#ifndef EV_KQUEUE_HPP #define EV_KQUEUE_HPP #include #include #if __FreeBSD__ // kqueue / kevent #include #include #endif #if(__APPLE__ && __MACH__) // kqueue / kevent #include #include #endif // MacOS needs this #ifndef SOCK_NONBLOCK #include #define SOCK_NONBLOCK O_NONBLOCK #endif // original upstream #include #include #include "ev.hpp" #include "logger.hpp" #include "net.hpp" namespace llarp { struct udp_listener : public ev_io { llarp_udp_io* udp; udp_listener(int fd, llarp_udp_io* u) : ev_io(fd), udp(u){}; ~udp_listener() { } virtual int read(void* buf, size_t sz) { sockaddr_in6 src; socklen_t slen = sizeof(sockaddr_in6); sockaddr* addr = (sockaddr*)&src; ssize_t ret = ::recvfrom(fd, buf, sz, 0, addr, &slen); if(ret == -1) return -1; udp->recvfrom(udp, addr, buf, ret); return 0; } virtual int sendto(const sockaddr* to, const void* data, size_t sz) { socklen_t slen; switch(to->sa_family) { case AF_INET: slen = sizeof(struct sockaddr_in); break; case AF_INET6: slen = sizeof(struct sockaddr_in6); break; default: return -1; } ssize_t sent = ::sendto(fd, data, sz, 0, to, slen); if(sent == -1) perror("kqueue sendto()"); return sent; } }; }; // namespace llarp struct llarp_kqueue_loop : public llarp_ev_loop { int kqueuefd; struct kevent change; /* event we want to monitor */ llarp_kqueue_loop() : kqueuefd(-1) { } ~llarp_kqueue_loop() { } bool init() { if(kqueuefd == -1) { kqueuefd = kqueue(); } return kqueuefd != -1; } int tick(int ms) { (void)ms; struct kevent events[1024]; int result; byte_t readbuf[2048]; result = kevent(kqueuefd, NULL, 0, events, 1024, NULL); // result: 0 is a timeout if(result > 0) { int idx = 0; while(idx < result) { llarp::ev_io* ev = static_cast< llarp::ev_io* >(events[idx].udata); if(ev->read(readbuf, sizeof(readbuf)) == -1) { llarp::Info("close ev"); close_ev(ev); delete ev; } ++idx; } } return result; } int run() { struct kevent events[1024]; int result; byte_t readbuf[2048]; do { result = kevent(kqueuefd, NULL, 0, events, 1024, NULL); // result: 0 is a timeout if(result > 0) { int idx = 0; while(idx < result) { llarp::ev_io* ev = static_cast< llarp::ev_io* >(events[idx].udata); if(ev->read(readbuf, sizeof(readbuf)) == -1) { llarp::Info("close ev"); close_ev(ev); delete ev; } ++idx; } } } while(result != -1); return result; } int udp_bind(const sockaddr* addr) { socklen_t slen; llarp::Debug("kqueue bind affam", addr->sa_family); switch(addr->sa_family) { case AF_INET: slen = sizeof(struct sockaddr_in); break; case AF_INET6: slen = sizeof(struct sockaddr_in6); break; #ifdef AF_LINK #endif #ifdef AF_PACKET case AF_PACKET: slen = sizeof(struct sockaddr_ll); break; #endif default: llarp::Error("unsupported address family"); return -1; } int fd = socket(addr->sa_family, SOCK_DGRAM, 0); if(fd == -1) { perror("socket()"); return -1; } if(addr->sa_family == AF_INET6) { // enable dual stack explicitly int dual = 1; if(setsockopt(fd, IPPROTO_IPV6, IPV6_V6ONLY, &dual, sizeof(dual)) == -1) { // failed perror("setsockopt()"); close(fd); return -1; } } llarp::Addr a(*addr); llarp::Info("bind to ", a); // FreeBSD handbook said to do this if(addr->sa_family == AF_INET && INADDR_ANY) a._addr4.sin_addr.s_addr = htonl(INADDR_ANY); if(bind(fd, addr, slen) == -1) { perror("bind()"); close(fd); return -1; } return fd; } bool close_ev(llarp::ev_io* ev) { EV_SET(&change, ev->fd, EVFILT_READ, EV_DELETE, 0, 0, NULL); return kevent(kqueuefd, &change, 1, NULL, 0, NULL) == -1; } bool udp_listen(llarp_udp_io* l, const sockaddr* src) { int fd = udp_bind(src); if(fd == -1) return false; llarp::udp_listener* listener = new llarp::udp_listener(fd, l); EV_SET(&change, fd, EVFILT_READ, EV_ADD, 0, 0, listener); if(kevent(kqueuefd, &change, 1, NULL, 0, NULL) == -1) { delete listener; return false; } l->impl = listener; return true; } bool udp_close(llarp_udp_io* l) { bool ret = false; auto listener = static_cast< llarp::udp_listener* >(l->impl); if(listener) { ret = close_ev(listener); delete listener; l->impl = nullptr; } return ret; } void stop() { if(kqueuefd != -1) ::close(kqueuefd); kqueuefd = -1; } }; #endif