#include #include #include #include namespace libuv { #define LoopCall(h, ...) LogicCall(static_cast((h)->loop->data)->m_Logic, __VA_ARGS__) struct glue { virtual ~glue() = default; virtual void Close() = 0; }; /// tcp connection glue between llarp and libuv struct conn_glue : public glue { using WriteBuffer_t = std::vector; struct WriteEvent { WriteBuffer_t data; uv_write_t request; WriteEvent() = default; explicit WriteEvent(size_t sz, char* ptr) { request.data = this; data.resize(sz); std::copy_n(ptr, sz, data.begin()); } uv_buf_t Buffer() { return uv_buf_init(data.data(), data.size()); } uv_write_t* Request() { return &request; } }; uv_tcp_t m_Handle; uv_connect_t m_Connect; uv_check_t m_Ticker; llarp_tcp_connecter* const m_TCP; llarp_tcp_acceptor* const m_Accept; llarp_tcp_conn m_Conn; llarp::SockAddr m_Addr; conn_glue(uv_loop_t* loop, llarp_tcp_connecter* tcp, const llarp::SockAddr& addr) : m_TCP(tcp), m_Accept(nullptr), m_Addr(addr) { m_Connect.data = this; m_Handle.data = this; m_TCP->impl = this; uv_tcp_init(loop, &m_Handle); m_Ticker.data = this; uv_check_init(loop, &m_Ticker); m_Conn.close = &ExplicitClose; m_Conn.write = &ExplicitWrite; } conn_glue(uv_loop_t* loop, llarp_tcp_acceptor* tcp, const llarp::SockAddr& addr) : m_TCP(nullptr), m_Accept(tcp), m_Addr(addr) { m_Connect.data = nullptr; m_Handle.data = this; uv_tcp_init(loop, &m_Handle); m_Ticker.data = this; uv_check_init(loop, &m_Ticker); m_Accept->close = &ExplicitCloseAccept; m_Conn.write = nullptr; m_Conn.closed = nullptr; m_Conn.tick = nullptr; } conn_glue(conn_glue* parent) : m_TCP(nullptr), m_Accept(nullptr) { m_Connect.data = nullptr; m_Conn.close = &ExplicitClose; m_Conn.write = &ExplicitWrite; m_Handle.data = this; uv_tcp_init(parent->m_Handle.loop, &m_Handle); m_Ticker.data = this; uv_check_init(parent->m_Handle.loop, &m_Ticker); } static void OnOutboundConnect(uv_connect_t* c, int status) { conn_glue* self = static_cast(c->data); self->HandleConnectResult(status); c->data = nullptr; } bool ConnectAsync() { return uv_tcp_connect(&m_Connect, &m_Handle, m_Addr, &OnOutboundConnect) != -1; } static void ExplicitClose(llarp_tcp_conn* conn) { static_cast(conn->impl)->Close(); } static void ExplicitCloseAccept(llarp_tcp_acceptor* tcp) { static_cast(tcp->impl)->Close(); } static ssize_t ExplicitWrite(llarp_tcp_conn* conn, const byte_t* ptr, size_t sz) { return static_cast(conn->impl)->WriteAsync((char*)ptr, sz); } static void OnRead(uv_stream_t* stream, ssize_t nread, const uv_buf_t* buf) { if (nread >= 0) { auto* conn = static_cast(stream->data); conn->Read(buf->base, nread); } else if (nread < 0) { static_cast(stream->data)->Close(); } delete[] buf->base; } static void Alloc(uv_handle_t*, size_t suggested_size, uv_buf_t* buf) { buf->base = new char[suggested_size]; buf->len = suggested_size; } void Read(const char* ptr, ssize_t sz) { if (m_Conn.read) { llarp::LogDebug("tcp read ", sz, " bytes"); const llarp_buffer_t buf(ptr, sz); m_Conn.read(&m_Conn, buf); } } void HandleConnectResult(int status) { if (m_TCP && m_TCP->connected) { if (status == 0) { m_Conn.impl = this; m_Conn.loop = m_TCP->loop; m_Conn.close = &ExplicitClose; m_Conn.write = &ExplicitWrite; m_TCP->connected(m_TCP, &m_Conn); Start(); } else if (m_TCP->error) { llarp::LogError("failed to connect tcp ", uv_strerror(status)); m_TCP->error(m_TCP); } } } void WriteFail() { if (m_Conn.close) m_Conn.close(&m_Conn); } uv_stream_t* Stream() { return (uv_stream_t*)&m_Handle; } static void OnWritten(uv_write_t* req, int status) { WriteEvent* ev = static_cast(req->data); if (status == 0) { llarp::LogDebug("wrote ", ev->data.size()); } else { llarp::LogDebug("write fail"); } delete ev; } int WriteAsync(char* data, size_t sz) { if (uv_is_closing((const uv_handle_t*)&m_Handle)) return -1; WriteEvent* ev = new WriteEvent(sz, data); auto buf = ev->Buffer(); if (uv_write(ev->Request(), Stream(), &buf, 1, &OnWritten) == 0) return sz; delete ev; return -1; } static void OnClosed(uv_handle_t* h) { conn_glue* conn = static_cast(h->data); conn->HandleClosed(); } static void FullClose(uv_handle_t* h) { auto* self = static_cast(h->data); h->data = nullptr; delete self; llarp::LogDebug("deleted"); } void HandleClosed() { m_Handle.data = nullptr; if (m_Accept) { if (m_Accept->closed) m_Accept->closed(m_Accept); m_Accept->impl = nullptr; } if (m_Conn.closed) { m_Conn.closed(&m_Conn); } m_Conn.impl = nullptr; llarp::LogDebug("closed"); uv_close((uv_handle_t*)&m_Ticker, &FullClose); } static void OnShutdown(uv_shutdown_t* shut, int code) { llarp::LogDebug("shut down ", code); auto* self = static_cast(shut->data); uv_close((uv_handle_t*)&self->m_Handle, &OnClosed); delete shut; } void Close() override { if (uv_is_closing((uv_handle_t*)Stream())) return; llarp::LogDebug("close tcp connection"); uv_check_stop(&m_Ticker); uv_read_stop(Stream()); auto* shut = new uv_shutdown_t(); shut->data = this; uv_shutdown(shut, Stream(), &OnShutdown); } static void OnAccept(uv_stream_t* stream, int status) { if (status == 0) { conn_glue* conn = static_cast(stream->data); conn->Accept(); } else { llarp::LogError("tcp accept failed: ", uv_strerror(status)); } } static void OnTick(uv_check_t* t) { conn_glue* conn = static_cast(t->data); conn->Tick(); } void Tick() { if (m_Accept && m_Accept->tick) { m_Accept->tick(m_Accept); } if (m_Conn.tick) { m_Conn.tick(&m_Conn); } } void Start() { auto result = uv_check_start(&m_Ticker, &OnTick); if (result) llarp::LogError("failed to start timer ", uv_strerror(result)); result = uv_read_start(Stream(), &Alloc, &OnRead); if (result) llarp::LogError("failed to start reader ", uv_strerror(result)); } void Accept() { if (m_Accept && m_Accept->accepted) { auto* child = new conn_glue(this); llarp::LogDebug("accepted new connection"); child->m_Conn.impl = child; child->m_Conn.loop = m_Accept->loop; child->m_Conn.close = &ExplicitClose; child->m_Conn.write = &ExplicitWrite; auto res = uv_accept(Stream(), child->Stream()); if (res) { llarp::LogError("failed to accept tcp connection ", uv_strerror(res)); child->Close(); return; } m_Accept->accepted(m_Accept, &child->m_Conn); child->Start(); } } bool Server() { uv_check_start(&m_Ticker, &OnTick); m_Accept->close = &ExplicitCloseAccept; return uv_tcp_bind(&m_Handle, m_Addr, 0) == 0 && uv_listen(Stream(), 5, &OnAccept) == 0; } }; struct ticker_glue : public glue { std::function func; ticker_glue(uv_loop_t* loop, std::function tick) : func(tick) { m_Ticker.data = this; uv_check_init(loop, &m_Ticker); } static void OnTick(uv_check_t* t) { ticker_glue* ticker = static_cast(t->data); LoopCall(t, ticker->func); } bool Start() { return uv_check_start(&m_Ticker, &OnTick) != -1; } void Close() override { uv_check_stop(&m_Ticker); uv_close((uv_handle_t*)&m_Ticker, [](auto h) { ticker_glue* self = (ticker_glue*)h->data; h->data = nullptr; delete self; }); } uv_check_t m_Ticker; }; struct udp_glue : public glue { uv_udp_t m_Handle; uv_check_t m_Ticker; llarp_udp_io* const m_UDP; llarp::SockAddr m_Addr; udp_glue(uv_loop_t* loop, llarp_udp_io* udp, const llarp::SockAddr& src) : m_UDP(udp), m_Addr(src) { m_Handle.data = this; m_Ticker.data = this; uv_udp_init(loop, &m_Handle); uv_check_init(loop, &m_Ticker); } static void Alloc(uv_handle_t*, size_t suggested_size, uv_buf_t* buf) { const size_t sz = std::min(suggested_size, size_t{1500}); buf->base = new char[sz]; buf->len = sz; } /// callback for libuv static void OnRecv(uv_udp_t* handle, ssize_t nread, const uv_buf_t* buf, const sockaddr* addr, unsigned) { udp_glue* glue = static_cast(handle->data); if (addr) glue->RecvFrom(nread, buf, llarp::SockAddr(*addr)); delete[] buf->base; } void RecvFrom(ssize_t sz, const uv_buf_t* buf, const llarp::SockAddr& fromaddr) { if (sz > 0 && m_UDP) { const size_t pktsz = sz; if (m_UDP->recvfrom) { const llarp_buffer_t pkt((const byte_t*)buf->base, pktsz); m_UDP->recvfrom(m_UDP, fromaddr, ManagedBuffer{pkt}); } } } static void OnTick(uv_check_t* t) { udp_glue* udp = static_cast(t->data); udp->Tick(); } void Tick() { if (m_UDP && m_UDP->tick) m_UDP->tick(m_UDP); } static int SendTo(llarp_udp_io* udp, const llarp::SockAddr& to, const byte_t* ptr, size_t sz) { auto* self = static_cast(udp->impl); if (self == nullptr) return -1; uv_buf_t buf = uv_buf_init((char*)ptr, sz); return uv_udp_try_send(&self->m_Handle, &buf, 1, to); } bool Bind() { auto ret = uv_udp_bind(&m_Handle, m_Addr, 0); if (ret) { llarp::LogError("failed to bind to ", m_Addr, " ", uv_strerror(ret)); return false; } if (uv_udp_recv_start(&m_Handle, &Alloc, &OnRecv)) { llarp::LogError("failed to start recving packets via ", m_Addr); return false; } if (uv_check_start(&m_Ticker, &OnTick)) { llarp::LogError("failed to start ticker"); return false; } #if defined(_WIN32) || defined(_WIN64) #else if (uv_fileno((const uv_handle_t*)&m_Handle, &m_UDP->fd)) return false; #endif m_UDP->sendto = &SendTo; m_UDP->impl = this; return true; } static void OnClosed(uv_handle_t* h) { auto* glue = static_cast(h->data); if (glue) { h->data = nullptr; delete glue; } } void Close() override { m_UDP->impl = nullptr; uv_check_stop(&m_Ticker); uv_close((uv_handle_t*)&m_Handle, &OnClosed); } }; struct pipe_glue : public glue { byte_t m_Buffer[1024 * 8]; llarp_ev_pkt_pipe* const m_Pipe; pipe_glue(uv_loop_t* loop, llarp_ev_pkt_pipe* pipe) : m_Pipe(pipe) { m_Handle.data = this; m_Ticker.data = this; uv_poll_init(loop, &m_Handle, m_Pipe->fd); uv_check_init(loop, &m_Ticker); } void Tick() { LoopCall(&m_Handle, std::bind(&llarp_ev_pkt_pipe::tick, m_Pipe)); } static void OnRead(uv_poll_t* handle, int status, int) { if (status) { return; } pipe_glue* glue = static_cast(handle->data); int r = glue->m_Pipe->read(glue->m_Buffer, sizeof(glue->m_Buffer)); if (r <= 0) return; const llarp_buffer_t buf{glue->m_Buffer, static_cast(r)}; glue->m_Pipe->OnRead(buf); } static void OnClosed(uv_handle_t* h) { auto* self = static_cast(h->data); if (self) { h->data = nullptr; delete self; } } void Close() override { uv_check_stop(&m_Ticker); uv_close((uv_handle_t*)&m_Handle, &OnClosed); } static void OnTick(uv_check_t* h) { pipe_glue* pipe = static_cast(h->data); LoopCall(h, std::bind(&pipe_glue::Tick, pipe)); } bool Start() { if (uv_poll_start(&m_Handle, UV_READABLE, &OnRead)) return false; if (uv_check_start(&m_Ticker, &OnTick)) return false; return true; } uv_poll_t m_Handle; uv_check_t m_Ticker; }; #if defined(_WIN32) || defined(_WIN64) #else struct tun_glue : public glue { uv_poll_t m_Handle; uv_check_t m_Ticker; llarp_tun_io* const m_Tun; device* const m_Device; byte_t m_Buffer[1500]; bool readpkt; tun_glue(llarp_tun_io* tun) : m_Tun(tun), m_Device(tuntap_init()) { m_Handle.data = this; m_Ticker.data = this; readpkt = false; } ~tun_glue() override { tuntap_destroy(m_Device); } static void OnTick(uv_check_t* timer) { tun_glue* tun = static_cast(timer->data); tun->Tick(); } static void OnPoll(uv_poll_t* h, int, int events) { if (events & UV_READABLE) { static_cast(h->data)->Read(); } } void Read() { auto sz = tuntap_read(m_Device, m_Buffer, sizeof(m_Buffer)); if (sz > 0) { llarp::LogDebug("tun read ", sz); const llarp_buffer_t pkt(m_Buffer, sz); if (m_Tun && m_Tun->recvpkt) m_Tun->recvpkt(m_Tun, pkt); } } void Tick() { if (m_Tun->before_write) m_Tun->before_write(m_Tun); if (m_Tun->tick) m_Tun->tick(m_Tun); } static void OnClosed(uv_handle_t* h) { auto* self = static_cast(h->data); if (self) { h->data = nullptr; delete self; } } void Close() override { if (m_Tun->impl == nullptr) return; m_Tun->impl = nullptr; uv_check_stop(&m_Ticker); uv_close((uv_handle_t*)&m_Ticker, [](uv_handle_t* h) { tun_glue* glue = static_cast(h->data); uv_close((uv_handle_t*)&glue->m_Handle, &OnClosed); }); } bool Write(const byte_t* pkt, size_t sz) { return tuntap_write(m_Device, (void*)pkt, sz) != -1; } static bool WritePkt(llarp_tun_io* tun, const byte_t* pkt, size_t sz) { tun_glue* glue = static_cast(tun->impl); return glue && glue->Write(pkt, sz); } bool Init(uv_loop_t* loop) { memcpy(m_Device->if_name, m_Tun->ifname, sizeof(m_Device->if_name)); if (tuntap_start(m_Device, TUNTAP_MODE_TUNNEL, 0) == -1) { llarp::LogError("failed to start up ", m_Tun->ifname); return false; } if (tuntap_set_ip(m_Device, m_Tun->ifaddr, m_Tun->ifaddr, m_Tun->netmask) == -1) { llarp::LogError("failed to set address on ", m_Tun->ifname); return false; } if (tuntap_up(m_Device) == -1) { llarp::LogError("failed to put up ", m_Tun->ifname); return false; } if (m_Device->tun_fd == -1) { llarp::LogError("tun interface ", m_Tun->ifname, " has invalid fd: ", m_Device->tun_fd); return false; } tuntap_set_nonblocking(m_Device, 1); if (uv_poll_init(loop, &m_Handle, m_Device->tun_fd) == -1) { llarp::LogError("failed to start polling on ", m_Tun->ifname); return false; } if (uv_poll_start(&m_Handle, UV_READABLE, &OnPoll)) { llarp::LogError("failed to start polling on ", m_Tun->ifname); return false; } if (uv_check_init(loop, &m_Ticker) != 0 || uv_check_start(&m_Ticker, &OnTick) != 0) { llarp::LogError("failed to set up tun interface timer for ", m_Tun->ifname); return false; } m_Tun->writepkt = &WritePkt; m_Tun->impl = this; return true; } }; #endif void Loop::FlushLogic() { while (not m_LogicCalls.empty()) { auto f = m_LogicCalls.popFront(); f(); } } static void OnAsyncWake(uv_async_t* async_handle) { Loop* loop = static_cast(async_handle->data); loop->update_time(); loop->process_timer_queue(); loop->process_cancel_queue(); loop->FlushLogic(); llarp::LogContext::Instance().logStream->Tick(loop->time_now()); } Loop::Loop() : llarp_ev_loop(), m_LogicCalls(1024), m_timerQueue(20), m_timerCancelQueue(20) { } bool Loop::init() { if (uv_loop_init(&m_Impl) == -1) return false; #ifdef LOKINET_DEBUG last_time = 0; loop_run_count = 0; #endif m_Impl.data = this; #if defined(_WIN32) || defined(_WIN64) #else uv_loop_configure(&m_Impl, UV_LOOP_BLOCK_SIGNAL, SIGPIPE); #endif m_TickTimer = new uv_timer_t; m_TickTimer->data = this; if (uv_timer_init(&m_Impl, m_TickTimer) == -1) return false; m_Run.store(true); m_nextID.store(0); m_WakeUp.data = this; uv_async_init(&m_Impl, &m_WakeUp, &OnAsyncWake); return true; } void Loop::update_time() { llarp_ev_loop::update_time(); uv_update_time(&m_Impl); } bool Loop::running() const { return m_Run.load(); } bool Loop::tcp_connect(llarp_tcp_connecter* tcp, const llarp::SockAddr& addr) { auto* impl = new conn_glue(&m_Impl, tcp, addr); tcp->impl = impl; if (impl->ConnectAsync()) return true; delete impl; tcp->impl = nullptr; return false; } static void OnTickTimeout(uv_timer_t* timer) { uv_stop(timer->loop); } int Loop::run() { uv_timer_start( m_TickTimer, [](uv_timer_t* t) { static_cast(t->loop->data)->FlushLogic(); }, 1000, 1000); return uv_run(&m_Impl, UV_RUN_DEFAULT); } int Loop::tick(int ms) { if (m_Run) { #ifdef TESTNET_SPEED ms *= TESTNET_SPEED; #endif uv_timer_start(m_TickTimer, &OnTickTimeout, ms, 0); uv_run(&m_Impl, UV_RUN_ONCE); } return 0; } struct TimerData { Loop* loop; uint64_t job_id; }; void CloseUVTimer(uv_timer_t* timer) { // have to delete timer handle this way because libuv. uv_timer_stop(timer); uv_close((uv_handle_t*)timer, [](uv_handle_t* handle) { delete (uv_timer_t*)handle; }); } static void OnUVTimer(uv_timer_t* timer) { TimerData* timer_data = static_cast(timer->data); Loop* loop = timer_data->loop; loop->do_timer_job(timer_data->job_id); delete timer_data; CloseUVTimer(timer); } uint32_t Loop::call_after_delay(llarp_time_t delay_ms, std::function callback) { #ifdef TESTNET_SPEED delay_ms *= TESTNET_SPEED; #endif PendingTimer timer; timer.delay_ms = delay_ms; timer.callback = callback; timer.job_id = m_nextID++; uint64_t job_id = timer.job_id; m_timerQueue.pushBack(std::move(timer)); uv_async_send(&m_WakeUp); return job_id; } void Loop::cancel_delayed_call(uint32_t job_id) { m_timerCancelQueue.pushBack(job_id); uv_async_send(&m_WakeUp); } void Loop::process_timer_queue() { while (not m_timerQueue.empty()) { PendingTimer job = m_timerQueue.popFront(); uint64_t job_id = job.job_id; m_pendingCalls.emplace(job_id, std::move(job.callback)); TimerData* timer_data = new TimerData; timer_data->loop = this; timer_data->job_id = job_id; uv_timer_t* newTimer = new uv_timer_t; newTimer->data = (void*)timer_data; uv_timer_init(&m_Impl, newTimer); uv_timer_start(newTimer, &OnUVTimer, job.delay_ms.count(), 0); } } void Loop::process_cancel_queue() { while (not m_timerCancelQueue.empty()) { uint64_t job_id = m_timerCancelQueue.popFront(); m_pendingCalls.erase(job_id); } } void Loop::do_timer_job(uint64_t job_id) { auto itr = m_pendingCalls.find(job_id); if (itr != m_pendingCalls.end()) { if (itr->second) itr->second(); m_pendingCalls.erase(itr->first); } } void Loop::stop() { if (m_Run) { llarp::LogInfo("stopping event loop"); CloseAll(); uv_stop(&m_Impl); } m_Run.store(false); } void Loop::CloseAll() { llarp::LogInfo("Closing all handles"); uv_walk( &m_Impl, [](uv_handle_t* h, void*) { if (uv_is_closing(h)) return; if (h->data && uv_is_active(h) && h->type != UV_TIMER) { static_cast(h->data)->Close(); } }, nullptr); } void Loop::stopped() { tick(50); llarp::LogInfo("we have stopped"); } bool Loop::udp_listen(llarp_udp_io* udp, const llarp::SockAddr& src) { auto* impl = new udp_glue(&m_Impl, udp, src); udp->impl = impl; if (impl->Bind()) { return true; } delete impl; return false; } bool Loop::add_ticker(std::function func) { auto* ticker = new ticker_glue(&m_Impl, func); if (ticker->Start()) { return true; } delete ticker; return false; } bool Loop::udp_close(llarp_udp_io* udp) { if (udp == nullptr) return false; auto* glue = static_cast(udp->impl); if (glue == nullptr) return false; glue->Close(); return true; } bool Loop::tun_listen(llarp_tun_io* tun) { #if defined(_WIN32) || defined(_WIN64) (void)tun; return false; #else auto* glue = new tun_glue(tun); tun->impl = glue; if (glue->Init(&m_Impl)) { return true; } delete glue; return false; #endif } bool Loop::tcp_listen(llarp_tcp_acceptor* tcp, const llarp::SockAddr& addr) { auto* glue = new conn_glue(&m_Impl, tcp, addr); tcp->impl = glue; if (glue->Server()) return true; tcp->impl = nullptr; delete glue; return false; } bool Loop::add_pipe(llarp_ev_pkt_pipe* p) { auto* glue = new pipe_glue(&m_Impl, p); if (glue->Start()) return true; delete glue; return false; } void Loop::call_soon(std::function f) { m_LogicCalls.tryPushBack(f); uv_async_send(&m_WakeUp); } } // namespace libuv