#include #include #include #include #include #include #include #include #include #include namespace { int fcntl_helper(int fd, int request, int *result, ...) { va_list args; va_start(args, result); if(!mlibc::sys_fcntl) { return ENOSYS; } int ret = mlibc::sys_fcntl(fd, request, args, result); va_end(args); return ret; } } namespace mlibc { int sys_socket(int family, int type, int protocol, int *fd) { auto result = syscall(SYS_SOCKET, family, type, protocol); if (result < 0) { return -result; } *fd = result; return 0; } int sys_bind(int fd, const struct sockaddr *addr_ptr, socklen_t addr_length) { auto result = syscall(SYS_BIND, fd, addr_ptr, (sc_word_t)addr_length); if (result < 0) { return -result; } return 0; } int sys_connect(int fd, const struct sockaddr *addr_ptr, socklen_t addr_length) { auto result = syscall(SYS_CONNECT, fd, addr_ptr, (sc_word_t)addr_length); if (result < 0) { return -result; } return 0; } int sys_listen(int fd, int backlog) { auto result = syscall(SYS_LISTEN, fd, backlog); if (result < 0) { return -result; } return 0; } int sys_accept(int sockfd, int *newfd, struct sockaddr *addr_ptr, socklen_t *addr_length, int flags) { auto result = syscall(SYS_ACCEPT, sockfd, addr_ptr, addr_length); if (result < 0) { return -result; } *newfd = result; if(flags & SOCK_NONBLOCK) { int fcntl_ret = 0; fcntl_helper(*newfd, F_GETFL, &fcntl_ret); fcntl_helper(*newfd, F_SETFL, &fcntl_ret, fcntl_ret | O_NONBLOCK); } if(flags & SOCK_CLOEXEC) { int fcntl_ret = 0; fcntl_helper(*newfd, F_GETFD, &fcntl_ret); fcntl_helper(*newfd, F_SETFD, &fcntl_ret, fcntl_ret | FD_CLOEXEC); } return 0; } int sys_msg_send(int fd, const struct msghdr *hdr, int flags, ssize_t *length) { auto result = syscall(SYS_SOCK_SEND, fd, hdr, flags); if (result < 0) return -result; *length = result; return 0; } int sys_msg_recv(int sockfd, struct msghdr *msg_hdr, int flags, ssize_t *length) { auto result = syscall(SYS_SOCK_RECV, sockfd, msg_hdr, flags); if (result < 0) { return -result; } *length = result; return 0; } int sys_socketpair(int domain, int type_and_flags, int proto, int *fds) { auto result = syscall(SYS_SOCKET_PAIR, domain, type_and_flags, proto, fds); if (result < 0) { return -result; } return 0; } int sys_getsockopt(int fd, int layer, int number, void *__restrict buffer, socklen_t *__restrict size) { (void)fd; (void)size; if (layer == SOL_SOCKET && number == SO_PEERCRED) { mlibc::infoLogger() << "\e[31mmlibc: getsockopt() call with SOL_SOCKET " "and SO_PEERCRED is unimplemented\e[39m" << frg::endlog; *(int *)buffer = 0; return 0; } else if (layer == SOL_SOCKET && number == SO_SNDBUF) { mlibc::infoLogger() << "\e[31mmlibc: getsockopt() call with SOL_SOCKET " "and SO_SNDBUF is unimplemented\e[39m" << frg::endlog; *(int *)buffer = 4096; return 0; } else if (layer == SOL_SOCKET && number == SO_TYPE) { mlibc::infoLogger() << "\e[31mmlibc: getsockopt() call with SOL_SOCKET and SO_TYPE is " "unimplemented, hardcoding SOCK_STREAM\e[39m" << frg::endlog; *(int *)buffer = SOCK_STREAM; return 0; } else if (layer == SOL_SOCKET && number == SO_ERROR) { mlibc::infoLogger() << "\e[31mmlibc: getsockopt() call with SOL_SOCKET and SO_ERROR is " "unimplemented, hardcoding 0\e[39m" << frg::endlog; *(int *)buffer = 0; return 0; } else if (layer == SOL_SOCKET && number == SO_KEEPALIVE) { mlibc::infoLogger() << "\e[31mmlibc: getsockopt() call with SOL_SOCKET and " "SO_KEEPALIVE is unimplemented, hardcoding 0\e[39m" << frg::endlog; *(int *)buffer = 0; return 0; } else { mlibc::panicLogger() << "\e[31mmlibc: Unexpected getsockopt() call, layer: " << layer << " number: " << number << "\e[39m" << frg::endlog; __builtin_unreachable(); } return 0; } int sys_setsockopt(int fd, int layer, int number, const void *buffer, socklen_t size) { (void)fd; (void)buffer; (void)size; if (layer == SOL_SOCKET && number == SO_PASSCRED) { mlibc::infoLogger() << "\e[31mmlibc: setsockopt(SO_PASSCRED) is not " "implemented correctly\e[39m" << frg::endlog; return 0; } else if (layer == SOL_SOCKET && number == SO_ATTACH_FILTER) { mlibc::infoLogger() << "\e[31mmlibc: setsockopt(SO_ATTACH_FILTER) is " "not implemented correctly\e[39m" << frg::endlog; return 0; } else if (layer == SOL_SOCKET && number == SO_RCVBUFFORCE) { mlibc::infoLogger() << "\e[31mmlibc: setsockopt(SO_RCVBUFFORCE) is not " "implemented correctly\e[39m" << frg::endlog; return 0; } else if (layer == SOL_SOCKET && number == SO_SNDBUF) { mlibc::infoLogger() << "\e[31mmlibc: setsockopt() call with SOL_SOCKET " "and SO_SNDBUF is unimplemented\e[39m" << frg::endlog; return 0; } else if (layer == SOL_SOCKET && number == SO_KEEPALIVE) { mlibc::infoLogger() << "\e[31mmlibc: setsockopt() call with SOL_SOCKET " "and SO_KEEPALIVE is unimplemented\e[39m" << frg::endlog; return 0; } else if (layer == SOL_SOCKET && number == SO_REUSEADDR) { mlibc::infoLogger() << "\e[31mmlibc: setsockopt() call with SOL_SOCKET " "and SO_REUSEADDR is unimplemented\e[39m" << frg::endlog; return 0; } else if (layer == AF_NETLINK && number == SO_ACCEPTCONN) { mlibc::infoLogger() << "\e[31mmlibc: setsockopt() call with AF_NETLINK " "and SO_ACCEPTCONN is unimplemented\e[39m" << frg::endlog; return 0; } else { mlibc::infoLogger() << "\e[31mmlibc: Unexpected setsockopt() call, layer: " << layer << " number: " << number << "\e[39m" << frg::endlog; return 0; } } int sys_shutdown(int sockfd, int how) { auto ret = syscall(SYS_SOCK_SHUTDOWN, sockfd, how); if(int e = sc_error(ret); e) return e; return 0; } int sys_if_nametoindex(const char *name, unsigned int *ret) { int fd = 0; int r = sys_socket(AF_INET, SOCK_DGRAM | SOCK_CLOEXEC, AF_UNSPEC, &fd); if (r) return r; struct ifreq ifr; strncpy(ifr.ifr_name, name, sizeof ifr.ifr_name); r = sys_ioctl(fd, SIOCGIFINDEX, &ifr, NULL); close(fd); if (r) return r; *ret = ifr.ifr_ifindex; return 0; } } // namespace mlibc