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protostack.hpp
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protostack.hpp
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// OpenVPN -- An application to securely tunnel IP networks
// over a single port, with support for SSL/TLS-based
// session authentication and key exchange,
// packet encryption, packet authentication, and
// packet compression.
//
// Copyright (C) 2012- OpenVPN Inc.
//
// SPDX-License-Identifier: MPL-2.0 OR AGPL-3.0-only WITH openvpn3-openssl-exception
//
#ifndef OPENVPN_SSL_PROTOSTACK_H
#define OPENVPN_SSL_PROTOSTACK_H
#include <deque>
#include <utility>
#include <openvpn/common/exception.hpp>
#include <openvpn/common/size.hpp>
#include <openvpn/common/usecount.hpp>
#include <openvpn/buffer/buffer.hpp>
#include <openvpn/time/time.hpp>
#include <openvpn/log/sessionstats.hpp>
#include <openvpn/reliable/relrecv.hpp>
#include <openvpn/reliable/relsend.hpp>
#include <openvpn/reliable/relack.hpp>
#include <openvpn/frame/frame.hpp>
#include <openvpn/error/excode.hpp>
#include <openvpn/ssl/sslconsts.hpp>
#include <openvpn/ssl/sslapi.hpp>
// ProtoStackBase is designed to allow general-purpose protocols (including
// but not limited to OpenVPN) to run over SSL, where the underlying transport
// layer is unreliable, such as UDP. The OpenVPN protocol implementation in
// proto.hpp (ProtoContext) layers on top of ProtoStackBase.
// ProtoStackBase is independent of any particular SSL implementation, and
// accepts the SSL object type as a template parameter.
namespace openvpn {
// PACKET type must define the following methods:
//
// Default constructor:
// PACKET()
//
// Constructor for BufferPtr:
// explicit PACKET(const BufferPtr& buf)
//
// Return cloned packet, including cloned buffer content:
// PACKET clone() const
//
// Test if defined:
// operator bool() const
//
// Return false if packet is raw, or true if packet is SSL ciphertext:
// bool contains_tls_ciphertext() const
//
// Reset back to post-default-constructor state:
// void reset()
//
// Return internal BufferPtr:
// const BufferPtr& buffer_ptr() const
//
// Call frame.prepare on internal buffer:
// void frame_prepare(const Frame& frame, const unsigned int context)
template <typename PACKET, typename PARENT>
class ProtoStackBase
{
public:
static constexpr size_t ovpn_sending_window = 6;
static constexpr size_t ovpn_receiving_window = ReliableAck::maximum_acks_ack_v1;
typedef reliable::id_t id_t;
typedef ReliableSendTemplate<PACKET> ReliableSend;
typedef ReliableRecvTemplate<PACKET> ReliableRecv;
OPENVPN_SIMPLE_EXCEPTION(proto_stack_invalidated);
OPENVPN_SIMPLE_EXCEPTION(unknown_status_from_ssl_layer);
enum NetSendType
{
NET_SEND_SSL,
NET_SEND_RAW,
NET_SEND_ACK,
NET_SEND_RETRANSMIT,
};
ProtoStackBase(SSLFactoryAPI &ssl_factory, // SSL factory object that can be used to generate new SSL sessions
TimePtr now_arg, // pointer to current time
const Time::Duration &tls_timeout_arg, // packet retransmit timeout
const Frame::Ptr &frame, // contains info on how to allocate and align buffers
const SessionStats::Ptr &stats_arg, // error statistics
bool psid_cookie_mode) // start the reliability layer at packet id 1, not 0
: tls_timeout(tls_timeout_arg),
ssl_(ssl_factory.ssl()),
frame_(frame),
stats(stats_arg),
now(now_arg),
rel_recv(ovpn_receiving_window, psid_cookie_mode ? 1 : 0),
rel_send(ovpn_sending_window, psid_cookie_mode ? 1 : 0)
{
}
// Start SSL handshake on underlying SSL connection object.
void start_handshake()
{
if (!invalidated())
{
ssl_->start_handshake();
ssl_started_ = true;
up_sequenced();
}
}
uint32_t get_tls_warnings() const
{
return ssl_->get_tls_warnings();
}
// Incoming ciphertext packet arriving from network,
// we will take ownership of pkt.
bool net_recv(PACKET &&pkt)
{
if (!invalidated())
return up_stack(pkt);
return false;
}
// Outgoing application-level cleartext packet ready to send
// (will be encrypted via SSL), we will take ownership
// of buf.
void app_send(BufferPtr &&buf)
{
if (!invalidated())
app_write_queue.push_back(std::move(buf));
}
// Outgoing raw packet ready to send (will NOT be encrypted
// via SSL, but will still be encapsulated, sequentialized,
// and tracked via reliability layer).
void raw_send(PACKET &&pkt)
{
if (!invalidated())
raw_write_queue.push_back(std::move(pkt));
}
// Write any pending data to network and update retransmit
// timer. Should be called as a final step after one or more
// net_recv, app_send, raw_send, or start_handshake calls.
void flush()
{
if (!invalidated() && !up_stack_reentry_level)
{
down_stack_raw();
down_stack_app();
update_retransmit();
}
}
// Send pending ACKs back to sender for packets already received
void send_pending_acks()
{
if (!invalidated())
{
while (!xmit_acks.empty())
{
ack_send_buf.frame_prepare(*frame_, Frame::WRITE_ACK_STANDALONE);
// encapsulate standalone ACK
parent().generate_ack(ack_send_buf);
// transmit it
parent().net_send(ack_send_buf, NET_SEND_ACK);
}
}
}
// Send any pending retransmissions
void retransmit()
{
if (!invalidated() && *now >= next_retransmit_)
{
for (id_t i = rel_send.head_id(); i < rel_send.tail_id(); ++i)
{
typename ReliableSend::Message &m = rel_send.ref_by_id(i);
if (m.ready_retransmit(*now))
{
// preserve original packet non-encapsulated
PACKET pkt = m.packet.clone();
// encapsulate packet
try
{
parent().encapsulate(m.id(), pkt);
}
catch (...)
{
error(Error::ENCAPSULATION_ERROR);
throw;
}
parent().net_send(pkt, NET_SEND_RETRANSMIT);
m.reset_retransmit(*now, tls_timeout);
}
}
update_retransmit();
}
}
// When should we next call retransmit()
Time next_retransmit() const
{
if (!invalidated())
return next_retransmit_;
else
return Time::infinite();
}
// Has SSL handshake been started yet?
bool ssl_started() const
{
return ssl_started_;
}
// Was session invalidated by an exception?
bool invalidated() const
{
return invalidated_;
}
// Reason for invalidation
Error::Type invalidation_reason() const
{
return invalidation_reason_;
}
// Invalidate session
void invalidate(const Error::Type reason)
{
if (!invalidated_)
{
invalidated_ = true;
invalidation_reason_ = reason;
parent().invalidate_callback();
}
}
std::string ssl_handshake_details() const
{
return ssl_->ssl_handshake_details();
}
void export_key_material(OpenVPNStaticKey &key, const std::string &label) const
{
if (!ssl_->export_keying_material(label, key.raw_alloc(), OpenVPNStaticKey::KEY_SIZE))
throw ErrorCode(Error::KEY_EXPANSION_ERROR, true, "TLS Keying material export error");
}
const AuthCert::Ptr &auth_cert() const
{
return ssl_->auth_cert();
}
private:
// Parent methods -- derived class must define these methods
// Encapsulate packet, use id as sequence number. If xmit_acks is non-empty,
// try to piggy-back ACK replies from xmit_acks to sender in encapsulated
// packet. Any exceptions thrown will invalidate session, i.e. this object
// can no longer be used.
//
// void encapsulate(id_t id, PACKET& pkt) = 0;
// Perform integrity check on packet. If packet is good, unencapsulate it and
// pass it into the rel_recv object. Any ACKs received for messages previously
// sent should be marked in rel_send. Message sequence number should be recorded
// in xmit_acks. Exceptions may be thrown here and they will be passed up to
// caller of net_recv and will not invalidate the session.
// Method should return true if packet was placed into rel_recv.
//
// bool decapsulate(PACKET& pkt) = 0;
// Generate a standalone ACK message in buf based on ACKs in xmit_acks
// (PACKET will be already be initialized by frame_prepare()).
//
// void generate_ack(PACKET& pkt) = 0;
// Transmit encapsulated ciphertext packet to peer. Method may not modify
// or take ownership of net_pkt or underlying data unless it copies it.
//
// void net_send(const PACKET& net_pkt, const NetSendType nstype) = 0;
// Pass cleartext data up to application, which make take
// ownership of to_app_buf via std::move.
//
// void app_recv(BufferPtr&& to_app_buf) = 0;
// Pass raw data up to application. A packet is considered to be raw
// if is_raw() method returns true. Method may take ownership
// of raw_pkt via std::move.
//
// void raw_recv(PACKET&& raw_pkt) = 0;
// called if session is invalidated by an error (optional)
//
// void invalidate_callback() {}
// END of parent methods
// get reference to parent for CRTP
PARENT &parent()
{
return *static_cast<PARENT *>(this);
}
// app data -> SSL -> protocol encapsulation -> reliability layer -> network
void down_stack_app()
{
if (ssl_started_)
{
// push app-layer cleartext through SSL object
while (!app_write_queue.empty())
{
BufferPtr &buf = app_write_queue.front();
ssize_t size;
try
{
size = ssl_->write_cleartext_unbuffered(buf->data(), buf->size());
}
catch (...)
{
error(Error::SSL_ERROR);
throw;
}
if (size == static_cast<ssize_t>(buf->size()))
app_write_queue.pop_front();
else if (size == SSLConst::SHOULD_RETRY)
break;
else if (size >= 0)
{
// partial write
app_write_queue.front()->advance(size);
break;
}
else
{
error(Error::SSL_ERROR);
throw unknown_status_from_ssl_layer();
}
}
// encapsulate SSL ciphertext packets
while (ssl_->read_ciphertext_ready() && rel_send.ready())
{
typename ReliableSend::Message &m = rel_send.send(*now, tls_timeout);
m.packet = PACKET(ssl_->read_ciphertext());
// encapsulate and send cloned packet, preserve original one for retransmit
PACKET pkt = m.packet.clone();
// encapsulate packet
try
{
parent().encapsulate(m.id(), pkt);
}
catch (...)
{
error(Error::ENCAPSULATION_ERROR);
throw;
}
// transmit it
parent().net_send(pkt, NET_SEND_SSL);
}
}
}
// raw app data -> protocol encapsulation -> reliability layer -> network
void down_stack_raw()
{
while (!raw_write_queue.empty() && rel_send.ready())
{
typename ReliableSend::Message &m = rel_send.send(*now, tls_timeout);
m.packet = raw_write_queue.front();
raw_write_queue.pop_front();
PACKET pkt = m.packet.clone();
// encapsulate packet
try
{
parent().encapsulate(m.id(), pkt);
}
catch (...)
{
error(Error::ENCAPSULATION_ERROR);
throw;
}
// transmit it
parent().net_send(pkt, NET_SEND_RAW);
}
}
// network -> reliability layer -> protocol decapsulation -> SSL -> app
bool up_stack(PACKET &recv)
{
UseCount use_count(up_stack_reentry_level);
if (parent().decapsulate(recv))
{
up_sequenced();
return true;
}
else
return false;
}
// if a sequenced packet is available from reliability layer,
// move it up the stack
void up_sequenced()
{
// is sequenced receive packet available?
while (rel_recv.ready())
{
typename ReliableRecv::Message &m = rel_recv.next_sequenced();
if (!m.packet.contains_tls_ciphertext())
parent().raw_recv(std::move(m.packet));
else // SSL packet
{
if (ssl_started_)
ssl_->write_ciphertext(m.packet.buffer_ptr());
else
break;
}
rel_recv.advance();
}
// read cleartext data from SSL object
if (ssl_started_)
while (ssl_->read_cleartext_ready())
{
ssize_t size;
to_app_buf = BufferAllocatedRc::Create();
frame_->prepare(Frame::READ_SSL_CLEARTEXT, *to_app_buf);
try
{
size = ssl_->read_cleartext(to_app_buf->data(), to_app_buf->max_size());
}
catch (...)
{
// SSL fatal errors will invalidate the session
error(Error::SSL_ERROR);
throw;
}
if (size >= 0)
{
to_app_buf->set_size(size);
// pass cleartext data to app
parent().app_recv(std::move(to_app_buf));
}
else if (size == SSLConst::SHOULD_RETRY)
break;
else if (size == SSLConst::PEER_CLOSE_NOTIFY)
{
error(Error::SSL_ERROR);
throw ErrorCode(Error::CLIENT_HALT, true, "SSL Close Notify received");
}
else
{
error(Error::SSL_ERROR);
throw unknown_status_from_ssl_layer();
}
}
}
void update_retransmit()
{
next_retransmit_ = *now + rel_send.until_retransmit(*now);
}
void error(const Error::Type reason)
{
if (stats)
stats->error(reason);
invalidate(reason);
}
private:
const Time::Duration tls_timeout;
typename SSLAPI::Ptr ssl_;
Frame::Ptr frame_;
int up_stack_reentry_level = 0;
bool invalidated_ = false;
Error::Type invalidation_reason_ = Error::SUCCESS;
bool ssl_started_ = false;
Time next_retransmit_ = Time::infinite();
BufferPtr to_app_buf; // cleartext data decrypted by SSL that is to be passed to app via app_recv method
PACKET ack_send_buf; // only used for standalone ACKs to be sent to peer
std::deque<BufferPtr> app_write_queue;
std::deque<PACKET> raw_write_queue;
SessionStats::Ptr stats;
protected:
TimePtr now;
ReliableRecv rel_recv;
ReliableSend rel_send;
ReliableAck xmit_acks{};
};
} // namespace openvpn
#endif // OPENVPN_SSL_PROTOSTACK_H