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;/*
* TLS Hello Request and Client Hello Messages
* (C) 2004-2011 Jack Lloyd
*
* Released under the terms of the Botan license
*/
#include <botan/internal/tls_messages.h>
#include <botan/internal/tls_reader.h>
#include <botan/internal/tls_session_key.h>
#include <botan/internal/tls_extensions.h>
#include <botan/tls_record.h>
#include <botan/internal/stl_util.h>
namespace Botan {
/*
* Encode and send a Handshake message
*/
void Handshake_Message::send(Record_Writer& writer, TLS_Handshake_Hash& hash) const
{
MemoryVector<byte> buf = serialize();
MemoryVector<byte> send_buf(4);
const size_t buf_size = buf.size();
send_buf[0] = type();
for(size_t i = 1; i != 4; ++i)
send_buf[i] = get_byte<u32bit>(i, buf_size);
send_buf += buf;
hash.update(send_buf);
writer.send(HANDSHAKE, &send_buf[0], send_buf.size());
}
/*
* Create a new Hello Request message
*/
Hello_Request::Hello_Request(Record_Writer& writer)
{
TLS_Handshake_Hash dummy; // FIXME: *UGLY*
send(writer, dummy);
}
/*
* Serialize a Hello Request message
*/
MemoryVector<byte> Hello_Request::serialize() const
{
return MemoryVector<byte>();
}
/*
* Deserialize a Hello Request message
*/
void Hello_Request::deserialize(const MemoryRegion<byte>& buf)
{
if(buf.size())
throw Decoding_Error("Hello_Request: Must be empty, and is not");
}
/*
* Create a new Client Hello message
*/
Client_Hello::Client_Hello(Record_Writer& writer,
TLS_Handshake_Hash& hash,
const TLS_Policy& policy,
RandomNumberGenerator& rng,
const MemoryRegion<byte>& reneg_info,
bool next_protocol,
const std::string& hostname,
const std::string& srp_identifier) :
m_version(policy.pref_version()),
m_random(rng.random_vec(32)),
m_suites(policy.ciphersuites(srp_identifier != "")),
m_comp_methods(policy.compression()),
m_hostname(hostname),
m_srp_identifier(srp_identifier),
m_next_protocol(next_protocol),
m_fragment_size(0),
m_secure_renegotiation(true),
m_renegotiation_info(reneg_info)
{
send(writer, hash);
}
/*
* Create a new Client Hello message
*/
Client_Hello::Client_Hello(Record_Writer& writer,
TLS_Handshake_Hash& hash,
RandomNumberGenerator& rng,
const TLS_Session& session,
bool next_protocol) :
m_version(session.version()),
m_session_id(session.session_id()),
m_random(rng.random_vec(32)),
m_hostname(session.sni_hostname()),
m_srp_identifier(session.srp_identifier()),
m_next_protocol(next_protocol),
m_fragment_size(session.fragment_size()),
m_secure_renegotiation(session.secure_renegotiation())
{
m_suites.push_back(session.ciphersuite());
m_comp_methods.push_back(session.compression_method());
send(writer, hash);
}
/*
* Serialize a Client Hello message
*/
MemoryVector<byte> Client_Hello::serialize() const
{
MemoryVector<byte> buf;
buf.push_back(static_cast<byte>(m_version >> 8));
buf.push_back(static_cast<byte>(m_version ));
buf += m_random;
append_tls_length_value(buf, m_session_id, 1);
append_tls_length_value(buf, m_suites, 2);
append_tls_length_value(buf, m_comp_methods, 1);
/*
* May not want to send extensions at all in some cases.
* If so, should include SCSV value (if reneg info is empty, if
* not we are renegotiating with a modern server and should only
* send that extension.
*/
TLS_Extensions extensions;
// Initial handshake
if(m_renegotiation_info.empty())
{
extensions.push_back(new Renegotation_Extension(m_renegotiation_info));
extensions.push_back(new Server_Name_Indicator(m_hostname));
extensions.push_back(new SRP_Identifier(m_srp_identifier));
if(m_next_protocol)
extensions.push_back(new Next_Protocol_Negotiation());
}
else
{
// renegotiation
extensions.push_back(new Renegotation_Extension(m_renegotiation_info));
}
buf += extensions.serialize();
return buf;
}
void Client_Hello::deserialize_sslv2(const MemoryRegion<byte>& buf)
{
if(buf.size() < 12 || buf[0] != 1)
throw Decoding_Error("Client_Hello: SSLv2 hello corrupted");
const size_t cipher_spec_len = make_u16bit(buf[3], buf[4]);
const size_t m_session_id_len = make_u16bit(buf[5], buf[6]);
const size_t challenge_len = make_u16bit(buf[7], buf[8]);
const size_t expected_size =
(9 + m_session_id_len + cipher_spec_len + challenge_len);
if(buf.size() != expected_size)
throw Decoding_Error("Client_Hello: SSLv2 hello corrupted");
if(m_session_id_len != 0 || cipher_spec_len % 3 != 0 ||
(challenge_len < 16 || challenge_len > 32))
{
throw Decoding_Error("Client_Hello: SSLv2 hello corrupted");
}
for(size_t i = 9; i != 9 + cipher_spec_len; i += 3)
{
if(buf[i] != 0) // a SSLv2 cipherspec; ignore it
continue;
m_suites.push_back(make_u16bit(buf[i+1], buf[i+2]));
}
m_version = static_cast<Version_Code>(make_u16bit(buf[1], buf[2]));
m_random.resize(challenge_len);
copy_mem(&m_random[0], &buf[9+cipher_spec_len+m_session_id_len], challenge_len);
m_secure_renegotiation =
value_exists(m_suites, static_cast<u16bit>(TLS_EMPTY_RENEGOTIATION_INFO_SCSV));
m_fragment_size = 0;
m_next_protocol = false;
}
/*
* Deserialize a Client Hello message
*/
void Client_Hello::deserialize(const MemoryRegion<byte>& buf)
{
if(buf.size() == 0)
throw Decoding_Error("Client_Hello: Packet corrupted");
if(buf.size() < 41)
throw Decoding_Error("Client_Hello: Packet corrupted");
TLS_Data_Reader reader(buf);
m_version = static_cast<Version_Code>(reader.get_u16bit());
m_random = reader.get_fixed<byte>(32);
m_session_id = reader.get_range<byte>(1, 0, 32);
m_suites = reader.get_range_vector<u16bit>(2, 1, 32767);
m_comp_methods = reader.get_range_vector<byte>(1, 1, 255);
m_next_protocol = false;
m_secure_renegotiation = false;
m_fragment_size = 0;
TLS_Extensions extensions(reader);
for(size_t i = 0; i != extensions.count(); ++i)
{
TLS_Extension* extn = extensions.at(i);
if(Server_Name_Indicator* sni = dynamic_cast<Server_Name_Indicator*>(extn))
{
m_hostname = sni->host_name();
}
else if(SRP_Identifier* srp = dynamic_cast<SRP_Identifier*>(extn))
{
m_srp_identifier = srp->identifier();
}
else if(Next_Protocol_Negotiation* npn = dynamic_cast<Next_Protocol_Negotiation*>(extn))
{
if(!npn->protocols().empty())
throw Decoding_Error("Client sent non-empty NPN extension");
m_next_protocol = true;
}
else if(Maximum_Fragment_Length* frag = dynamic_cast<Maximum_Fragment_Length*>(extn))
{
m_fragment_size = frag->fragment_size();
}
else if(Renegotation_Extension* reneg = dynamic_cast<Renegotation_Extension*>(extn))
{
// checked by TLS_Client / TLS_Server as they know the handshake state
m_secure_renegotiation = true;
m_renegotiation_info = reneg->renegotiation_info();
}
}
if(value_exists(m_suites, static_cast<u16bit>(TLS_EMPTY_RENEGOTIATION_INFO_SCSV)))
{
/*
* Clients are allowed to send both the extension and the SCSV
* though it is not recommended. If it did, require that the
* extension value be empty.
*/
if(m_secure_renegotiation)
{
if(!m_renegotiation_info.empty())
{
throw TLS_Exception(HANDSHAKE_FAILURE,
"Client send SCSV and non-empty extension");
}
}
m_secure_renegotiation = true;
m_renegotiation_info.clear();
}
}
/*
* Check if we offered this ciphersuite
*/
bool Client_Hello::offered_suite(u16bit ciphersuite) const
{
for(size_t i = 0; i != m_suites.size(); ++i)
if(m_suites[i] == ciphersuite)
return true;
return false;
}
}
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