Ejemplo n.º 1
0
    void run ()
    {
        testcase ("Seed");
        RippleAddress seed;
        expect (seed.setSeedGeneric ("masterpassphrase"));
        expect (seed.humanSeed () == "snoPBrXtMeMyMHUVTgbuqAfg1SUTb", seed.humanSeed ());

        testcase ("RipplePublicKey");
        RippleAddress deprecatedPublicKey (RippleAddress::createNodePublic (seed));
        expect (deprecatedPublicKey.humanNodePublic () ==
            "n94a1u4jAz288pZLtw6yFWVbi89YamiC6JBXPVUj5zmExe5fTVg9",
                deprecatedPublicKey.humanNodePublic ());
        RipplePublicKey publicKey = deprecatedPublicKey.toPublicKey();
        expect (publicKey.to_string() == deprecatedPublicKey.humanNodePublic(),
            publicKey.to_string());

        testcase ("Generator");
        RippleAddress generator (RippleAddress::createGeneratorPublic (seed));
        expect (generator.humanGenerator () ==
            "fhuJKrhSDzV2SkjLn9qbwm5AaRmrxDPfFsHDCP6yfDZWcxDFz4mt",
                generator.humanGenerator ());
    }
Ejemplo n.º 2
0
Handoff
OverlayImpl::onHandoff (std::unique_ptr <beast::asio::ssl_bundle>&& ssl_bundle,
    beast::http::message&& request,
        endpoint_type remote_endpoint)
{
    auto const id = next_id_++;
    beast::WrappedSink sink (deprecatedLogs()["Peer"], makePrefix(id));
    beast::Journal journal (sink);

    Handoff handoff;
    if (processRequest(request, handoff))
        return handoff;
    if (! isPeerUpgrade(request))
        return handoff;

    handoff.moved = true;

    if (journal.trace) journal.trace <<
        "Peer connection upgrade from " << remote_endpoint;

    error_code ec;
    auto const local_endpoint (ssl_bundle->socket.local_endpoint(ec));
    if (ec)
    {
        if (journal.trace) journal.trace <<
            remote_endpoint << " failed: " << ec.message();
        return handoff;
    }

    auto consumer = m_resourceManager.newInboundEndpoint(
        beast::IPAddressConversion::from_asio(remote_endpoint));
    if (consumer.disconnect())
        return handoff;

    auto const slot = m_peerFinder->new_inbound_slot (
        beast::IPAddressConversion::from_asio(local_endpoint),
            beast::IPAddressConversion::from_asio(remote_endpoint));

    if (slot == nullptr)
    {
        // self-connect, close
        handoff.moved = false;
        return handoff;
    }

    // TODO Validate HTTP request

    {
        auto const types = beast::rfc2616::split_commas(
            request.headers["Connect-As"]);
        if (std::find_if(types.begin(), types.end(),
                [](std::string const& s)
                {
                    return beast::ci_equal(s, "peer");
                }) == types.end())
        {
            handoff.moved = false;
            handoff.response = makeRedirectResponse(slot, request,
                remote_endpoint.address());
            handoff.keep_alive = request.keep_alive();
            return handoff;
        }
    }

    handoff.moved = true;
    bool success = true;

    protocol::TMHello hello;
    std::tie(hello, success) = parseHello (request, journal);
    if(! success)
        return handoff;

    uint256 sharedValue;
    std::tie(sharedValue, success) = makeSharedValue(
        ssl_bundle->stream.native_handle(), journal);
    if(! success)
        return handoff;

    RippleAddress publicKey;
    std::tie(publicKey, success) = verifyHello (hello,
        sharedValue, journal, getApp());
    if(! success)
        return handoff;

    std::string name;
    bool const cluster = getApp().getUNL().nodeInCluster(
        publicKey, name);
    
    auto const result = m_peerFinder->activate (slot,
        publicKey.toPublicKey(), cluster);
    if (result != PeerFinder::Result::success)
    {
        if (journal.trace) journal.trace <<
            "Peer " << remote_endpoint << " redirected, slots full";
        handoff.moved = false;
        handoff.response = makeRedirectResponse(slot, request,
            remote_endpoint.address());
        handoff.keep_alive = request.keep_alive();
        return handoff;
    }

    auto const peer = std::make_shared<PeerImp>(id,
        remote_endpoint, slot, std::move(request), hello, publicKey,
            consumer, std::move(ssl_bundle), *this);
    {
        // As we are not on the strand, run() must be called
        // while holding the lock, otherwise new I/O can be
        // queued after a call to stop().
        std::lock_guard <decltype(mutex_)> lock (mutex_);
        add(peer);
        peer->run();
    }
    handoff.moved = true;
    return handoff;
}