#include #include #include #include #include #include #include #include #include #include #include #include "crypto.h" #define TLV_TYPE_ENCRYPTED_BLOB 0x0000 #define TLV_TYPE_NONCE 0x0001 #define TLV_TYPE_PUBLIC_KEY 0x0002 #define TLV_TYPE_DOWNSTREAM_BITRATE 0x0003 #define TLV_TYPE_ENCRYPTED 0x8000 #define TLV_TYPE_CLIENT_HANDSHAKE 0x8001 #define TLV_TYPE_CLIENT_HANDSHAKE_SECURE 0x8002 #define TLV_TYPE_SERVER_HANDSHAKE 0x8003 #define TLV_TYPE_SERVER_HANDSHAKE_SECURE 0x8004 #define TLV_TYPE_TUNNEL_REQUEST 0x8005 #define TLV_TYPE_CHANNEL 0x8006 std::string CryptoUtil::BinToHex(const std::string& bin) { static const char hex[] = "0123456789abcdef"; std::string ret; ret.reserve(bin.length() * 2); for (int i = 0; i < bin.length(); i++) { ret.push_back(hex[(bin[i] & 0xf0) >> 4]); ret.push_back(hex[bin[i] & 0x0f]); } return ret; } void CryptoUtil::GenKey(std::string* key) { unsigned char buf[crypto_secretbox_KEYBYTES]; randombytes_buf(buf, crypto_secretbox_KEYBYTES); key->assign((char*)buf, crypto_secretbox_KEYBYTES); } void CryptoUtil::GenKeyPair(std::string* secret_key, std::string* public_key) { unsigned char public_key_buf[crypto_box_PUBLICKEYBYTES]; unsigned char secret_key_buf[crypto_box_PUBLICKEYBYTES]; assert(crypto_box_keypair(public_key_buf, secret_key_buf) == 0); public_key->assign((char*)public_key_buf, crypto_box_PUBLICKEYBYTES); secret_key->assign((char*)secret_key_buf, crypto_box_SECRETKEYBYTES); } void CryptoUtil::DerivePublicKey(const std::string& secret_key, std::string* public_key) { assert(secret_key.length() == crypto_box_SECRETKEYBYTES); unsigned char buf[crypto_box_PUBLICKEYBYTES]; assert(!crypto_scalarmult_base(buf, (const unsigned char*)secret_key.data())); public_key->assign((char*)buf, crypto_box_PUBLICKEYBYTES); } void CryptoUtil::ReadKeyFromFile(const std::string& filename, std::string* key) { std::fstream key_file(filename, std::fstream::in); assert(!key_file.fail()); key_file >> *key; } void CryptoUtil::WriteKeyToFile(const std::string& filename, const std::string& key) { std::fstream key_file(filename, std::fstream::out); assert(!key_file.fail()); key_file << key; } void CryptoUtil::EncodeEncryptAppend(const std::string& secret_key, const std::string& public_key, const TLVNode& input, TLVNode* container) { assert(secret_key.length() == crypto_box_SECRETKEYBYTES); assert(public_key.length() == crypto_box_PUBLICKEYBYTES); std::string encoded; input.Encode(&encoded); size_t encrypted_bytes = encoded.length() + crypto_box_MACBYTES; unsigned char nonce[crypto_box_NONCEBYTES]; randombytes_buf(nonce, crypto_box_NONCEBYTES); unsigned char output[encrypted_bytes]; assert(!crypto_box_easy(output, (const unsigned char*)encoded.data(), encoded.length(), nonce, (const unsigned char*)public_key.data(), (const unsigned char*)secret_key.data())); auto encrypted = new TLVNode(TLV_TYPE_ENCRYPTED); encrypted->AppendChild(new TLVNode(TLV_TYPE_NONCE, std::string((char*)nonce, crypto_box_NONCEBYTES))); encrypted->AppendChild(new TLVNode(TLV_TYPE_ENCRYPTED_BLOB, std::string((char*)output, encrypted_bytes))); container->AppendChild(encrypted); } TLVNode* CryptoUtil::DecryptDecode(const std::string& secret_key, const std::string& public_key, const TLVNode& input) { assert(secret_key.length() == crypto_box_SECRETKEYBYTES); assert(public_key.length() == crypto_box_PUBLICKEYBYTES); assert(input.GetType() == TLV_TYPE_ENCRYPTED); auto nonce = input.FindChild(TLV_TYPE_NONCE); if (!nonce || nonce->GetValue().length() != crypto_box_NONCEBYTES) { return nullptr; } auto encrypted = input.FindChild(TLV_TYPE_ENCRYPTED_BLOB); if (!encrypted || encrypted->GetValue().length() < crypto_box_MACBYTES) { return nullptr; } size_t decrypted_bytes = encrypted->GetValue().length() - crypto_box_MACBYTES; unsigned char output[decrypted_bytes]; if (crypto_box_open_easy(output, (const unsigned char*)encrypted->GetValue().data(), encrypted->GetValue().length(), (const unsigned char*)nonce->GetValue().data(), (const unsigned char*)public_key.data(), (const unsigned char*)secret_key.data())) { return nullptr; } return TLVNode::Decode(std::string((char*)output, decrypted_bytes)); } std::ostream& CryptoBase::Log(void *obj) { char buf[64]; snprintf(buf, 64, "[%p] ", obj ? obj : this); return std::cerr << buf; } std::ostream& CryptoBase::LogFatal(void *obj) { std::ostream& ret = Log(obj); delete this; return ret; } CryptoConnBase::CryptoConnBase(const std::string& secret_key) : secret_key_(secret_key), state_(AWAITING_HANDSHAKE) {} CryptoPubServer::CryptoPubServer(const std::string& secret_key) : secret_key_(secret_key), event_base_(event_base_new()) { assert(secret_key_.length() == crypto_box_SECRETKEYBYTES); struct sockaddr_in6 server_addr = {0}; server_addr.sin6_family = AF_INET6; server_addr.sin6_addr = in6addr_any; server_addr.sin6_port = htons(4990); listener_ = evconnlistener_new_bind(event_base_, &CryptoPubServer::OnNewConn_, this, LEV_OPT_REUSEABLE|LEV_OPT_CLOSE_ON_FREE, -1, (struct sockaddr*)&server_addr, sizeof(server_addr)); } CryptoPubServer::~CryptoPubServer() { evconnlistener_free(listener_); event_base_free(event_base_); } void CryptoPubServer::OnNewConn_(struct evconnlistener* listener, int client_fd, struct sockaddr* client_addr_, int client_addrlen, void* this__) { auto this_ = (CryptoPubServer*)this__; this_->OnNewConn(client_fd, client_addr_, client_addrlen); } void CryptoPubServer::OnNewConn(int client_fd, struct sockaddr* client_addr_, int client_addrlen) { assert(client_addr_->sa_family == AF_INET6); auto client_addr = (struct sockaddr_in6*)client_addr_; char buf[128]; inet_ntop(AF_INET6, &client_addr->sin6_addr, buf, 128); auto bev = bufferevent_socket_new(this->event_base_, client_fd, BEV_OPT_CLOSE_ON_FREE); bufferevent_enable(bev, EV_READ); bufferevent_enable(bev, EV_WRITE); auto peer = new CryptoPubServerConnection(bev, this->secret_key_); bufferevent_setcb(bev, &CryptoPubServerConnection::OnReadable_, NULL, &CryptoPubServerConnection::OnError_, peer); Log(peer) << "New connection from [" << buf << "]:" << ntohs(client_addr->sin6_port) << std::endl; } void CryptoPubServer::Loop() { event_base_dispatch(event_base_); } CryptoPubServerConnection::CryptoPubServerConnection(struct bufferevent* bev, const std::string& secret_key) : CryptoConnBase(secret_key), bev_(bev) { } CryptoPubServerConnection::~CryptoPubServerConnection() { Log() << "Connection closed" << std::endl; bufferevent_free(bev_); } void CryptoPubServerConnection::OnReadable_(struct bufferevent* bev, void* this__) { auto this_ = (CryptoPubServerConnection*)this__; this_->OnReadable(); } void CryptoPubServerConnection::OnReadable() { char buf[UINT16_MAX]; int bytes = bufferevent_read(bev_, buf, UINT16_MAX); const std::string input(buf, bytes); std::unique_ptr decoded(TLVNode::Decode(input)); if (!decoded.get()) { // TODO: re-buffer? return; } if (state_ == AWAITING_HANDSHAKE) { OnHandshake(*decoded); return; } if (decoded->GetType() != TLV_TYPE_ENCRYPTED) { LogFatal() << "Protocol error (wrong message type)" << std::endl; return; } std::unique_ptr decrypted(CryptoUtil::DecryptDecode(ephemeral_secret_key_, peer_ephemeral_public_key_, *decoded)); if (!decrypted.get()) { LogFatal() << "Protocol error (decryption failure)" << std::endl; return; } switch (decrypted->GetType()) { } } void CryptoPubServerConnection::OnHandshake(const TLVNode& decoded) { if (decoded.GetType() != TLV_TYPE_CLIENT_HANDSHAKE) { LogFatal() << "Protocol error (client handshake -- wrong message type)" << std::endl; return; } auto peer_public_key = decoded.FindChild(TLV_TYPE_PUBLIC_KEY); if (!peer_public_key) { LogFatal() << "Protocol error (client handshake -- no public key)" << std::endl; return; } peer_public_key_ = peer_public_key->GetValue(); if (peer_public_key_.length() != crypto_box_PUBLICKEYBYTES) { LogFatal() << "Protocol error (client handshake -- wrong public key length)" << std::endl; return; } auto encrypted = decoded.FindChild(TLV_TYPE_ENCRYPTED); if (!encrypted) { LogFatal() << "Protocol error (client handshake -- no encrypted portion)" << std::endl; return; } std::unique_ptr decrypted(CryptoUtil::DecryptDecode(secret_key_, peer_public_key_, *encrypted)); if (!decrypted.get()) { LogFatal() << "Protocol error (client handshake -- decryption failure)" << std::endl; return; } auto peer_ephemeral_public_key = decrypted->FindChild(TLV_TYPE_PUBLIC_KEY); if (!peer_ephemeral_public_key) { LogFatal() << "Protocol error (client handshake -- no ephemeral public key)" << std::endl; return; } peer_ephemeral_public_key_ = peer_ephemeral_public_key->GetValue(); if (peer_ephemeral_public_key_.length() != crypto_box_PUBLICKEYBYTES) { LogFatal() << "Protocol error (client handshake -- wrong ephemeral public key length)" << std::endl; return; } SendHandshake(); this->state_ = READY; Log() << "Handshake successful (client ID: " << CryptoUtil::BinToHex(peer_public_key_) << ")" << std::endl; } void CryptoPubServerConnection::SendHandshake() { std::string ephemeral_public_key; CryptoUtil::GenKeyPair(&ephemeral_secret_key_, &ephemeral_public_key); TLVNode handshake(TLV_TYPE_SERVER_HANDSHAKE); TLVNode secure_handshake(TLV_TYPE_SERVER_HANDSHAKE_SECURE); secure_handshake.AppendChild(new TLVNode(TLV_TYPE_PUBLIC_KEY, ephemeral_public_key)); CryptoUtil::EncodeEncryptAppend(secret_key_, peer_public_key_, secure_handshake, &handshake); std::string out; handshake.Encode(&out); bufferevent_write(bev_, out.data(), out.length()); } void CryptoPubServerConnection::OnError_(struct bufferevent* bev, const short what, void* this__) { auto this_ = (CryptoPubServerConnection*)this__; this_->OnError(what); } void CryptoPubServerConnection::OnError(const short what) { delete this; } CryptoPubClient::CryptoPubClient(struct sockaddr* addr, socklen_t addrlen, const std::string& secret_key, const std::string& server_public_key, const std::list& channel_bitrates) : CryptoConnBase(secret_key), event_base_(event_base_new()), bev_(bufferevent_socket_new(event_base_, -1, BEV_OPT_CLOSE_ON_FREE)), channel_bitrates_(channel_bitrates) { peer_public_key_ = server_public_key; assert(secret_key_.length() == crypto_box_SECRETKEYBYTES); assert(peer_public_key_.length() == crypto_box_PUBLICKEYBYTES); bufferevent_setcb(bev_, &CryptoPubClient::OnReadable_, NULL, &CryptoPubClient::OnConnectOrError_, this); bufferevent_enable(bev_, EV_READ); bufferevent_enable(bev_, EV_WRITE); bufferevent_socket_connect(bev_, addr, addrlen); } CryptoPubClient::~CryptoPubClient() { bufferevent_free(bev_); event_base_free(event_base_); } CryptoPubClient* CryptoPubClient::FromHostname(const std::string& server_address, const std::string& server_port, const std::string& secret_key, const std::string& server_public_key, const std::list& channel_bitrates) { struct addrinfo* res; int gai_ret = getaddrinfo(server_address.c_str(), server_port.c_str(), NULL, &res); if (gai_ret) { std::cerr << "Failed to resolve server_address: " << gai_strerror(gai_ret) << std::endl; return nullptr; } auto ret = new CryptoPubClient((struct sockaddr*)res->ai_addr, res->ai_addrlen, secret_key, server_public_key, channel_bitrates); freeaddrinfo(res); return ret; } void CryptoPubClient::OnReadable_(struct bufferevent* bev, void* this__) { auto this_ = (CryptoPubClient*)this__; this_->OnReadable(); } void CryptoPubClient::OnReadable() { char buf[UINT16_MAX]; int bytes = bufferevent_read(bev_, buf, UINT16_MAX); const std::string input(buf, bytes); std::unique_ptr decoded(TLVNode::Decode(input)); if (!decoded.get()) { // TODO: re-buffer? return; } if (state_ == AWAITING_HANDSHAKE) { OnHandshake(*decoded); return; } if (decoded->GetType() != TLV_TYPE_ENCRYPTED) { LogFatal() << "Protocol error (unexpected message type)" << std::endl; return; } std::unique_ptr decrypted(CryptoUtil::DecryptDecode(ephemeral_secret_key_, peer_ephemeral_public_key_, *decoded)); if (!decrypted.get()) { LogFatal() << "Protocol error (decryption failure)" << std::endl; return; } switch (decrypted->GetType()) { } } void CryptoPubClient::OnHandshake(const TLVNode& decoded) { if (decoded.GetType() != TLV_TYPE_SERVER_HANDSHAKE) { LogFatal() << "Protocol error (server handshake -- wrong message type)" << std::endl; return; } auto encrypted = decoded.FindChild(TLV_TYPE_ENCRYPTED); if (!encrypted) { LogFatal() << "Protocol error (server handshake -- no encrypted portion)" << std::endl; return; } std::unique_ptr decrypted(CryptoUtil::DecryptDecode(secret_key_, peer_public_key_, *encrypted)); if (!decrypted.get()) { LogFatal() << "Protocol error (server handshake -- decryption failure)" << std::endl; return; } auto peer_ephemeral_public_key = decrypted->FindChild(TLV_TYPE_PUBLIC_KEY); if (!peer_ephemeral_public_key) { LogFatal() << "Protocol error (server handshake -- no ephemeral public key)" << std::endl; return; } peer_ephemeral_public_key_ = peer_ephemeral_public_key->GetValue(); if (peer_ephemeral_public_key_.length() != crypto_box_PUBLICKEYBYTES) { LogFatal() << "Protocol error (server handshake -- wrong ephemeral public key length)" << std::endl; return; } this->state_ = READY; Log() << "Handshake successful" << std::endl; SendTunnelRequest(); } void CryptoPubClient::OnConnectOrError_(struct bufferevent* bev, const short what, void* this__) { auto this_ = (CryptoPubClient*)this__; if (what == BEV_EVENT_CONNECTED) { this_->OnConnect(); } else { this_->OnError(); } } void CryptoPubClient::OnConnect() { Log() << "Connected to server" << std::endl; SendHandshake(); } void CryptoPubClient::SendHandshake() { std::string ephemeral_public_key; CryptoUtil::GenKeyPair(&ephemeral_secret_key_, &ephemeral_public_key); TLVNode handshake(TLV_TYPE_CLIENT_HANDSHAKE); std::string public_key; CryptoUtil::DerivePublicKey(secret_key_, &public_key); handshake.AppendChild(new TLVNode(TLV_TYPE_PUBLIC_KEY, public_key)); TLVNode secure_handshake(TLV_TYPE_CLIENT_HANDSHAKE_SECURE); secure_handshake.AppendChild(new TLVNode(TLV_TYPE_PUBLIC_KEY, ephemeral_public_key)); CryptoUtil::EncodeEncryptAppend(secret_key_, peer_public_key_, secure_handshake, &handshake); std::string out; handshake.Encode(&out); bufferevent_write(bev_, out.data(), out.length()); } void CryptoPubClient::SendTunnelRequest() { } void CryptoPubClient::OnError() { Log() << "Connection error" << std::endl; } void CryptoPubClient::Loop() { event_base_dispatch(event_base_); }