type(HANDSHAKE_CCS) & m_hand_expecting_mask) != 0;
return m_handshake_io->get_next_record(expecting_ccs);
}
std::string Handshake_State::srp_identifier() const
{
#if defined(BOTAN_HAS_SRP6)
// Authenticated via the successful key exchange
if(ciphersuite().valid() && ciphersuite().kex_method() == Kex_Algo::SRP_SHA)
return client_hello()->srp_identifier();
#endif
return "";
}
std::vector<uint8_t> Handshake_State::session_ticket() const
{
if(new_session_ticket() && !new_session_ticket()->ticket().empty())
return new_session_ticket()->ticket();
return client_hello()->session_ticket();
}
KDF* Handshake_State::protocol_specific_prf() const
{
if(version().supports_ciphersuite_specific_prf())
{
const std::string prf_algo = ciphersuite().prf_algo();
if(prf_algo == "MD5" || prf_algo == "SHA-1")
return get_kdf("TLS-12-PRF(SHA-256)");
return get_kdf("TLS-12-PRF(" + prf_algo + ")");
}
// Old PRF used in TLS v1.0, v1.1 and DTLS v1.0
return get_kdf("TLS-PRF");
}
std::pair<std::string, Signature_Format>
Handshake_State::choose_sig_format(const Private_Key& key,
Signature_Scheme& chosen_scheme,
bool for_client_auth,
const Policy& policy) const
{
const std::string sig_algo = key.algo_name();
if(this->version().supports_negotiable_signature_algorithms())
{
const std::vector<Signature_Scheme> allowed = policy.allowed_signature_schemes();
std::vector<Signature_Scheme> schemes =
(for_client_auth) ? cert_req()->signature_schemes() : client_hello()->signature_schemes();
if(schemes.empty())
{
// Implicit SHA-1
schemes.push_back(Signature_Scheme::RSA_PKCS1_SHA1);
schemes.push_back(Signature_Scheme::ECDSA_SHA1);
schemes.push_back(Signature_Scheme::DSA_SHA1);
}
for(Signature_Scheme scheme : schemes)
{
if(signature_scheme_is_known(scheme) == false)
{
continue;
}
if(signature_algorithm_of_scheme(scheme) == sig_algo)
{
if(std::find(allowed.begin(), allowed.end(), scheme) != allowed.end())
{
chosen_scheme = scheme;
break;
}
}
}
const std::string hash = hash_function_of_scheme(chosen_scheme);
if(!policy.allowed_signature_hash(hash))
{
throw TLS_Exception(Alert::HANDSHAKE_FAILURE,
"Policy refuses to accept signing with any hash supported by peer");
}
if(sig_algo == "RSA")
{
return std::make_pair(padding_string_for_scheme(chosen_scheme), IEEE_1363);
}
else if(sig_algo == "DSA" || sig_algo == "ECDSA")
{
return std::make_pair(padding_string_for_scheme(chosen_scheme), DER_SEQUENCE);
}
}
else
{
if(sig_algo == "RSA")
{
const std::string padding = "PKCS1v15(Parallel(MD5,SHA-160))";
return std::make_pair(padding, IEEE_1363);
}
else if(sig_algo == "DSA" || sig_algo == "ECDSA")
{
const std::string padding = "EMSA1(SHA-1)";
return std::make_pair(padding, DER_SEQUENCE);
}
}
throw Invalid_Argument(sig_algo + " is invalid/unknown for TLS signatures");
}
namespace {
bool supported_algos_include(
const std::vector<Signature_Scheme>& schemes,
const std::string& key_type,
const std::string& hash_type)
{
for(Signature_Scheme scheme : schemes)
{
if(signature_scheme_is_known(scheme) &&
hash_function_of_scheme(scheme) == hash_type &&
signature_algorithm_of_scheme(scheme) == key_type)
{
return true;
}
}
return false;
}
}
std::pair<std::string, Signature_Format>
Handshake_State::parse_sig_format(const Public_Key& key,
Signature_Scheme scheme,
bool for_client_auth,
const Policy& policy) const
{
const std::string key_type = key.algo_name();
if(!policy.allowed_signature_method(key_type))
{
throw TLS_Exception(Alert::HANDSHAKE_FAILURE,
"Rejecting " + key_type + " signature");
}
if(this->version().supports_negotiable_signature_algorithms() == false)
{
if(scheme != Signature_Scheme::NONE)
throw Decoding_Error("Counterparty sent hash/sig IDs with old version");
/*
There is no check on the acceptability of a v1.0/v1.1 hash type,
since it's implicit with use of the protocol
*/
if(key_type == "RSA")
{
const std::string padding = "PKCS1v15(Parallel(MD5,SHA-160))";
return std::make_pair(padding, IEEE_1363);
}
else if(key_type == "DSA" || key_type == "ECDSA")
{
const std::string padding = "EMSA1(SHA-1)";
return std::make_pair(padding, DER_SEQUENCE);
}
else
throw Invalid_Argument(key_type + " is invalid/unknown for TLS signatures");
}
if(scheme == Signature_Scheme::NONE)
throw Decoding_Error("Counterparty did not send hash/sig IDS");
if(key_type != signature_algorithm_of_scheme(scheme))
throw Decoding_Error("Counterparty sent inconsistent key and sig types");
if(for_client_auth && !cert_req())
{
throw TLS_Exception(Alert::HANDSHAKE_FAILURE,
"No certificate verify set");
}
/*
Confirm the signature type we just received against the
supported_algos list that we sent; it better be there.
*/
const std::vector<Signature_Scheme> supported_algos =
for_client_auth ? cert_req()->signature_schemes() :
client_hello()->signature_schemes();
const std::string hash_algo = hash_function_of_scheme(scheme);
if(!supported_algos_include(supported_algos, key_type, hash_algo))
{
throw TLS_Exception(Alert::HANDSHAKE_FAILURE,
"TLS signature extension did not allow for " +
key_type + "/" + hash_algo + " signature");
}
if(key_type == "RSA")
{
return std::make_pair(padding_string_for_scheme(scheme), IEEE_1363);
}
else if(key_type == "DSA" || key_type == "ECDSA")
{
return std::make_pair(padding_string_for_scheme(scheme), DER_SEQUENCE);
}
throw Invalid_Argument(key_type + " is invalid/unknown for TLS signatures");
}
}
}
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