/* Copyright (C) 2010 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 "pcapport.h" #include "devicemanager.h" #include "packetbuffer.h" #include #ifdef Q_OS_WIN32 #include #endif pcap_if_t *PcapPort::deviceList_ = NULL; #if defined(Q_OS_LINUX) typedef struct timeval TimeStamp; static void inline getTimeStamp(TimeStamp *stamp) { gettimeofday(stamp, NULL); } // Returns time diff in usecs between end and start static long inline udiffTimeStamp(const TimeStamp *start, const TimeStamp *end) { struct timeval diff; long usecs; timersub(end, start, &diff); usecs = diff.tv_usec; if (diff.tv_sec) usecs += diff.tv_sec*1e6; return usecs; } #elif defined(Q_OS_WIN32) static quint64 gTicksFreq; typedef LARGE_INTEGER TimeStamp; static void inline getTimeStamp(TimeStamp* stamp) { QueryPerformanceCounter(stamp); } static long inline udiffTimeStamp(const TimeStamp *start, const TimeStamp *end) { if (end->QuadPart >= start->QuadPart) return (end->QuadPart - start->QuadPart)*long(1e6)/gTicksFreq; else { // FIXME: incorrect! what's the max value for this counter before // it rolls over? return (start->QuadPart)*long(1e6)/gTicksFreq; } } #else typedef int TimeStamp; static void inline getTimeStamp(TimeStamp*) {} static long inline udiffTimeStamp(const TimeStamp*, const TimeStamp*) { return 0; } #endif PcapPort::PcapPort(int id, const char *device) : AbstractPort(id, device) { monitorRx_ = new PortMonitor(device, kDirectionRx, &stats_); monitorTx_ = new PortMonitor(device, kDirectionTx, &stats_); transmitter_ = new PortTransmitter(device); capturer_ = new PortCapturer(device); emulXcvr_ = new EmulationTransceiver(device, deviceManager_); if (!monitorRx_->handle() || !monitorTx_->handle()) isUsable_ = false; if (!deviceList_) { char errbuf[PCAP_ERRBUF_SIZE]; if (pcap_findalldevs(&deviceList_, errbuf) == -1) qDebug("Error in pcap_findalldevs_ex: %s\n", errbuf); } for (pcap_if_t *dev = deviceList_; dev != NULL; dev = dev->next) { if (strcmp(device, dev->name) == 0) { #ifdef Q_OS_WIN32 data_.set_name(QString("if%1").arg(id).toStdString()); #else if (dev->name) data_.set_name(dev->name); #endif if (dev->description) data_.set_description(dev->description); //! \todo set port IP addr also } } } void PcapPort::init() { if (!monitorTx_->isDirectional()) transmitter_->useExternalStats(&stats_); transmitter_->setHandle(monitorRx_->handle()); updateNotes(); monitorRx_->start(); monitorTx_->start(); } PcapPort::~PcapPort() { qDebug("In %s", __FUNCTION__); if (monitorRx_) monitorRx_->stop(); if (monitorTx_) monitorTx_->stop(); delete emulXcvr_; delete capturer_; delete transmitter_; if (monitorRx_) monitorRx_->wait(); delete monitorRx_; if (monitorTx_) monitorTx_->wait(); delete monitorTx_; } void PcapPort::updateNotes() { QString notes; if ((!monitorRx_->isPromiscuous()) || (!monitorTx_->isPromiscuous())) notes.append("
  • Non Promiscuous Mode
  • "); if (!monitorRx_->isDirectional() && !hasExclusiveControl()) notes.append("
  • Rx Frames/Bytes: Includes non Ostinato Tx pkts also (Tx by Ostinato are not included)
  • "); if (!monitorTx_->isDirectional() && !hasExclusiveControl()) notes.append("
  • Tx Frames/Bytes: Only Ostinato Tx pkts (Tx by others NOT included)
  • "); if (notes.isEmpty()) data_.set_notes(""); else data_.set_notes(QString("Limitation(s)" "
      %1
    " "Rx/Tx Rates are also subject to above limitation(s)"). arg(notes).toStdString()); } bool PcapPort::setRateAccuracy(AbstractPort::Accuracy accuracy) { if (transmitter_->setRateAccuracy(accuracy)) { AbstractPort::setRateAccuracy(accuracy); return true; } return false; } void PcapPort::startDeviceEmulation() { emulXcvr_->start(); } void PcapPort::stopDeviceEmulation() { emulXcvr_->stop(); } int PcapPort::sendEmulationPacket(PacketBuffer *pktBuf) { return emulXcvr_->transmitPacket(pktBuf); } /* * ------------------------------------------------------------------- * * Port Monitor * ------------------------------------------------------------------- * */ PcapPort::PortMonitor::PortMonitor(const char *device, Direction direction, AbstractPort::PortStats *stats) { int ret; char errbuf[PCAP_ERRBUF_SIZE] = ""; bool noLocalCapture; direction_ = direction; isDirectional_ = true; isPromisc_ = true; noLocalCapture = true; stats_ = stats; stop_ = false; _retry: #ifdef Q_OS_WIN32 int flags = 0; if (isPromisc_) flags |= PCAP_OPENFLAG_PROMISCUOUS; if (noLocalCapture) flags |= PCAP_OPENFLAG_NOCAPTURE_LOCAL; handle_ = pcap_open(device, 64 /* FIXME */, flags, 1000 /* ms */, NULL, errbuf); #else handle_ = pcap_open_live(device, 64 /* FIXME */, int(isPromisc_), 1000 /* ms */, errbuf); #endif if (handle_ == NULL) { if (isPromisc_ && QString(errbuf).contains("promiscuous")) { qDebug("Can't set promiscuous mode, trying non-promisc %s", device); isPromisc_ = false; goto _retry; } else if (noLocalCapture && QString(errbuf).contains("loopback")) { qDebug("Can't set no local capture mode %s", device); noLocalCapture = false; goto _retry; } else goto _open_error; } #ifdef Q_OS_WIN32 // pcap_setdirection() API is not supported in Windows. // NOTE: WinPcap 4.1.1 and above exports a dummy API that returns -1 // but since we would like to work with previous versions of WinPcap // also, we assume the API does not exist ret = -1; #else switch (direction_) { case kDirectionRx: ret = pcap_setdirection(handle_, PCAP_D_IN); break; case kDirectionTx: ret = pcap_setdirection(handle_, PCAP_D_OUT); break; default: ret = -1; // avoid 'may be used uninitialized' warning Q_ASSERT(false); } #endif if (ret < 0) goto _set_direction_error; return; _set_direction_error: qDebug("Error setting direction(%d) %s: %s\n", direction, device, pcap_geterr(handle_)); isDirectional_ = false; return; _open_error: qDebug("%s: Error opening port %s: %s\n", __FUNCTION__, device, errbuf); } PcapPort::PortMonitor::~PortMonitor() { if (handle_) pcap_close(handle_); } void PcapPort::PortMonitor::run() { while (!stop_) { int ret; struct pcap_pkthdr *hdr; const uchar *data; ret = pcap_next_ex(handle_, &hdr, &data); switch (ret) { case 1: switch (direction_) { case kDirectionRx: stats_->rxPkts++; stats_->rxBytes += hdr->len; break; case kDirectionTx: if (isDirectional_) { stats_->txPkts++; stats_->txBytes += hdr->len; } break; default: Q_ASSERT(false); } //! \todo TODO pkt/bit rates break; case 0: //qDebug("%s: timeout. continuing ...", __PRETTY_FUNCTION__); continue; case -1: qWarning("%s: error reading packet (%d): %s", __PRETTY_FUNCTION__, ret, pcap_geterr(handle_)); break; case -2: qWarning("%s: error reading packet (%d): %s", __PRETTY_FUNCTION__, ret, pcap_geterr(handle_)); break; default: qFatal("%s: Unexpected return value %d", __PRETTY_FUNCTION__, ret); } } } void PcapPort::PortMonitor::stop() { stop_ = true; pcap_breakloop(handle()); } /* * ------------------------------------------------------------------- * * Port Transmitter * ------------------------------------------------------------------- * */ PcapPort::PortTransmitter::PortTransmitter(const char *device) { char errbuf[PCAP_ERRBUF_SIZE] = ""; #ifdef Q_OS_WIN32 LARGE_INTEGER freq; if (QueryPerformanceFrequency(&freq)) gTicksFreq = freq.QuadPart; else Q_ASSERT_X(false, "PortTransmitter::PortTransmitter", "This Win32 platform does not support performance counter"); #endif state_ = kNotStarted; returnToQIdx_ = -1; loopDelay_ = 0; stop_ = false; stats_ = new AbstractPort::PortStats; usingInternalStats_ = true; handle_ = pcap_open_live(device, 64 /* FIXME */, 0, 1000 /* ms */, errbuf); if (handle_ == NULL) goto _open_error; usingInternalHandle_ = true; return; _open_error: qDebug("%s: Error opening port %s: %s\n", __FUNCTION__, device, errbuf); usingInternalHandle_ = false; } PcapPort::PortTransmitter::~PortTransmitter() { if (usingInternalStats_) delete stats_; if (usingInternalHandle_) pcap_close(handle_); } bool PcapPort::PortTransmitter::setRateAccuracy( AbstractPort::Accuracy accuracy) { switch (accuracy) { case kHighAccuracy: udelayFn_ = udelay; qWarning("%s: rate accuracy set to High - busy wait", __FUNCTION__); break; case kLowAccuracy: udelayFn_ = QThread::usleep; qWarning("%s: rate accuracy set to Low - usleep", __FUNCTION__); break; default: qWarning("%s: unsupported rate accuracy value %d", __FUNCTION__, accuracy); return false; } return true; } void PcapPort::PortTransmitter::clearPacketList() { Q_ASSERT(!isRunning()); // \todo lock for packetSequenceList while(packetSequenceList_.size()) delete packetSequenceList_.takeFirst(); currentPacketSequence_ = NULL; repeatSequenceStart_ = -1; repeatSize_ = 0; packetCount_ = 0; returnToQIdx_ = -1; setPacketListLoopMode(false, 0, 0); } void PcapPort::PortTransmitter::loopNextPacketSet(qint64 size, qint64 repeats, long repeatDelaySec, long repeatDelayNsec) { currentPacketSequence_ = new PacketSequence; currentPacketSequence_->repeatCount_ = repeats; currentPacketSequence_->usecDelay_ = repeatDelaySec * long(1e6) + repeatDelayNsec/1000; repeatSequenceStart_ = packetSequenceList_.size(); repeatSize_ = size; packetCount_ = 0; packetSequenceList_.append(currentPacketSequence_); } bool PcapPort::PortTransmitter::appendToPacketList(long sec, long nsec, const uchar *packet, int length) { bool op = true; pcap_pkthdr pktHdr; pktHdr.caplen = pktHdr.len = length; pktHdr.ts.tv_sec = sec; pktHdr.ts.tv_usec = nsec/1000; if (currentPacketSequence_ == NULL || !currentPacketSequence_->hasFreeSpace(2*sizeof(pcap_pkthdr)+length)) { if (currentPacketSequence_ != NULL) { long usecs; usecs = (pktHdr.ts.tv_sec - currentPacketSequence_->lastPacket_->ts.tv_sec) * long(1e6); usecs += (pktHdr.ts.tv_usec - currentPacketSequence_->lastPacket_->ts.tv_usec); currentPacketSequence_->usecDelay_ = usecs; } //! \todo (LOW): calculate sendqueue size currentPacketSequence_ = new PacketSequence; packetSequenceList_.append(currentPacketSequence_); // Validate that the pkt will fit inside the new currentSendQueue_ Q_ASSERT(currentPacketSequence_->hasFreeSpace( sizeof(pcap_pkthdr) + length)); } if (currentPacketSequence_->appendPacket(&pktHdr, (u_char*) packet) < 0) { op = false; } packetCount_++; if (repeatSize_ > 0 && packetCount_ == repeatSize_) { qDebug("repeatSequenceStart_=%d, repeatSize_ = %llu", repeatSequenceStart_, repeatSize_); // Set the packetSequence repeatSize Q_ASSERT(repeatSequenceStart_ >= 0); Q_ASSERT(repeatSequenceStart_ < packetSequenceList_.size()); if (currentPacketSequence_ != packetSequenceList_[repeatSequenceStart_]) { PacketSequence *start = packetSequenceList_[repeatSequenceStart_]; currentPacketSequence_->usecDelay_ = start->usecDelay_; start->usecDelay_ = 0; start->repeatSize_ = packetSequenceList_.size() - repeatSequenceStart_; } repeatSize_ = 0; // End current pktSeq and trigger a new pktSeq allocation for next pkt currentPacketSequence_ = NULL; } return op; } void PcapPort::PortTransmitter::setHandle(pcap_t *handle) { if (usingInternalHandle_) pcap_close(handle_); handle_ = handle; usingInternalHandle_ = false; } void PcapPort::PortTransmitter::useExternalStats(AbstractPort::PortStats *stats) { if (usingInternalStats_) delete stats_; stats_ = stats; usingInternalStats_ = false; } void PcapPort::PortTransmitter::run() { //! \todo (MED) Stream Mode - continuous: define before implement // NOTE1: We can't use pcap_sendqueue_transmit() directly even on Win32 // 'coz of 2 reasons - there's no way of stopping it before all packets // in the sendQueue are sent out and secondly, stats are available only // when all packets have been sent - no periodic updates // // NOTE2: Transmit on the Rx Handle so that we can receive it back // on the Tx Handle to do stats // // NOTE3: Update pcapExtra counters - port TxStats will be updated in the // 'stats callback' function so that both Rx and Tx stats are updated // together const int kSyncTransmit = 1; int i; long overHead = 0; // overHead should be negative or zero qDebug("packetSequenceList_.size = %d", packetSequenceList_.size()); if (packetSequenceList_.size() <= 0) goto _exit; for(i = 0; i < packetSequenceList_.size(); i++) { qDebug("sendQ[%d]: rptCnt = %d, rptSz = %d, usecDelay = %ld", i, packetSequenceList_.at(i)->repeatCount_, packetSequenceList_.at(i)->repeatSize_, packetSequenceList_.at(i)->usecDelay_); qDebug("sendQ[%d]: pkts = %ld, usecDuration = %ld", i, packetSequenceList_.at(i)->packets_, packetSequenceList_.at(i)->usecDuration_); } state_ = kRunning; i = 0; while (i < packetSequenceList_.size()) { _restart: int rptSz = packetSequenceList_.at(i)->repeatSize_; int rptCnt = packetSequenceList_.at(i)->repeatCount_; for (int j = 0; j < rptCnt; j++) { for (int k = 0; k < rptSz; k++) { int ret; PacketSequence *seq = packetSequenceList_.at(i+k); #ifdef Q_OS_WIN32 TimeStamp ovrStart, ovrEnd; if (seq->usecDuration_ <= long(1e6)) // 1s { getTimeStamp(&ovrStart); ret = pcap_sendqueue_transmit(handle_, seq->sendQueue_, kSyncTransmit); if (ret >= 0) { stats_->txPkts += seq->packets_; stats_->txBytes += seq->bytes_; getTimeStamp(&ovrEnd); overHead += seq->usecDuration_ - udiffTimeStamp(&ovrStart, &ovrEnd); Q_ASSERT(overHead <= 0); } if (stop_) ret = -2; } else { ret = sendQueueTransmit(handle_, seq->sendQueue_, overHead, kSyncTransmit); } #else ret = sendQueueTransmit(handle_, seq->sendQueue_, overHead, kSyncTransmit); #endif if (ret >= 0) { long usecs = seq->usecDelay_ + overHead; if (usecs > 0) { (*udelayFn_)(usecs); overHead = 0; } else overHead = usecs; } else { qDebug("error %d in sendQueueTransmit()", ret); qDebug("overHead = %ld", overHead); stop_ = false; goto _exit; } } } // Move to the next Packet Set i += rptSz; } if (returnToQIdx_ >= 0) { long usecs = loopDelay_ + overHead; if (usecs > 0) { (*udelayFn_)(usecs); overHead = 0; } else overHead = usecs; i = returnToQIdx_; goto _restart; } _exit: state_ = kFinished; } void PcapPort::PortTransmitter::start() { // FIXME: return error if (state_ == kRunning) { qWarning("Transmit start requested but is already running!"); return; } state_ = kNotStarted; QThread::start(); while (state_ == kNotStarted) QThread::msleep(10); } void PcapPort::PortTransmitter::stop() { if (state_ == kRunning) { stop_ = true; while (state_ == kRunning) QThread::msleep(10); } else { // FIXME: return error qWarning("Transmit stop requested but is not running!"); return; } } bool PcapPort::PortTransmitter::isRunning() { return (state_ == kRunning); } int PcapPort::PortTransmitter::sendQueueTransmit(pcap_t *p, pcap_send_queue *queue, long &overHead, int sync) { TimeStamp ovrStart, ovrEnd; struct timeval ts; struct pcap_pkthdr *hdr = (struct pcap_pkthdr*) queue->buffer; char *end = queue->buffer + queue->len; ts = hdr->ts; getTimeStamp(&ovrStart); while((char*) hdr < end) { uchar *pkt = (uchar*)hdr + sizeof(*hdr); int pktLen = hdr->caplen; if (sync) { long usec = (hdr->ts.tv_sec - ts.tv_sec) * 1000000 + (hdr->ts.tv_usec - ts.tv_usec); getTimeStamp(&ovrEnd); overHead -= udiffTimeStamp(&ovrStart, &ovrEnd); Q_ASSERT(overHead <= 0); usec += overHead; if (usec > 0) { (*udelayFn_)(usec); overHead = 0; } else overHead = usec; ts = hdr->ts; getTimeStamp(&ovrStart); } Q_ASSERT(pktLen > 0); pcap_sendpacket(p, pkt, pktLen); stats_->txPkts++; stats_->txBytes += pktLen; // Step to the next packet in the buffer hdr = (struct pcap_pkthdr*) (pkt + pktLen); pkt = (uchar*) ((uchar*)hdr + sizeof(*hdr)); if (stop_) { return -2; } } return 0; } void PcapPort::PortTransmitter::udelay(unsigned long usec) { #if defined(Q_OS_WIN32) LARGE_INTEGER tgtTicks; LARGE_INTEGER curTicks; QueryPerformanceCounter(&curTicks); tgtTicks.QuadPart = curTicks.QuadPart + (usec*gTicksFreq)/1000000; while (curTicks.QuadPart < tgtTicks.QuadPart) QueryPerformanceCounter(&curTicks); #elif defined(Q_OS_LINUX) struct timeval delay, target, now; //qDebug("usec delay = %ld", usec); delay.tv_sec = 0; delay.tv_usec = usec; while (delay.tv_usec >= 1000000) { delay.tv_sec++; delay.tv_usec -= 1000000; } gettimeofday(&now, NULL); timeradd(&now, &delay, &target); do { gettimeofday(&now, NULL); } while (timercmp(&now, &target, <)); #else QThread::usleep(usec); #endif } /* * ------------------------------------------------------------------- * * Port Capturer * ------------------------------------------------------------------- * */ PcapPort::PortCapturer::PortCapturer(const char *device) { device_ = QString::fromAscii(device); stop_ = false; state_ = kNotStarted; if (!capFile_.open()) qWarning("Unable to open temp cap file"); qDebug("cap file = %s", capFile_.fileName().toAscii().constData()); dumpHandle_ = NULL; handle_ = NULL; } PcapPort::PortCapturer::~PortCapturer() { capFile_.close(); } void PcapPort::PortCapturer::run() { int flag = PCAP_OPENFLAG_PROMISCUOUS; char errbuf[PCAP_ERRBUF_SIZE] = ""; qDebug("In %s", __PRETTY_FUNCTION__); if (!capFile_.isOpen()) { qWarning("temp cap file is not open"); goto _exit; } _retry: handle_ = pcap_open_live(device_.toAscii().constData(), 65535, flag, 1000 /* ms */, errbuf); if (handle_ == NULL) { if (flag && QString(errbuf).contains("promiscuous")) { qDebug("%s:can't set promiscuous mode, trying non-promisc", device_.toAscii().constData()); flag = 0; goto _retry; } else { qDebug("%s: Error opening port %s: %s\n", __FUNCTION__, device_.toAscii().constData(), errbuf); goto _exit; } } dumpHandle_ = pcap_dump_open(handle_, capFile_.fileName().toAscii().constData()); state_ = kRunning; while (1) { int ret; struct pcap_pkthdr *hdr; const uchar *data; ret = pcap_next_ex(handle_, &hdr, &data); switch (ret) { case 1: pcap_dump((uchar*) dumpHandle_, hdr, data); break; case 0: // timeout: just go back to the loop break; case -1: qWarning("%s: error reading packet (%d): %s", __PRETTY_FUNCTION__, ret, pcap_geterr(handle_)); break; case -2: default: qFatal("%s: Unexpected return value %d", __PRETTY_FUNCTION__, ret); } if (stop_) { qDebug("user requested capture stop\n"); break; } } pcap_dump_close(dumpHandle_); pcap_close(handle_); dumpHandle_ = NULL; handle_ = NULL; stop_ = false; _exit: state_ = kFinished; } void PcapPort::PortCapturer::start() { // FIXME: return error if (state_ == kRunning) { qWarning("Capture start requested but is already running!"); return; } state_ = kNotStarted; QThread::start(); while (state_ == kNotStarted) QThread::msleep(10); } void PcapPort::PortCapturer::stop() { if (state_ == kRunning) { stop_ = true; while (state_ == kRunning) QThread::msleep(10); } else { // FIXME: return error qWarning("Capture stop requested but is not running!"); return; } } bool PcapPort::PortCapturer::isRunning() { return (state_ == kRunning); } QFile* PcapPort::PortCapturer::captureFile() { return &capFile_; } /* * ------------------------------------------------------------------- * * Transmit+Receiver for Device/ProtocolEmulation * ------------------------------------------------------------------- * */ PcapPort::EmulationTransceiver::EmulationTransceiver(const char *device, DeviceManager *deviceManager) { device_ = QString::fromAscii(device); deviceManager_ = deviceManager; stop_ = false; state_ = kNotStarted; handle_ = NULL; } PcapPort::EmulationTransceiver::~EmulationTransceiver() { stop(); } void PcapPort::EmulationTransceiver::run() { int flags = PCAP_OPENFLAG_PROMISCUOUS; char errbuf[PCAP_ERRBUF_SIZE] = ""; struct bpf_program bpf; #if 0 const char *capture_filter = "arp or icmp or icmp6 or " "(vlan and (arp or icmp or icmp6)) or " "(vlan and vlan and (arp or icmp or icmp6)) or " "(vlan and vlan and vlan and (arp or icmp or icmp6)) or " "(vlan and vlan and vlan and vlan and (arp or icmp or icmp6))"; /* Ideally we should use the above filter, but the 'vlan' capture filter in libpcap is implemented as a kludge. From the pcap-filter man page - vlan [vlan_id] Note that the first vlan keyword encountered in expression changes the decoding offsets for the remainder of expression on the assumption that the packet is a VLAN packet. The vlan [vlan_id] expression may be used more than once, to filter on VLAN hierarchies. Each use of that expression increments the filter offsets by 4. See https://ask.wireshark.org/questions/31953/unusual-behavior-with-stacked-vlan-tags-and-capture-filter So we use the modified filter expression that works as we intend. If ever libpcap changes their implementation, this will need to change as well. */ #else const char *capture_filter = "arp or icmp or icmp6 or " "(vlan and (arp or icmp or icmp6)) or " "(vlan and (arp or icmp or icmp6)) or " "(vlan and (arp or icmp or icmp6)) or " "(vlan and (arp or icmp or icmp6))"; #endif const int optimize = 1; qDebug("In %s", __PRETTY_FUNCTION__); #ifdef Q_OS_WIN32 flags |= PCAP_OPENFLAG_NOCAPTURE_LOCAL; #endif _retry: #ifdef Q_OS_WIN32 // NOCAPTURE_LOCAL needs windows only pcap_open() handle_ = pcap_open(qPrintable(device_), 65535, flags, 100 /* ms */, NULL, errbuf); #else handle_ = pcap_open_live(qPrintable(device_), 65535, flags, 100 /* ms */, errbuf); #endif if (handle_ == NULL) { if (flags && QString(errbuf).contains("promiscuous")) { notify("Unable to set promiscuous mode on <%s> - " "device emulation will not work", qPrintable(device_)); goto _exit; } #ifdef Q_OS_WIN32 else if ((flags & PCAP_OPENFLAG_NOCAPTURE_LOCAL) && QString(errbuf).contains("loopback")) { qDebug("Can't set no local capture mode %s", qPrintable(device_)); flags &= ~PCAP_OPENFLAG_NOCAPTURE_LOCAL; goto _retry; } #endif else { notify("Unable to open <%s> [%s] - device emulation will not work", qPrintable(device_), errbuf); goto _exit; } } // TODO: for now the filter is hardcoded to accept tagged/untagged // ARP/NDP or ICMPv4/v6; when more protocols are added, we may need // to derive this filter based on which protocols are configured // on the devices if (pcap_compile(handle_, &bpf, capture_filter, optimize, 0) < 0) { qWarning("%s: error compiling filter: %s", qPrintable(device_), pcap_geterr(handle_)); goto _skip_filter; } if (pcap_setfilter(handle_, &bpf) < 0) { qWarning("%s: error setting filter: %s", qPrintable(device_), pcap_geterr(handle_)); goto _skip_filter; } _skip_filter: state_ = kRunning; while (1) { int ret; struct pcap_pkthdr *hdr; const uchar *data; ret = pcap_next_ex(handle_, &hdr, &data); switch (ret) { case 1: { PacketBuffer *pktBuf = new PacketBuffer(data, hdr->caplen); #if 0 for (int i = 0; i < 64; i++) { printf("%02x ", data[i]); if (i % 16 == 0) printf("\n"); } printf("\n"); #endif // XXX: deviceManager should free pktBuf before returning // from this call; if it needs to process the pkt async // it should make a copy as the pktBuf's data buffer is // owned by libpcap which does not guarantee data will // persist across calls to pcap_next_ex() deviceManager_->receivePacket(pktBuf); break; } case 0: // timeout: just go back to the loop break; case -1: qWarning("%s: error reading packet (%d): %s", __PRETTY_FUNCTION__, ret, pcap_geterr(handle_)); break; case -2: default: qFatal("%s: Unexpected return value %d", __PRETTY_FUNCTION__, ret); } if (stop_) { qDebug("user requested receiver stop\n"); break; } } pcap_close(handle_); handle_ = NULL; stop_ = false; _exit: state_ = kFinished; } void PcapPort::EmulationTransceiver::start() { if (state_ == kRunning) { qWarning("Receive start requested but is already running!"); return; } state_ = kNotStarted; QThread::start(); while (state_ == kNotStarted) QThread::msleep(10); } void PcapPort::EmulationTransceiver::stop() { if (state_ == kRunning) { stop_ = true; while (state_ == kRunning) QThread::msleep(10); } else { qWarning("Receive stop requested but is not running!"); return; } } bool PcapPort::EmulationTransceiver::isRunning() { return (state_ == kRunning); } int PcapPort::EmulationTransceiver::transmitPacket(PacketBuffer *pktBuf) { return pcap_sendpacket(handle_, pktBuf->data(), pktBuf->length()); }