#include #include #include #include "mem.hpp" #define EV_TICK_INTERVAL 100 // apparently current Solaris will emulate epoll. #if __linux__ || __sun__ #include "ev_epoll.hpp" #elif defined(__FreeBSD__) || defined(__OpenBSD__) || defined(__NetBSD__) \ || (__APPLE__ && __MACH__) #include "ev_kqueue.hpp" #elif defined(_WIN32) || defined(_WIN64) || defined(__NT__) #include "ev_win32.hpp" #else #error No async event loop for your platform, subclass llarp_ev_loop #endif void llarp_ev_loop_alloc(struct llarp_ev_loop **ev) { #if __linux__ || __sun__ *ev = new llarp_epoll_loop; #elif defined(__FreeBSD__) || defined(__OpenBSD__) || defined(__NetBSD__) \ || (__APPLE__ && __MACH__) *ev = new llarp_kqueue_loop; #elif defined(_WIN32) || defined(_WIN64) || defined(__NT__) *ev = new llarp_win32_loop; #else #error no event loop subclass #endif (*ev)->init(); (*ev)->_now = llarp_time_now_ms(); } void llarp_ev_loop_free(struct llarp_ev_loop **ev) { delete *ev; *ev = nullptr; } int llarp_ev_loop_run(struct llarp_ev_loop *ev, struct llarp_logic *logic) { while(ev->running()) { ev->_now = llarp_time_now_ms(); ev->tick(EV_TICK_INTERVAL); if(ev->running()) llarp_logic_tick(logic, ev->_now); } return 0; } void llarp_ev_loop_run_single_process(struct llarp_ev_loop *ev, struct llarp_threadpool *tp, struct llarp_logic *logic) { while(ev->running()) { ev->_now = llarp_time_now_ms(); ev->tick(EV_TICK_INTERVAL); if(ev->running()) { llarp_logic_tick_async(logic, ev->_now); llarp_threadpool_tick(tp); } } } int llarp_ev_add_udp(struct llarp_ev_loop *ev, struct llarp_udp_io *udp, const struct sockaddr *src) { udp->parent = ev; if(ev->udp_listen(udp, src)) return 0; return -1; } int llarp_ev_close_udp(struct llarp_udp_io *udp) { if(udp->parent->udp_close(udp)) return 0; return -1; } llarp_time_t llarp_ev_loop_time_now_ms(struct llarp_ev_loop *loop) { return loop->_now; } void llarp_ev_loop_stop(struct llarp_ev_loop *loop) { loop->stop(); } int llarp_ev_udp_sendto(struct llarp_udp_io *udp, const sockaddr *to, const void *buf, size_t sz) { auto ret = static_cast< llarp::ev_io * >(udp->impl)->sendto(to, buf, sz); if(ret == -1 && errno != 0) { llarp::LogWarn("sendto failed ", strerror(errno)); errno = 0; } return ret; } bool llarp_ev_add_tun(struct llarp_ev_loop *loop, struct llarp_tun_io *tun) { auto dev = loop->create_tun(tun); tun->impl = dev; if(dev) { return loop->add_ev(dev, false); } return false; } bool llarp_tcp_conn_async_write(struct llarp_tcp_conn *conn, const void *pkt, size_t sz) { const byte_t *ptr = (const byte_t *)pkt; llarp::tcp_conn *impl = static_cast< llarp::tcp_conn * >(conn->impl); if(impl->_shouldClose) { llarp::LogError("write on closed connection"); return false; } while(sz > EV_WRITE_BUF_SZ) { if(!impl->queue_write((const byte_t *)ptr, EV_WRITE_BUF_SZ)) return false; ptr += EV_WRITE_BUF_SZ; sz -= EV_WRITE_BUF_SZ; } return impl->queue_write(ptr, sz); } void llarp_tcp_async_try_connect(struct llarp_ev_loop *loop, struct llarp_tcp_connecter *tcp) { tcp->loop = loop; llarp::string_view addr_str, port_str; // try parsing address const char *begin = tcp->remote; const char *ptr = strstr(tcp->remote, ":"); // get end of address if(ptr == nullptr) { llarp::LogError("bad address: ", tcp->remote); if(tcp->error) tcp->error(tcp); return; } const char *end = ptr; while(*end && (end - begin) < sizeof(tcp->remote)) { ++end; } addr_str = llarp::string_view(begin, ptr - begin); ++ptr; port_str = llarp::string_view(ptr, end - ptr); // actually parse address llarp::Addr addr(addr_str, port_str); if(!loop->tcp_connect(tcp, addr)) { llarp::LogError("async connect failed"); if(tcp->error) tcp->error(tcp); } } bool llarp_tcp_serve(struct llarp_ev_loop *loop, struct llarp_tcp_acceptor *tcp, const struct sockaddr *bindaddr) { tcp->loop = loop; llarp::ev_io *impl = loop->bind_tcp(tcp, bindaddr); if(impl) { return loop->add_ev(impl, false); } return false; } void llarp_tcp_acceptor_close(struct llarp_tcp_acceptor *tcp) { llarp::ev_io *impl = static_cast< llarp::ev_io * >(tcp->user); tcp->impl = nullptr; tcp->loop->close_ev(impl); if(tcp->closed) tcp->closed(tcp); // dont free acceptor because it may be stack allocated } bool llarp_ev_tun_async_write(struct llarp_tun_io *tun, const void *buf, size_t sz) { if(sz > EV_WRITE_BUF_SZ) { llarp::LogWarn("packet too big, ", sz, " > ", EV_WRITE_BUF_SZ); return false; } return static_cast< llarp::tun * >(tun->impl)->queue_write( (const byte_t *)buf, sz); } void llarp_tcp_conn_close(struct llarp_tcp_conn *conn) { static_cast< llarp::tcp_conn * >(conn->impl)->_shouldClose = true; } namespace llarp { bool tcp_conn::tick() { if(_shouldClose) { if(tcp.closed) tcp.closed(&tcp); return false; } else if(tcp.tick) tcp.tick(&tcp); return true; } } // namespace llarp