/* Copyright (C) 2011 Srivats P. This file is part of "Ostinato" This is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see */ #include "linuxport.h" #include "interfaceinfo.h" #include "linuxutils.h" #ifdef Q_OS_LINUX #include "../common/qtport.h" #include #include #include #include #include #include #include #include #if (LIBNL_VER_NUM > 0x0302) || ((LIBNL_VER_NUM == 0x0302) && (LIBNL_VER_MIC >= 26)) #include #endif #include #include #include #include #include #include QList LinuxPort::allPorts_; LinuxPort::StatsMonitor *LinuxPort::monitor_; const quint32 kMaxValue32 = 0xffffffff; const quint64 kMaxValue64 = 0xffffffffffffffffULL; #ifdef HAVE_IFLA_STATS64 #define X_IFLA_STATS IFLA_STATS64 typedef struct rtnl_link_stats64 x_rtnl_link_stats; #else #define X_IFLA_STATS IFLA_STATS typedef struct rtnl_link_stats x_rtnl_link_stats; #endif nl_sock *LinuxPort::netSock_{nullptr}; nl_cache *LinuxPort::linkCache_{nullptr}; nl_cache *LinuxPort::addressCache_{nullptr}; nl_cache *LinuxPort::routeCache_{nullptr}; LinuxPort::LinuxPort(int id, const char *device) : PcapPort(id, device) { isPromisc_ = true; clearPromisc_ = false; populateInterfaceInfo(); // We don't need per port Rx/Tx monitors for Linux // No need to stop them because we start them only in // PcapPort::init which has not yet been called delete monitorRx_; delete monitorTx_; monitorRx_ = monitorTx_ = NULL; // We have one monitor for both Rx/Tx of all ports if (!monitor_) monitor_ = new StatsMonitor(); data_.set_is_exclusive_control(hasExclusiveControl()); minPacketSetSize_ = 16; qDebug("adding dev to all ports list <%s>", device); allPorts_.append(this); // A port can support either 32 or 64 bit stats - we will attempt // to guess this for each port and initialize this variable at // run time when the counter wraps around maxStatsValue_ = 0; } LinuxPort::~LinuxPort() { qDebug("In %s", __FUNCTION__); allPorts_.removeAll(this); if (monitor_->isRunning()) { monitor_->stop(); monitor_->wait(); } if (clearPromisc_) { int sd = socket(AF_INET, SOCK_DGRAM, 0); struct ifreq ifr; memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, name(), sizeof(ifr.ifr_name)); if (ioctl(sd, SIOCGIFFLAGS, &ifr) != -1) { if (ifr.ifr_flags & IFF_PROMISC) { ifr.ifr_flags &= ~IFF_PROMISC; if (ioctl(sd, SIOCSIFFLAGS, &ifr) == -1) qDebug("Failed clearing promisc flag. SIOCSIFFLAGS failed: %s", strerror(errno)); } } else qDebug("Failed clearing promisc flag. SIOCGIFFLAGS failed: %s", strerror(errno)); close(sd); } } void LinuxPort::fetchHostNetworkInfo() { netSock_ = nl_socket_alloc(); if (!netSock_) { qWarning("Failed to open netlink socket"); return; } if (nl_connect(netSock_, NETLINK_ROUTE) < 0) { qWarning("Failed to connect netlink socket"); return; } if (rtnl_link_alloc_cache(netSock_, AF_UNSPEC, &linkCache_) < 0) { qWarning("Failed to populate link cache"); return; } if (rtnl_addr_alloc_cache(netSock_, &addressCache_) < 0) { qWarning("Failed to populate addr cache"); return; } if (rtnl_route_alloc_cache(netSock_, AF_UNSPEC, 0, &routeCache_) < 0) { qWarning("Failed to populate addr cache"); return; } } void LinuxPort::freeHostNetworkInfo() { nl_cache_put(routeCache_); nl_cache_put(addressCache_); nl_cache_put(linkCache_); nl_socket_free(netSock_); } void LinuxPort::init() { if (!monitor_->isRunning()) monitor_->start(); monitor_->waitForSetupFinished(); if (!isPromisc_) addNote("Non Promiscuous Mode"); AbstractPort::init(); } OstProto::LinkState LinuxPort::linkState() { return linkState_; } bool LinuxPort::hasExclusiveControl() { // TODO return false; } bool LinuxPort::setExclusiveControl(bool /*exclusive*/) { // TODO return false; } void LinuxPort::populateInterfaceInfo() { // // Find Mac // if (!linkCache_) { qWarning("rtnetlink link cache empty for %s", name()); return; } rtnl_link *link = rtnl_link_get_by_name(linkCache_, name()); if (!link) { qWarning("rtnetlink link not found for %s", name()); return; } nl_addr *addr = rtnl_link_get_addr(link); if (!addr) { qWarning("rtnetlink mac addr not found for %s", name()); return; } if (nl_addr_get_family(addr) != AF_LLC) { qWarning("unexpected mac family found for %s:%d", name(), nl_addr_get_family(addr)); rtnl_link_put(link); return; } if (nl_addr_get_prefixlen(addr) != 48) { qWarning("unexpected mac length for %s:%d", name(), nl_addr_get_prefixlen(addr)); rtnl_link_put(link); return; } quint64 mac = qFromBigEndian(nl_addr_get_binary_addr(addr)) >> 16; if (!mac) { qWarning("zero mac for %s - skipping", name()); rtnl_link_put(link); return; } interfaceInfo_ = new InterfaceInfo; interfaceInfo_->speed = sysfsAttrib(name(), "speed").toDouble(); interfaceInfo_->mtu = rtnl_link_get_mtu(link); int ifIndex = rtnl_link_get_ifindex(link); rtnl_link_put(link); interfaceInfo_->mac = mac; // // Find gateways // quint32 gw4 = 0; UInt128 gw6 = 0; for (rtnl_route *rt = routeCache_ ? (rtnl_route*) nl_cache_get_first(routeCache_) : 0; rt && (!gw4 || !gw6); rt = (rtnl_route*) nl_cache_get_next(OBJ_CAST(rt))) { if (rtnl_route_get_table(rt) != RT_TABLE_MAIN) // we want only main RTT continue; nl_addr *pfx = rtnl_route_get_dst(rt); if (nl_addr_get_len(pfx)) // default route has len = 0 continue; if (!rtnl_route_get_nnexthops(rt)) // at least one nh is required continue; rtnl_nexthop *nh = rtnl_route_nexthop_n(rt, 0); if (rtnl_route_nh_get_ifindex(nh) != ifIndex) // ignore gw on other links continue; if (!gw4 && rtnl_route_get_family(rt) == AF_INET) { nl_addr *gwa = rtnl_route_nh_get_gateway(nh); if (gwa) gw4 = qFromBigEndian(nl_addr_get_binary_addr(gwa)); } else if (!gw6 && rtnl_route_get_family(rt) == AF_INET6) { nl_addr *gwa = rtnl_route_nh_get_gateway(nh); if (gwa) gw6 = UInt128((quint8*) nl_addr_get_binary_addr(gwa)); } } // // Find self IP // if (!addressCache_) { qWarning("rtnetlink address cache empty for %s", name()); return; } rtnl_addr *l3addr = (rtnl_addr*) nl_cache_get_first(addressCache_); while (l3addr) { if (rtnl_addr_get_ifindex(l3addr) == ifIndex) { if (rtnl_addr_get_family(l3addr) == AF_INET) { Ip4Config ip; ip.address = qFromBigEndian( nl_addr_get_binary_addr( rtnl_addr_get_local(l3addr))); ip.prefixLength = rtnl_addr_get_prefixlen(l3addr); ip.gateway = gw4; interfaceInfo_->ip4.append(ip); } else if (rtnl_addr_get_family(l3addr) == AF_INET6) { Ip6Config ip; ip.address = UInt128((quint8*)nl_addr_get_binary_addr( rtnl_addr_get_local(l3addr))); ip.prefixLength = rtnl_addr_get_prefixlen(l3addr); ip.gateway = gw6; interfaceInfo_->ip6.append(ip); } } l3addr = (rtnl_addr*) nl_cache_get_next((nl_object*)l3addr); } } LinuxPort::StatsMonitor::StatsMonitor() : QThread() { setObjectName("StatsMon"); stop_ = false; setupDone_ = false; ioctlSocket_ = socket(AF_INET, SOCK_DGRAM, 0); Q_ASSERT(ioctlSocket_ >= 0); } LinuxPort::StatsMonitor::~StatsMonitor() { close(ioctlSocket_); } void LinuxPort::StatsMonitor::run() { if (netlinkStats() < 0) { qDebug("netlink stats not available - using /proc stats"); procStats(); } } void LinuxPort::StatsMonitor::procStats() { PortStats **portStats; int fd; QByteArray buf; int len; char *p, *end; int count, index; const char* fmtopt[] = { "%llu%llu%llu%llu%llu%llu%u%u%llu%llu%u%u%u%u%u%u\n", "%llu%llu%llu%llu%llu%llu%n%n%llu%llu%u%u%u%u%u%n\n", }; const char *fmt; // // We first setup stuff before we start polling for stats // fd = open("/proc/net/dev", O_RDONLY); if (fd < 0) { qWarning("Unable to open /proc/net/dev - no stats will be available"); return; } buf.fill('\0', 8192); len = read(fd, (void*) buf.data(), buf.size()); if (len < 0) { qWarning("initial buffer size is too small. no stats will be available"); return; } p = buf.data(); end = p + len; // Select scanf format if (strstr(buf, "compressed")) fmt = fmtopt[0]; else fmt = fmtopt[1]; // Count number of lines - number of ports is 2 less than number of lines count = 0; while (p < end) { if (*p == '\n') count++; p++; } count -= 2; if (count <= 0) { qWarning("no ports in /proc/dev/net - no stats will be available"); return; } portStats = (PortStats**) calloc(count, sizeof(PortStats)); Q_ASSERT(portStats != NULL); // // Populate the port stats array // p = buf.data(); // Skip first two lines while (*p != '\n') p++; p++; while (*p != '\n') p++; p++; index = 0; while (p < end) { char* q; // Skip whitespace while ((p < end) && (*p == ' ')) p++; q = p; // Get interface name while ((q < end) && (*q != ':') && (*q != '\n')) q++; if ((q < end) && (*q == ':')) { foreach(LinuxPort* port, allPorts_) { if (strncmp(port->name(), p, int(q-p)) == 0) { portStats[index] = &(port->stats_); if (setPromisc(port->name())) port->clearPromisc_ = true; else port->isPromisc_ = false; break; } } } index++; // Skip till newline p = q; while (*p != '\n') p++; p++; } Q_ASSERT(index == count); qDebug("stats for %d ports setup", count); setupDone_ = true; // // We are all set - Let's start polling for stats! // while (!stop_) { lseek(fd, 0, SEEK_SET); len = read(fd, (void*) buf.data(), buf.size()); if (len < 0) { if (buf.size() > 1*1024*1024) { qWarning("buffer size hit limit. no more stats"); return; } qDebug("doubling buffer size. curr = %d", buf.size()); buf.resize(buf.size() * 2); continue; } p = buf.data(); end = p + len; // Skip first two lines while (*p != '\n') p++; p++; while (*p != '\n') p++; p++; index = 0; while (p < end) { uint dummy; quint64 rxBytes, rxPkts; quint64 rxErrors, rxDrops, rxFifo, rxFrame; quint64 txBytes, txPkts; // Skip interface name - we assume the number and order of ports // won't change since we parsed the output before we started polling while ((p < end) && (*p != ':') && (*p != '\n')) p++; if (p >= end) break; if (*p == '\n') { index++; continue; } p++; sscanf(p, fmt, &rxBytes, &rxPkts, &rxErrors, &rxDrops, &rxFifo, &rxFrame, &dummy, &dummy, &txBytes, &txPkts, &dummy, &dummy, &dummy, &dummy, &dummy, &dummy); if (index < count) { AbstractPort::PortStats *stats = portStats[index]; if (stats) { // TODO: fix the pps/Bps calc similar to netlink stats stats->rxPps = ((rxPkts >= stats->rxPkts) ? rxPkts - stats->rxPkts : rxPkts + (kMaxValue32 - stats->rxPkts)) / kRefreshFreq_; stats->rxBps = ((rxBytes >= stats->rxBytes) ? rxBytes - stats->rxBytes : rxBytes + (kMaxValue32 - stats->rxBytes)) / kRefreshFreq_; stats->rxPkts = rxPkts; stats->rxBytes = rxBytes; stats->txPps = ((txPkts >= stats->txPkts) ? txPkts - stats->txPkts : txPkts + (kMaxValue32 - stats->txPkts)) / kRefreshFreq_; stats->txBps = ((txBytes >= stats->txBytes) ? txBytes - stats->txBytes : txBytes + (kMaxValue32 - stats->txBytes)) / kRefreshFreq_; stats->txPkts = txPkts; stats->txBytes = txBytes; stats->rxDrops = rxDrops; stats->rxErrors = rxErrors; stats->rxFifoErrors = rxFifo; stats->rxFrameErrors = rxFrame; } } while (*p != '\n') p++; p++; index++; } QThread::sleep(kRefreshFreq_); } free(portStats); } int LinuxPort::StatsMonitor::netlinkStats() { QHash portStats; QHash portMaxStatsValue; QHash linkState; int fd; struct sockaddr_nl local; struct sockaddr_nl kernel; QByteArray buf; int len, count; struct { struct nlmsghdr nlh; struct rtgenmsg rtg; } ifListReq; struct iovec iov; struct msghdr msg; struct nlmsghdr *nlm; bool done = false; // // We first setup stuff before we start polling for stats // fd = socket(AF_NETLINK, SOCK_RAW, NETLINK_ROUTE); if (fd < 0) { qWarning("Unable to open netlink socket (errno %d)", errno); return -1; } memset(&local, 0, sizeof(local)); local.nl_family = AF_NETLINK; if (bind(fd, (struct sockaddr*) &local, sizeof(local)) < 0) { qWarning("Unable to bind netlink socket (errno %d)", errno); return -1; } memset(&ifListReq, 0, sizeof(ifListReq)); ifListReq.nlh.nlmsg_len = sizeof(ifListReq); ifListReq.nlh.nlmsg_type = RTM_GETLINK; ifListReq.nlh.nlmsg_flags = NLM_F_REQUEST | NLM_F_DUMP; ifListReq.nlh.nlmsg_pid = 0; ifListReq.rtg.rtgen_family = AF_PACKET; buf.fill('\0', 1024); msg.msg_name = &kernel; msg.msg_namelen = sizeof(kernel); msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_control = NULL; msg.msg_controllen = 0; msg.msg_flags = 0; qDebug("nlmsg_flags = %x", ifListReq.nlh.nlmsg_flags); if (send(fd, (void*)&ifListReq, sizeof(ifListReq), 0) < 0) { qWarning("Unable to send GETLINK request (errno %d)", errno); return -1; } count = 0; _retry: // Find required size of buffer and resize accordingly while (1) { iov.iov_base = buf.data(); iov.iov_len = buf.size(); msg.msg_flags = 0; // Peek at reply to check buffer size required len = recvmsg(fd, &msg, MSG_PEEK|MSG_TRUNC); if (len < 0) { if (errno == EINTR || errno == EAGAIN) continue; qWarning("netlink recv error %d", errno); return -1; } else if (len == 0) { qWarning("netlink closed the socket on my face!"); return -1; } else { if (msg.msg_flags & MSG_TRUNC) { if (len == buf.size()) // Older Kernel returns truncated size { qDebug("netlink buffer size %d not enough", buf.size()); qDebug("retrying with double the size"); // Double the size and retry buf.resize(buf.size()*2); continue; } else // Newer Kernel returns actual size required { qDebug("netlink required buffer size = %d", len); buf.resize(len); continue; } } else qDebug("buffer size %d enough for netlink", buf.size()); break; } } msg.msg_flags = 0; // Actually receive the reply now len = recvmsg(fd, &msg, 0); if (len < 0) { if (errno == EINTR || errno == EAGAIN) goto _retry; qWarning("netlink recv error %d", errno); return -1; } else if (len == 0) { qWarning("netlink socket closed unexpectedly"); return -1; } // // Populate the port stats hash table // nlm = (struct nlmsghdr*) buf.data(); while (NLMSG_OK(nlm, (uint)len)) { struct ifinfomsg *ifi; struct rtattr *rta; int rtaLen; char ifname[64] = ""; if (nlm->nlmsg_type == NLMSG_DONE) { done = true; break; } if (nlm->nlmsg_type == NLMSG_ERROR) { struct nlmsgerr *err = (struct nlmsgerr*) NLMSG_DATA(nlm); qDebug("RTNETLINK error %d", err->error); done = true; break; } Q_ASSERT(nlm->nlmsg_type == RTM_NEWLINK); ifi = (struct ifinfomsg*) NLMSG_DATA(nlm); rta = IFLA_RTA(ifi); rtaLen = len - NLMSG_LENGTH(sizeof(*ifi)); while (RTA_OK(rta, rtaLen)) { if (rta->rta_type == IFLA_IFNAME) { strncpy(ifname, (char*)RTA_DATA(rta), RTA_PAYLOAD(rta)); ifname[RTA_PAYLOAD(rta)] = 0; break; } rta = RTA_NEXT(rta, rtaLen); } qDebug("if: %s(%d)", ifname, ifi->ifi_index); foreach(LinuxPort* port, allPorts_) { if (strcmp(port->name(), ifname) == 0) { portStats[uint(ifi->ifi_index)] = &(port->stats_); portMaxStatsValue[uint(ifi->ifi_index)] = &(port->maxStatsValue_); linkState[uint(ifi->ifi_index)] = &(port->linkState_); if (setPromisc(port->name())) port->clearPromisc_ = true; else port->isPromisc_ = false; count++; break; } } nlm = NLMSG_NEXT(nlm, len); } if (!done) goto _retry; qDebug("port count = %d\n", count); if (count <= 0) { qWarning("no ports in RTNETLINK GET_LINK - no stats will be available"); return - 1; } qDebug("stats for %d ports setup", count); setupDone_ = true; // // We are all set - Let's start polling for stats! // while (!stop_) { if (send(fd, (void*)&ifListReq, sizeof(ifListReq), 0) < 0) { qWarning("Unable to send GETLINK request (errno %d)", errno); goto _try_later; } done = false; _retry_recv: msg.msg_flags = 0; len = recvmsg(fd, &msg, 0); if (len < 0) { if (errno == EINTR || errno == EAGAIN) goto _retry_recv; qWarning("netlink recv error %d", errno); break; } else if (len == 0) { qWarning("netlink socket closed unexpectedly"); break; } nlm = (struct nlmsghdr*) buf.data(); while (NLMSG_OK(nlm, (uint)len)) { struct ifinfomsg *ifi; struct rtattr *rta; int rtaLen; if (nlm->nlmsg_type == NLMSG_DONE) { done = true; break; } if (nlm->nlmsg_type == NLMSG_ERROR) { struct nlmsgerr *err = (struct nlmsgerr*) NLMSG_DATA(nlm); qDebug("RTNETLINK error: %s", strerror(-err->error)); done = true; break; } Q_ASSERT(nlm->nlmsg_type == RTM_NEWLINK); ifi = (struct ifinfomsg*) NLMSG_DATA(nlm); rta = IFLA_RTA(ifi); rtaLen = len - NLMSG_LENGTH(sizeof(*ifi)); while (RTA_OK(rta, rtaLen)) { if (rta->rta_type == X_IFLA_STATS) { x_rtnl_link_stats *rtnlStats = (x_rtnl_link_stats*) RTA_DATA(rta); AbstractPort::PortStats *stats = portStats[ifi->ifi_index]; quint64 *maxStatsValue = portMaxStatsValue[ifi->ifi_index]; OstProto::LinkState *state = linkState[ifi->ifi_index]; if (!stats) break; if (rtnlStats->rx_packets >= stats->rxPkts) { stats->rxPps = (rtnlStats->rx_packets - stats->rxPkts) / kRefreshFreq_; } else { if (*maxStatsValue == 0) { *maxStatsValue = stats->rxPkts > kMaxValue32 ? kMaxValue64 : kMaxValue32; } stats->rxPps = ((*maxStatsValue - stats->rxPkts) + rtnlStats->rx_packets) / kRefreshFreq_; } if (rtnlStats->rx_bytes >= stats->rxBytes) { stats->rxBps = (rtnlStats->rx_bytes - stats->rxBytes) / kRefreshFreq_; } else { if (*maxStatsValue == 0) { *maxStatsValue = stats->rxBytes > kMaxValue32 ? kMaxValue64 : kMaxValue32; } stats->rxBps = ((*maxStatsValue - stats->rxBytes) + rtnlStats->rx_bytes) / kRefreshFreq_; } stats->rxPkts = rtnlStats->rx_packets; stats->rxBytes = rtnlStats->rx_bytes; if (rtnlStats->tx_packets >= stats->txPkts) { stats->txPps = (rtnlStats->tx_packets - stats->txPkts) / kRefreshFreq_; } else { if (*maxStatsValue == 0) { *maxStatsValue = stats->txPkts > kMaxValue32 ? kMaxValue64 : kMaxValue32; } stats->txPps = ((*maxStatsValue - stats->txPkts) + rtnlStats->tx_packets) / kRefreshFreq_; } if (rtnlStats->tx_bytes >= stats->txBytes) { stats->txBps = (rtnlStats->tx_bytes - stats->txBytes) / kRefreshFreq_; } else { if (*maxStatsValue == 0) { *maxStatsValue = stats->txBytes > kMaxValue32 ? kMaxValue64 : kMaxValue32; } stats->txBps = ((*maxStatsValue - stats->txBytes) + rtnlStats->tx_bytes) / kRefreshFreq_; } stats->txPkts = rtnlStats->tx_packets; stats->txBytes = rtnlStats->tx_bytes; // TODO: export detailed error stats stats->rxDrops = rtnlStats->rx_dropped + rtnlStats->rx_missed_errors; stats->rxErrors = rtnlStats->rx_errors; stats->rxFifoErrors = rtnlStats->rx_fifo_errors; stats->rxFrameErrors = rtnlStats->rx_crc_errors + rtnlStats->rx_length_errors + rtnlStats->rx_over_errors + rtnlStats->rx_frame_errors; Q_ASSERT(state); *state = ifi->ifi_flags & IFF_RUNNING ? OstProto::LinkStateUp : OstProto::LinkStateDown; break; } rta = RTA_NEXT(rta, rtaLen); } nlm = NLMSG_NEXT(nlm, len); } if (!done) goto _retry_recv; _try_later: QThread::sleep(kRefreshFreq_); } portStats.clear(); linkState.clear(); return 0; } int LinuxPort::StatsMonitor::setPromisc(const char * portName) { struct ifreq ifr; memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, portName, sizeof(ifr.ifr_name)); if (ioctl(ioctlSocket_, SIOCGIFFLAGS, &ifr) != -1) { if ((ifr.ifr_flags & IFF_PROMISC) == 0) { ifr.ifr_flags |= IFF_PROMISC; if (ioctl(ioctlSocket_, SIOCSIFFLAGS, &ifr) != -1) { return 1; } else { qDebug("%s: failed to set promisc; " "SIOCSIFFLAGS failed (%s)", portName, strerror(errno)); } } } else { qDebug("%s: failed to set promisc; SIOCGIFFLAGS failed (%s)", portName, strerror(errno)); } return 0; } void LinuxPort::StatsMonitor::stop() { stop_ = true; } bool LinuxPort::StatsMonitor::waitForSetupFinished(int msecs) { QTime t; t.start(); while (!setupDone_) { if (t.elapsed() > msecs) return false; QThread::msleep(10); } return true; } #endif