#pragma once #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef inline #undef inline #endif #include "common.hpp" #include "config.hpp" #include "utils/command.hpp" #include "utils/file.hpp" #include "utils/string.hpp" LEMONBUDDY_NS namespace net { DEFINE_ERROR(network_error); DEFINE_ERROR(wired_network_error); DEFINE_ERROR(wireless_network_error); // types {{{ struct bytes_t { uint32_t transmitted = 0; uint32_t received = 0; std::chrono::system_clock::time_point time; }; struct linkdata_t { string ip_address; bytes_t previous; bytes_t current; }; // }}} // class: network {{{ class network { public: explicit network(string interface) : m_interface(interface) { if (if_nametoindex(m_interface.c_str()) == 0) throw network_error("Invalid network interface \"" + m_interface + "\""); if ((m_fd = socket(AF_INET, SOCK_DGRAM, 0)) < 0) throw network_error("Failed to open socket"); std::memset(&m_data, 0, sizeof(m_data)); std::strncpy(m_data.ifr_name, m_interface.data(), IFNAMSIZ - 1); } ~network() { if (m_fd != -1) close(m_fd); } bool test_interface() { if ((ioctl(m_fd, SIOCGIFFLAGS, &m_data)) == -1) throw network_error("Failed to get flags"); if ((m_data.ifr_flags & IFF_UP) == 0) return false; if ((m_data.ifr_flags & IFF_RUNNING) == 0) return false; return true; } bool test_connection() { int status = EXIT_FAILURE; try { m_ping = command_util::make_command( "ping -c 2 -W 2 -I " + m_interface + " " + string(CONNECTION_TEST_IP)); status = m_ping->exec(true); m_ping.reset(); } catch (std::exception& e) { } return (status == EXIT_SUCCESS); } bool test() { try { return test_interface() && test_connection(); } catch (network_error& e) { return false; } } bool connected() { try { if (!test_interface()) return false; return file_util::get_contents("/sys/class/net/" + m_interface + "/carrier")[0] == '1'; } catch (network_error& e) { return false; } } bool query_interface() { auto now = chrono::system_clock::now(); if ((now - m_last_query) < chrono::seconds(1)) return true; m_last_query = now; struct ifaddrs* ifaddr; getifaddrs(&ifaddr); bool match = false; for (auto ifa = ifaddr; ifa != nullptr; ifa = ifa->ifa_next) { if (m_interface.compare(0, m_interface.length(), ifa->ifa_name) != 0) continue; match = true; switch (ifa->ifa_addr->sa_family) { case AF_INET: char ip_buffer[NI_MAXHOST]; getnameinfo(ifa->ifa_addr, sizeof(sockaddr_in), ip_buffer, NI_MAXHOST, nullptr, 0, NI_NUMERICHOST); m_linkdata.ip_address = string(ip_buffer); break; case AF_PACKET: if (ifa->ifa_data == nullptr) continue; struct rtnl_link_stats* link_state = reinterpret_cast(ifa->ifa_data); m_linkdata.previous = m_linkdata.current; m_linkdata.current.transmitted = link_state->tx_bytes; m_linkdata.current.received = link_state->rx_bytes; m_linkdata.current.time = chrono::system_clock::now(); break; } } freeifaddrs(ifaddr); return match; } string ip() { if (!test_interface()) throw network_error("Interface is not up"); if (!query_interface()) throw network_error("Failed to query interface"); return m_linkdata.ip_address; } string downspeed(int minwidth = 3) { if (!query_interface()) throw network_error("Failed to query interface"); float bytes_diff = m_linkdata.current.received - m_linkdata.previous.received; float time_diff = chrono::duration_cast(m_linkdata.current.time - m_linkdata.previous.time) .count(); float speed = bytes_diff / time_diff; speed /= 1000; // convert to KB int suffix_n = 0; vector suffixes{"KB", "MB", "GB"}; while (speed >= 1000 && suffix_n < (int)suffixes.size() - 1) { suffix_n++; speed /= 1000; } return string_util::from_stream(stringstream() << std::setw(minwidth) << std::setfill(' ') << std::setprecision(0) << std::fixed << speed << " " << suffixes[suffix_n] << "/s"); } string upspeed(int minwidth = 3) { if (!query_interface()) throw network_error("Failed to query interface"); float bytes_diff = m_linkdata.current.transmitted - m_linkdata.previous.transmitted; float time_diff = chrono::duration_cast(m_linkdata.current.time - m_linkdata.previous.time) .count(); float speed = bytes_diff / time_diff; speed /= 1000; // convert to KB int suffix_n = 0; vector suffixes{"KB", "MB", "GB"}; while (speed >= 1000 && suffix_n < (int)suffixes.size() - 1) { suffix_n++; speed /= 1000; } return string_util::from_stream(stringstream() << std::setw(minwidth) << std::setfill(' ') << std::setprecision(0) << std::fixed << speed << " " << suffixes[suffix_n] << "/s"); } protected: unique_ptr m_ping; string m_interface; string m_ip; struct ifreq m_data; int m_fd = 0; linkdata_t m_linkdata; chrono::system_clock::time_point m_last_query; }; // }}} // class: wired_network {{{ class wired_network : public network { public: explicit wired_network(string interface) : network(interface) { struct ethtool_cmd e; e.cmd = ETHTOOL_GSET; m_data.ifr_data = (caddr_t)&e; if (ioctl(m_fd, SIOCETHTOOL, &m_data) == 0) m_linkspeed = (e.speed == USHRT_MAX ? 0 : e.speed); } string link_speed() { return string((m_linkspeed == 0 ? "???" : to_string(m_linkspeed)) + " Mbit/s"); } private: int m_linkspeed = 0; }; // }}} // class: wireless_network {{{ struct wireless_info { std::bitset<5> flags; string essid{IW_ESSID_MAX_SIZE + 1}; int quality = 0; int quality_max = 0; int quality_avg = 0; int signal = 0; int signal_max = 0; int noise = 0; int noise_max = 0; int bitrate = 0; double frequency = 0; }; enum wireless_flags { ESSID = 0, QUALITY = 1, SIGNAL = 2, NOISE = 3, FREQUENCY = 4, }; class wireless_network : public network { public: wireless_network(string interface) : network(interface) { std::strcpy((char*)&m_iw.ifr_ifrn.ifrn_name, m_interface.c_str()); if (!m_info) m_info.reset(new wireless_info()); } string essid() { if (!query_interface()) return ""; if (!m_info->flags.test(wireless_flags::ESSID)) return ""; return m_info->essid; } float signal_quality() { if (!query_interface()) return 0; if (m_info->flags.test(wireless_flags::QUALITY)) return 2 * (signal_dbm() + 100); return 0; } float signal_dbm() { if (!query_interface()) return 0; if (m_info->flags.test(wireless_flags::QUALITY)) return m_info->quality + m_info->noise - 256; return 0; } protected: bool query_interface() { if ((chrono::system_clock::now() - m_last_query) < chrono::seconds(1)) return true; network::query_interface(); auto ifname = m_interface.c_str(); auto socket_fd = iw_sockets_open(); if (socket_fd == -1) return false; auto on_exit = scope_util::make_exit_handler<>([&]() { iw_sockets_close(socket_fd); }); { wireless_config wcfg; if (iw_get_basic_config(socket_fd, ifname, &wcfg) == -1) return false; // reset flags m_info->flags.none(); if (wcfg.has_essid && wcfg.essid_on) { m_info->essid = {wcfg.essid, 0, IW_ESSID_MAX_SIZE}; m_info->flags |= wireless_flags::ESSID; } if (wcfg.has_freq) { m_info->frequency = wcfg.freq; m_info->flags |= wireless_flags::FREQUENCY; } if (wcfg.mode == IW_MODE_ADHOC) return true; iwrange range; if (iw_get_range_info(socket_fd, ifname, &range) == -1) return false; iwstats stats; if (iw_get_stats(socket_fd, ifname, &stats, &range, 1) == -1) return false; if (stats.qual.updated & IW_QUAL_RCPI) { if (!(stats.qual.updated & IW_QUAL_QUAL_INVALID)) { m_info->quality = stats.qual.qual; m_info->quality_max = range.max_qual.qual; m_info->quality_avg = range.avg_qual.qual; m_info->flags |= wireless_flags::QUALITY; } if (stats.qual.updated & IW_QUAL_RCPI) { if (!(stats.qual.updated & IW_QUAL_LEVEL_INVALID)) { m_info->signal = stats.qual.level / 2.0 - 110 + 0.5; m_info->flags |= wireless_flags::SIGNAL; } if (!(stats.qual.updated & IW_QUAL_NOISE_INVALID)) { m_info->noise = stats.qual.noise / 2.0 - 110 + 0.5; m_info->flags |= wireless_flags::NOISE; } } else { if ((stats.qual.updated & IW_QUAL_DBM) || stats.qual.level > range.max_qual.level) { if (!(stats.qual.updated & IW_QUAL_LEVEL_INVALID)) { m_info->signal = stats.qual.level; if (m_info->signal > 63) m_info->signal -= 256; m_info->flags |= wireless_flags::SIGNAL; } if (!(stats.qual.updated & IW_QUAL_NOISE_INVALID)) { m_info->noise = stats.qual.noise; if (m_info->noise > 63) m_info->noise -= 256; m_info->flags |= wireless_flags::NOISE; } } else { if (!(stats.qual.updated & IW_QUAL_LEVEL_INVALID)) { m_info->signal = stats.qual.level; m_info->signal_max = range.max_qual.level; m_info->flags |= wireless_flags::SIGNAL; } if (!(stats.qual.updated & IW_QUAL_NOISE_INVALID)) { m_info->noise = stats.qual.noise; m_info->noise_max = range.max_qual.noise; m_info->flags |= wireless_flags::NOISE; } } } } else { if (!(stats.qual.updated & IW_QUAL_QUAL_INVALID)) { m_info->quality = stats.qual.qual; m_info->flags |= wireless_flags::QUALITY; } if (!(stats.qual.updated & IW_QUAL_LEVEL_INVALID)) { m_info->quality = stats.qual.level; m_info->flags |= wireless_flags::SIGNAL; } if (!(stats.qual.updated & IW_QUAL_NOISE_INVALID)) { m_info->quality = stats.qual.noise; m_info->flags |= wireless_flags::NOISE; } } // struct iwreq wrq; // if (iw_get_ext(socket_fd, ifname, SIOCGIWRATE, &wrq) != -1) // m_info->bitrate = wrq.u.bitrate.value; return true; } } private: struct iwreq m_iw; shared_ptr m_info; }; // }}} inline bool is_wireless_interface(string ifname) { return file_util::exists("/sys/class/net/" + ifname + "/wireless"); } } LEMONBUDDY_NS_END