osmocom
/
wireshark
11
0
Fork 1
Code Issues Pull Requests Projects Releases Wiki Activity
wireshark/ui/qt/tcp_stream_dialog.cpp

2219 lines
77 KiB
C++
Raw Blame History

/* tcp_stream_dialog.cpp
*
* Wireshark - Network traffic analyzer
* By Gerald Combs <gerald@wireshark.org>
* Copyright 1998 Gerald Combs
*
* SPDX-License-Identifier: GPL-2.0-or-later
*/
#include "tcp_stream_dialog.h"
#include <ui_tcp_stream_dialog.h>
#include <algorithm> // for std::sort
#include <utility> // for std::pair
#include <vector>
#include "epan/to_str.h"
#include "wsutil/str_util.h"
#include <wsutil/utf8_entities.h>
#include <ui/qt/utils/tango_colors.h>
#include <ui/qt/utils/qt_ui_utils.h>
#include "progress_frame.h"
#include "main_application.h"
#include "ui/qt/widgets/wireshark_file_dialog.h"
#include <QCursor>
#include <QDir>
#include <QIcon>
#include <QPushButton>
#include <QDebug>
// To do:
// - Make the Help button work.
// - Show a message or disable the graph if we don't have any data.
// - Add a bytes in flight graph
// - Make the crosshairs tracer a vertical band?
// - Implement File->Copy
// - Add UDP graphs
// - Make the first throughput MA period a dotted/dashed line?
// - Add range scroll bars?
// - ACK & RWIN segment ticks in tcptrace graph
// - Add missing elements (retrans, URG, SACK, etc) to tcptrace. It probably makes
// sense to subclass QCPGraph for this.
// The GTK+ version computes a 20 (or 21!) segment moving average. Comment
// out the line below to use that. By default we use a 1 second MA.
#define MA_1_SECOND
#ifndef MA_1_SECOND
const int moving_avg_period_ = 20;
#endif
const QRgb graph_color_1 = tango_sky_blue_5;
const QRgb graph_color_2 = tango_butter_6;
const QRgb graph_color_3 = tango_chameleon_5;
const QRgb graph_color_4 = tango_scarlet_red_4;
const QRgb graph_color_5 = tango_scarlet_red_6;
// Size of selectable packet points in the base graph
const double pkt_point_size_ = 3.0;
// Don't accidentally zoom into a 1x1 rect if you happen to click on the graph
// in zoom mode.
const int min_zoom_pixels_ = 20;
const QString average_throughput_label_ = QObject::tr("Average Throughput (bits/s)");
const QString round_trip_time_ms_label_ = QObject::tr("Round Trip Time (ms)");
const QString segment_length_label_ = QObject::tr("Segment Length (B)");
const QString sequence_number_label_ = QObject::tr("Sequence Number (B)");
const QString time_s_label_ = QObject::tr("Time (s)");
const QString window_size_label_ = QObject::tr("Window Size (B)");
QCPErrorBarsNotSelectable::QCPErrorBarsNotSelectable(QCPAxis *keyAxis, QCPAxis *valueAxis) :
QCPErrorBars(keyAxis, valueAxis)
{
}
QCPErrorBarsNotSelectable::~QCPErrorBarsNotSelectable()
{
}
double QCPErrorBarsNotSelectable::selectTest(const QPointF &pos, bool onlySelectable, QVariant *details) const
{
Q_UNUSED(pos);
Q_UNUSED(onlySelectable);
Q_UNUSED(details);
return -1.0;
}
TCPStreamDialog::TCPStreamDialog(QWidget *parent, capture_file *cf, tcp_graph_type graph_type) :
GeometryStateDialog(parent),
ui(new Ui::TCPStreamDialog),
cap_file_(cf),
ts_offset_(0),
ts_origin_conn_(true),
seq_offset_(0),
seq_origin_zero_(true),
title_(nullptr),
base_graph_(nullptr),
tput_graph_(nullptr),
goodput_graph_(nullptr),
seg_graph_(nullptr),
seg_eb_(nullptr),
ack_graph_(nullptr),
sack_graph_(nullptr),
sack_eb_(nullptr),
sack2_graph_(nullptr),
sack2_eb_(nullptr),
rwin_graph_(nullptr),
dup_ack_graph_(nullptr),
zero_win_graph_(nullptr),
tracer_(nullptr),
packet_num_(0),
mouse_drags_(true),
rubber_band_(nullptr),
graph_updater_(this),
num_dsegs_(-1),
num_acks_(-1),
num_sack_ranges_(-1),
ma_window_size_(1.0)
{
int graph_idx = -1;
memset(&graph_, 0, sizeof(graph_));
ui->setupUi(this);
if (parent) loadGeometry(parent->width() * 2 / 3, parent->height() * 4 / 5);
setAttribute(Qt::WA_DeleteOnClose, true);
ui->streamNumberSpinBox->setStyleSheet("QSpinBox { min-width: 2em; }");
guint32 th_stream = select_tcpip_session(cap_file_);
if (th_stream == G_MAXUINT32) {
done(QDialog::Rejected);
return;
}
QComboBox *gtcb = ui->graphTypeComboBox;
gtcb->setUpdatesEnabled(false);
gtcb->addItem(ui->actionRoundTripTime->text(), GRAPH_RTT);
if (graph_type == GRAPH_RTT) graph_idx = gtcb->count() - 1;
gtcb->addItem(ui->actionThroughput->text(), GRAPH_THROUGHPUT);
if (graph_type == GRAPH_THROUGHPUT) graph_idx = gtcb->count() - 1;
gtcb->addItem(ui->actionStevens->text(), GRAPH_TSEQ_STEVENS);
if (graph_type == GRAPH_TSEQ_STEVENS) graph_idx = gtcb->count() - 1;
gtcb->addItem(ui->actionTcptrace->text(), GRAPH_TSEQ_TCPTRACE);
if (graph_type == GRAPH_TSEQ_TCPTRACE) graph_idx = gtcb->count() - 1;
gtcb->addItem(ui->actionWindowScaling->text(), GRAPH_WSCALE);
if (graph_type == GRAPH_WSCALE) graph_idx = gtcb->count() - 1;
gtcb->setUpdatesEnabled(true);
ui->dragRadioButton->setChecked(mouse_drags_);
ctx_menu_.addAction(ui->actionZoomIn);
ctx_menu_.addAction(ui->actionZoomInX);
ctx_menu_.addAction(ui->actionZoomInY);
ctx_menu_.addAction(ui->actionZoomOut);
ctx_menu_.addAction(ui->actionZoomOutX);
ctx_menu_.addAction(ui->actionZoomOutY);
ctx_menu_.addAction(ui->actionReset);
ctx_menu_.addSeparator();
ctx_menu_.addAction(ui->actionMoveRight10);
ctx_menu_.addAction(ui->actionMoveLeft10);
ctx_menu_.addAction(ui->actionMoveUp10);
ctx_menu_.addAction(ui->actionMoveDown10);
ctx_menu_.addAction(ui->actionMoveRight1);
ctx_menu_.addAction(ui->actionMoveLeft1);
ctx_menu_.addAction(ui->actionMoveUp1);
ctx_menu_.addAction(ui->actionMoveDown1);
ctx_menu_.addSeparator();
ctx_menu_.addAction(ui->actionNextStream);
ctx_menu_.addAction(ui->actionPreviousStream);
ctx_menu_.addAction(ui->actionSwitchDirection);
ctx_menu_.addAction(ui->actionGoToPacket);
ctx_menu_.addSeparator();
ctx_menu_.addAction(ui->actionDragZoom);
ctx_menu_.addAction(ui->actionToggleSequenceNumbers);
ctx_menu_.addAction(ui->actionToggleTimeOrigin);
ctx_menu_.addAction(ui->actionCrosshairs);
ctx_menu_.addSeparator();
ctx_menu_.addAction(ui->actionRoundTripTime);
ctx_menu_.addAction(ui->actionThroughput);
ctx_menu_.addAction(ui->actionStevens);
ctx_menu_.addAction(ui->actionTcptrace);
ctx_menu_.addAction(ui->actionWindowScaling);
set_action_shortcuts_visible_in_context_menu(ctx_menu_.actions());
graph_.type = graph_type;
graph_.stream = th_stream;
findStream();
showWidgetsForGraphType();
ui->streamNumberSpinBox->blockSignals(true);
ui->streamNumberSpinBox->setMaximum(get_tcp_stream_count() - 1);
ui->streamNumberSpinBox->setValue(graph_.stream);
ui->streamNumberSpinBox->blockSignals(false);
#ifdef MA_1_SECOND
ui->maWindowSizeSpinBox->blockSignals(true);
ui->maWindowSizeSpinBox->setDecimals(6);
ui->maWindowSizeSpinBox->setMinimum(0.000001);
ui->maWindowSizeSpinBox->setValue(ma_window_size_);
ui->maWindowSizeSpinBox->blockSignals(false);
#endif
// set which Throughput graphs are displayed by default
ui->showSegLengthCheckBox->blockSignals(true);
ui->showSegLengthCheckBox->setChecked(true);
ui->showSegLengthCheckBox->blockSignals(false);
ui->showThroughputCheckBox->blockSignals(true);
ui->showThroughputCheckBox->setChecked(true);
ui->showThroughputCheckBox->blockSignals(false);
// set which WScale graphs are displayed by default
ui->showRcvWinCheckBox->blockSignals(true);
ui->showRcvWinCheckBox->setChecked(true);
ui->showRcvWinCheckBox->blockSignals(false);
ui->showBytesOutCheckBox->blockSignals(true);
ui->showBytesOutCheckBox->setChecked(true);
ui->showBytesOutCheckBox->blockSignals(false);
QCustomPlot *sp = ui->streamPlot;
QCPTextElement *file_title = new QCPTextElement(sp, gchar_free_to_qstring(cf_get_display_name(cap_file_)));
file_title->setFont(sp->xAxis->labelFont());
title_ = new QCPTextElement(sp);
sp->plotLayout()->insertRow(0);
sp->plotLayout()->addElement(0, 0, file_title);
sp->plotLayout()->insertRow(0);
sp->plotLayout()->addElement(0, 0, title_);
qreal pen_width = 0.5;
// Base Graph - enables selecting segments (both data and SACKs)
base_graph_ = sp->addGraph();
base_graph_->setPen(QPen(QBrush(graph_color_1), pen_width));
// Throughput Graph - rate of sent bytes
tput_graph_ = sp->addGraph(sp->xAxis, sp->yAxis2);
tput_graph_->setPen(QPen(QBrush(graph_color_2), pen_width));
tput_graph_->setLineStyle(QCPGraph::lsStepLeft);
// Goodput Graph - rate of ACKed bytes
goodput_graph_ = sp->addGraph(sp->xAxis, sp->yAxis2);
goodput_graph_->setPen(QPen(QBrush(graph_color_3), pen_width));
goodput_graph_->setLineStyle(QCPGraph::lsStepLeft);
// Seg Graph - displays forward data segments on tcptrace graph
seg_graph_ = sp->addGraph();
seg_graph_->setLineStyle(QCPGraph::lsNone);
seg_graph_->setScatterStyle(QCPScatterStyle(QCPScatterStyle::ssDot, Qt::transparent, 0));
seg_eb_ = new QCPErrorBarsNotSelectable(sp->xAxis, sp->yAxis);
seg_eb_->setErrorType(QCPErrorBars::etValueError);
seg_eb_->setPen(QPen(QBrush(graph_color_1), pen_width));
seg_eb_->setSymbolGap(0.0); // draw error spine as single line
seg_eb_->setWhiskerWidth(pkt_point_size_);
seg_eb_->removeFromLegend();
seg_eb_->setDataPlottable(seg_graph_);
// Ack Graph - displays ack numbers from reverse packets
ack_graph_ = sp->addGraph();
ack_graph_->setPen(QPen(QBrush(graph_color_2), pen_width));
ack_graph_->setLineStyle(QCPGraph::lsStepLeft);
// Sack Graph - displays highest number (most recent) SACK block
sack_graph_ = sp->addGraph();
sack_graph_->setLineStyle(QCPGraph::lsNone);
sack_graph_->setScatterStyle(QCPScatterStyle(QCPScatterStyle::ssDot, Qt::transparent, 0));
sack_eb_ = new QCPErrorBarsNotSelectable(sp->xAxis, sp->yAxis);
sack_eb_->setErrorType(QCPErrorBars::etValueError);
sack_eb_->setPen(QPen(QBrush(graph_color_4), pen_width));
sack_eb_->setSymbolGap(0.0); // draw error spine as single line
sack_eb_->setWhiskerWidth(0.0);
sack_eb_->removeFromLegend();
sack_eb_->setDataPlottable(sack_graph_);
// Sack Graph 2 - displays subsequent SACK blocks
sack2_graph_ = sp->addGraph();
sack2_graph_->setLineStyle(QCPGraph::lsNone);
sack2_graph_->setScatterStyle(QCPScatterStyle(QCPScatterStyle::ssDot, Qt::transparent, 0));
sack2_eb_ = new QCPErrorBarsNotSelectable(sp->xAxis, sp->yAxis);
sack2_eb_->setErrorType(QCPErrorBars::etValueError);
sack2_eb_->setPen(QPen(QBrush(graph_color_5), pen_width));
sack2_eb_->setSymbolGap(0.0); // draw error spine as single line
sack2_eb_->setWhiskerWidth(0.0);
sack2_eb_->removeFromLegend();
sack2_eb_->setDataPlottable(sack2_graph_);
// RWin graph - displays upper extent of RWIN advertised on reverse packets
rwin_graph_ = sp->addGraph();
rwin_graph_->setPen(QPen(QBrush(graph_color_3), pen_width));
rwin_graph_->setLineStyle(QCPGraph::lsStepLeft);
// Duplicate ACK Graph - displays duplicate ack ticks
// QCustomPlot doesn't have QCPScatterStyle::ssTick so we have to make our own.
int tick_len = 3;
tick_len *= devicePixelRatio();
QPixmap da_tick_pm = QPixmap(1, tick_len * 2);
da_tick_pm.fill(Qt::transparent);
QPainter painter(&da_tick_pm);
QPen da_tick_pen;
da_tick_pen.setColor(graph_color_2);
da_tick_pen.setWidthF(pen_width);
painter.setPen(da_tick_pen);
painter.drawLine(0, tick_len, 0, tick_len * 2);
dup_ack_graph_ = sp->addGraph();
dup_ack_graph_->setLineStyle(QCPGraph::lsNone);
QCPScatterStyle da_ss = QCPScatterStyle(QCPScatterStyle::ssPixmap, graph_color_2, 0);
da_ss.setPixmap(da_tick_pm);
dup_ack_graph_->setScatterStyle(da_ss);
// Zero Window Graph - displays zero window crosses (x)
zero_win_graph_ = sp->addGraph();
zero_win_graph_->setLineStyle(QCPGraph::lsNone);
zero_win_graph_->setScatterStyle(QCPScatterStyle(QCPScatterStyle::ssCross, graph_color_1, 5));
tracer_ = new QCPItemTracer(sp);
// Triggers fillGraph() [ UNLESS the index is already graph_idx!! ]
if (graph_idx != ui->graphTypeComboBox->currentIndex())
// changing the current index will call fillGraph
ui->graphTypeComboBox->setCurrentIndex(graph_idx);
else
// the current index is what we want - so fillGraph() manually
fillGraph();
sp->setMouseTracking(true);
sp->yAxis->setLabelColor(QColor(graph_color_1));
sp->yAxis->setTickLabelColor(QColor(graph_color_1));
tracer_->setVisible(false);
toggleTracerStyle(true);
QPushButton *save_bt = ui->buttonBox->button(QDialogButtonBox::Save);
save_bt->setText(tr("Save As…"));
QPushButton *close_bt = ui->buttonBox->button(QDialogButtonBox::Close);
if (close_bt) {
close_bt->setDefault(true);
}
ProgressFrame::addToButtonBox(ui->buttonBox, parent);
connect(sp, SIGNAL(mousePress(QMouseEvent*)), this, SLOT(graphClicked(QMouseEvent*)));
connect(sp, SIGNAL(mouseMove(QMouseEvent*)), this, SLOT(mouseMoved(QMouseEvent*)));
connect(sp, SIGNAL(mouseRelease(QMouseEvent*)), this, SLOT(mouseReleased(QMouseEvent*)));
connect(sp, SIGNAL(axisClick(QCPAxis*,QCPAxis::SelectablePart,QMouseEvent*)),
this, SLOT(axisClicked(QCPAxis*,QCPAxis::SelectablePart,QMouseEvent*)));
connect(sp->yAxis, SIGNAL(rangeChanged(QCPRange)), this, SLOT(transformYRange(QCPRange)));
disconnect(ui->buttonBox, SIGNAL(accepted()), this, SLOT(accept()));
this->setResult(QDialog::Accepted);
}
TCPStreamDialog::~TCPStreamDialog()
{
graph_segment_list_free(&graph_);
delete ui;
}
void TCPStreamDialog::showEvent(QShowEvent *)
{
resetAxes();
}
void TCPStreamDialog::keyPressEvent(QKeyEvent *event)
{
int pan_pixels = event->modifiers() & Qt::ShiftModifier ? 1 : 10;
QWidget* focusWidget = QApplication::focusWidget();
// Block propagation of "Enter" key when focus is not default (e.g. SpinBox)
// [ Note that if focus was on, e.g. Close button, event would never reach
// here ]
if ((event->key() == Qt::Key_Enter || event->key() == Qt::Key_Return) &&
focusWidget !=NULL && focusWidget != ui->streamPlot) {
// reset focus to default, and accept event
ui->streamPlot->setFocus();
event->accept();
return;
}
// XXX - This differs from the main window but matches other applications (e.g. Mozilla and Safari)
switch(event->key()) {
case Qt::Key_Minus:
case Qt::Key_Underscore: // Shifted minus on U.S. keyboards
case Qt::Key_O: // GTK+
zoomAxes(false);
break;
case Qt::Key_Plus:
case Qt::Key_Equal: // Unshifted plus on U.S. keyboards
case Qt::Key_I: // GTK+
zoomAxes(true);
break;
case Qt::Key_X: // Zoom X axis only
if (event->modifiers() & Qt::ShiftModifier) {
zoomXAxis(false); // upper case X -> Zoom out
} else {
zoomXAxis(true); // lower case x -> Zoom in
}
break;
case Qt::Key_Y: // Zoom Y axis only
if (event->modifiers() & Qt::ShiftModifier) {
zoomYAxis(false); // upper case Y -> Zoom out
} else {
zoomYAxis(true); // lower case y -> Zoom in
}
break;
case Qt::Key_Right:
case Qt::Key_L:
panAxes(pan_pixels, 0);
break;
case Qt::Key_Left:
case Qt::Key_H:
panAxes(-1 * pan_pixels, 0);
break;
case Qt::Key_Up:
case Qt::Key_K:
panAxes(0, pan_pixels);
break;
case Qt::Key_Down:
case Qt::Key_J:
panAxes(0, -1 * pan_pixels);
break;
case Qt::Key_Space:
toggleTracerStyle();
break;
case Qt::Key_0:
case Qt::Key_ParenRight: // Shifted 0 on U.S. keyboards
case Qt::Key_R:
case Qt::Key_Home:
resetAxes();
break;
case Qt::Key_PageUp:
on_actionNextStream_triggered();
break;
case Qt::Key_PageDown:
on_actionPreviousStream_triggered();
break;
case Qt::Key_D:
on_actionSwitchDirection_triggered();
break;
case Qt::Key_G:
on_actionGoToPacket_triggered();
break;
case Qt::Key_S:
on_actionToggleSequenceNumbers_triggered();
break;
case Qt::Key_T:
on_actionToggleTimeOrigin_triggered();
break;
case Qt::Key_Z:
on_actionDragZoom_triggered();
break;
case Qt::Key_1:
on_actionRoundTripTime_triggered();
break;
case Qt::Key_2:
on_actionThroughput_triggered();
break;
case Qt::Key_3:
on_actionStevens_triggered();
break;
case Qt::Key_4:
on_actionTcptrace_triggered();
break;
case Qt::Key_5:
on_actionWindowScaling_triggered();
break;
// Alas, there is no Blade Runner-style Qt::Key_Enhance
}
QDialog::keyPressEvent(event);
}
void TCPStreamDialog::mousePressEvent(QMouseEvent *event)
{
// if no-one else wants the event, then this is a click on blank space.
// Use this opportunity to set focus back to default, and accept event.
ui->streamPlot->setFocus();
event->accept();
}
void TCPStreamDialog::mouseReleaseEvent(QMouseEvent *event)
{
mouseReleased(event);
}
void TCPStreamDialog::findStream()
{
QCustomPlot *sp = ui->streamPlot;
disconnect(sp, SIGNAL(mouseMove(QMouseEvent*)), this, SLOT(mouseMoved(QMouseEvent*)));
// if streamNumberSpinBox has focus -
// first clear focus, then disable/enable, then restore focus
bool spin_box_focused = ui->streamNumberSpinBox->hasFocus();
if (spin_box_focused)
ui->streamNumberSpinBox->clearFocus();
ui->streamNumberSpinBox->setEnabled(false);
graph_segment_list_free(&graph_);
graph_segment_list_get(cap_file_, &graph_);
ui->streamNumberSpinBox->setEnabled(true);
if (spin_box_focused)
ui->streamNumberSpinBox->setFocus();
connect(sp, SIGNAL(mouseMove(QMouseEvent*)), this, SLOT(mouseMoved(QMouseEvent*)));
}
void TCPStreamDialog::fillGraph(bool reset_axes, bool set_focus)
{
QCustomPlot *sp = ui->streamPlot;
if (sp->graphCount() < 1) return;
base_graph_->setLineStyle(QCPGraph::lsNone);
tracer_->setGraph(NULL);
// base_graph_ is always visible.
for (int i = 0; i < sp->graphCount(); i++) {
sp->graph(i)->data()->clear();
sp->graph(i)->setVisible(i == 0 ? true : false);
}
// also clear and hide ErrorBars plottables
seg_eb_->setVisible(false);
seg_eb_->data()->clear();
sack_eb_->setVisible(false);
sack_eb_->data()->clear();
sack2_eb_->setVisible(false);
sack2_eb_->data()->clear();
base_graph_->setScatterStyle(QCPScatterStyle(QCPScatterStyle::ssDisc, pkt_point_size_));
sp->xAxis->setLabel(time_s_label_);
sp->xAxis->setNumberFormat("gb");
// Use enough precision to mark microseconds
// when zooming in on a <100s capture
sp->xAxis->setNumberPrecision(8);
sp->yAxis->setNumberFormat("f");
sp->yAxis->setNumberPrecision(0);
sp->yAxis2->setVisible(false);
sp->yAxis2->setLabel(QString());
if (!cap_file_) {
QString dlg_title = QString(tr("No Capture Data"));
setWindowTitle(dlg_title);
title_->setText(dlg_title);
sp->setEnabled(false);
sp->yAxis->setLabel(QString());
sp->replot();
return;
}
ts_offset_ = 0;
seq_offset_ = 0;
bool first = true;
guint64 bytes_fwd = 0;
guint64 bytes_rev = 0;
int pkts_fwd = 0;
int pkts_rev = 0;
time_stamp_map_.clear();
for (struct segment *seg = graph_.segments; seg != NULL; seg = seg->next) {
// NOTE - adding both forward and reverse packets to time_stamp_map_
// so that both data and acks are selectable
// (this is important especially in selecting particular SACK pkts)
bool insert = true;
if (!compareHeaders(seg)) {
bytes_rev += seg->th_seglen;
pkts_rev++;
// only insert reverse packets if SACK present
insert = (seg->num_sack_ranges != 0);
} else {
bytes_fwd += seg->th_seglen;
pkts_fwd++;
}
double ts = seg->rel_secs + seg->rel_usecs / 1000000.0;
if (first) {
if (ts_origin_conn_) ts_offset_ = ts;
if (seq_origin_zero_) {
if (compareHeaders(seg))
seq_offset_ = seg->th_seq;
else
seq_offset_ = seg->th_ack;
}
first = false;
}
if (insert) {
time_stamp_map_.insert(ts - ts_offset_, seg);
}
}
switch (graph_.type) {
case GRAPH_TSEQ_STEVENS:
fillStevens();
break;
case GRAPH_TSEQ_TCPTRACE:
fillTcptrace();
break;
case GRAPH_THROUGHPUT:
fillThroughput();
break;
case GRAPH_RTT:
fillRoundTripTime();
break;
case GRAPH_WSCALE:
fillWindowScale();
break;
default:
break;
}
sp->setEnabled(true);
stream_desc_ = tr("%1 %2 pkts, %3 %4 %5 pkts, %6 ")
.arg(UTF8_RIGHTWARDS_ARROW)
.arg(gchar_free_to_qstring(format_size(pkts_fwd, FORMAT_SIZE_UNIT_NONE, FORMAT_SIZE_PREFIX_SI)))
.arg(gchar_free_to_qstring(format_size(bytes_fwd, FORMAT_SIZE_UNIT_BYTES, FORMAT_SIZE_PREFIX_SI)))
.arg(UTF8_LEFTWARDS_ARROW)
.arg(gchar_free_to_qstring(format_size(pkts_rev, FORMAT_SIZE_UNIT_NONE, FORMAT_SIZE_PREFIX_SI)))
.arg(gchar_free_to_qstring(format_size(bytes_rev, FORMAT_SIZE_UNIT_BYTES, FORMAT_SIZE_PREFIX_SI)));
mouseMoved(NULL);
if (reset_axes)
resetAxes();
else
sp->replot();
// Throughput and Window Scale graphs can hide base_graph_
if (base_graph_->visible())
tracer_->setGraph(base_graph_);
// XXX QCustomPlot doesn't seem to draw any sort of focus indicator.
if (set_focus)
sp->setFocus();
}
void TCPStreamDialog::showWidgetsForGraphType()
{
if (graph_.type == GRAPH_RTT) {
ui->bySeqNumberCheckBox->setVisible(true);
} else {
ui->bySeqNumberCheckBox->setVisible(false);
}
if (graph_.type == GRAPH_THROUGHPUT) {
#ifdef MA_1_SECOND
ui->maWindowSizeLabel->setVisible(true);
ui->maWindowSizeSpinBox->setVisible(true);
#else
ui->maWindowSizeLabel->setVisible(false);
ui->maWindowSizeSpinBox->setVisible(false);
#endif
ui->showSegLengthCheckBox->setVisible(true);
ui->showThroughputCheckBox->setVisible(true);
ui->showGoodputCheckBox->setVisible(true);
} else {
ui->maWindowSizeLabel->setVisible(false);
ui->maWindowSizeSpinBox->setVisible(false);
ui->showSegLengthCheckBox->setVisible(false);
ui->showThroughputCheckBox->setVisible(false);
ui->showGoodputCheckBox->setVisible(false);
}
if (graph_.type == GRAPH_TSEQ_TCPTRACE) {
ui->selectSACKsCheckBox->setVisible(true);
} else {
ui->selectSACKsCheckBox->setVisible(false);
}
if (graph_.type == GRAPH_WSCALE) {
ui->showRcvWinCheckBox->setVisible(true);
ui->showBytesOutCheckBox->setVisible(true);
} else {
ui->showRcvWinCheckBox->setVisible(false);
ui->showBytesOutCheckBox->setVisible(false);
}
}
void TCPStreamDialog::zoomAxes(bool in)
{
QCustomPlot *sp = ui->streamPlot;
double h_factor = sp->axisRect()->rangeZoomFactor(Qt::Horizontal);
double v_factor = sp->axisRect()->rangeZoomFactor(Qt::Vertical);
if (!in) {
h_factor = pow(h_factor, -1);
v_factor = pow(v_factor, -1);
}
sp->xAxis->scaleRange(h_factor, sp->xAxis->range().center());
sp->yAxis->scaleRange(v_factor, sp->yAxis->range().center());
sp->replot();
}
void TCPStreamDialog::zoomXAxis(bool in)
{
QCustomPlot *sp = ui->streamPlot;
double h_factor = sp->axisRect()->rangeZoomFactor(Qt::Horizontal);
if (!in) {
h_factor = pow(h_factor, -1);
}
sp->xAxis->scaleRange(h_factor, sp->xAxis->range().center());
sp->replot();
}
void TCPStreamDialog::zoomYAxis(bool in)
{
QCustomPlot *sp = ui->streamPlot;
double v_factor = sp->axisRect()->rangeZoomFactor(Qt::Vertical);
if (!in) {
v_factor = pow(v_factor, -1);
}
sp->yAxis->scaleRange(v_factor, sp->yAxis->range().center());
sp->replot();
}
void TCPStreamDialog::panAxes(int x_pixels, int y_pixels)
{
QCustomPlot *sp = ui->streamPlot;
double h_pan = 0.0;
double v_pan = 0.0;
h_pan = sp->xAxis->range().size() * x_pixels / sp->xAxis->axisRect()->width();
v_pan = sp->yAxis->range().size() * y_pixels / sp->yAxis->axisRect()->height();
// The GTK+ version won't pan unless we're zoomed. Should we do the same here?
if (h_pan) {
sp->xAxis->moveRange(h_pan);
sp->replot();
}
if (v_pan) {
sp->yAxis->moveRange(v_pan);
sp->replot();
}
}
void TCPStreamDialog::resetAxes()
{
QCustomPlot *sp = ui->streamPlot;
y_axis_xfrm_.reset();
double pixel_pad = 10.0; // per side
sp->rescaleAxes(true);
// tput_graph_->rescaleValueAxis(false, true);
// base_graph_->rescaleAxes(false, true);
// for (int i = 0; i < sp->graphCount(); i++) {
// sp->graph(i)->rescaleValueAxis(false, true);
// }
double axis_pixels = sp->xAxis->axisRect()->width();
sp->xAxis->scaleRange((axis_pixels + (pixel_pad * 2)) / axis_pixels, sp->xAxis->range().center());
if (sp->yAxis2->visible()) {
double ratio = sp->yAxis2->range().size() / sp->yAxis->range().size();
y_axis_xfrm_.translate(0.0, sp->yAxis2->range().lower - (sp->yAxis->range().lower * ratio));
y_axis_xfrm_.scale(1.0, ratio);
}
axis_pixels = sp->yAxis->axisRect()->height();
sp->yAxis->scaleRange((axis_pixels + (pixel_pad * 2)) / axis_pixels, sp->yAxis->range().center());
sp->replot();
}
void TCPStreamDialog::fillStevens()
{
QString dlg_title = QString(tr("Sequence Numbers (Stevens)")) + streamDescription();
setWindowTitle(dlg_title);
title_->setText(dlg_title);
QCustomPlot *sp = ui->streamPlot;
sp->yAxis->setLabel(sequence_number_label_);
// True Stevens-style graphs don't have lines but I like them - gcc
base_graph_->setLineStyle(QCPGraph::lsStepLeft);
QVector<double> rel_time, seq;
for (struct segment *seg = graph_.segments; seg != NULL; seg = seg->next) {
if (!compareHeaders(seg)) {
continue;
}
double ts = seg->rel_secs + seg->rel_usecs / 1000000.0;
rel_time.append(ts - ts_offset_);
seq.append(seg->th_seq - seq_offset_);
}
base_graph_->setData(rel_time, seq);
}
void TCPStreamDialog::fillTcptrace()
{
QString dlg_title = QString(tr("Sequence Numbers (tcptrace)")) + streamDescription();
setWindowTitle(dlg_title);
title_->setText(dlg_title);
bool allow_sack_select = ui->selectSACKsCheckBox->isChecked();
QCustomPlot *sp = ui->streamPlot;
sp->yAxis->setLabel(sequence_number_label_);
base_graph_->setScatterStyle(QCPScatterStyle(QCPScatterStyle::ssDot));
seg_graph_->setVisible(true);
seg_eb_->setVisible(true);
ack_graph_->setVisible(true);
sack_graph_->setVisible(true);
sack_eb_->setVisible(true);
sack2_graph_->setVisible(true);
sack2_eb_->setVisible(true);
rwin_graph_->setVisible(true);
dup_ack_graph_->setVisible(true);
zero_win_graph_->setVisible(true);
QVector<double> pkt_time, pkt_seqnums;
QVector<double> sb_time, sb_center, sb_span;
QVector<double> ackrwin_time, ack, rwin;
QVector<double> sack_time, sack_center, sack_span;
QVector<double> sack2_time, sack2_center, sack2_span;
QVector<double> dup_ack_time, dup_ack;
QVector<double> zero_win_time, zero_win;
for (struct segment *seg = graph_.segments; seg != NULL; seg = seg->next) {
double ts = (seg->rel_secs + seg->rel_usecs / 1000000.0) - ts_offset_;
if (compareHeaders(seg)) {
double half = seg->th_seglen / 2.0;
double center = seg->th_seq - seq_offset_ + half;
// Add forward direction to base_graph_ (to select data packets)
// Forward direction: seq + data
pkt_time.append(ts);
pkt_seqnums.append(center);
// QCP doesn't have a segment graph type. For now, fake
// it with error bars.
if (seg->th_seglen > 0) {
sb_time.append(ts);
sb_center.append(center);
sb_span.append(half);
}
// Look for zero window sizes.
// Should match the TCP_A_ZERO_WINDOW test in packet-tcp.c.
if (seg->th_win == 0 && (seg->th_flags & (TH_RST|TH_FIN|TH_SYN)) == 0) {
zero_win_time.append(ts);
zero_win.append(center);
}
} else {
// Reverse direction: ACK + RWIN
if (! (seg->th_flags & TH_ACK)) {
// SYNs and RSTs do not necessarily have ACKs
continue;
}
double ackno = seg->th_ack - seq_offset_;
// add SACK segments to sack, sack2, and selectable packet graph
for (int i = 0; i < seg->num_sack_ranges; ++i) {
double half = seg->sack_right_edge[i] - seg->sack_left_edge[i];
half = half/2.0;
double center = seg->sack_left_edge[i] - seq_offset_ + half;
if (i == 0) {
sack_time.append(ts);
sack_center.append(center);
sack_span.append(half);
if (allow_sack_select) {
pkt_time.append(ts);
pkt_seqnums.append(center);
}
} else {
sack2_time.append(ts);
sack2_center.append(center);
sack2_span.append(half);
}
}
// If ackno is the same as our last one mark it as a duplicate.
// (but don't mark window updates as duplicate acks)
if (ack.size() > 0 && ack.last() == ackno
&& rwin.last() == ackno + seg->th_win) {
dup_ack_time.append(ts);
dup_ack.append(ackno);
}
// Also add reverse packets to the ack_graph_
ackrwin_time.append(ts);
ack.append(ackno);
rwin.append(ackno + seg->th_win);
}
}
base_graph_->setData(pkt_time, pkt_seqnums, true);
ack_graph_->setData(ackrwin_time, ack, true);
seg_graph_->setData(sb_time, sb_center, true);
seg_eb_->setData(sb_span);
sack_graph_->setData(sack_time, sack_center, true);
sack_eb_->setData(sack_span);
sack2_graph_->setData(sack2_time, sack2_center, true);
sack2_eb_->setData(sack2_span);
rwin_graph_->setData(ackrwin_time, rwin, true);
dup_ack_graph_->setData(dup_ack_time, dup_ack, true);
zero_win_graph_->setData(zero_win_time, zero_win, true);
}
// If the current implementation of incorporating SACKs in goodput calc
// is slow, comment out the following line to ignore SACKs in goodput calc.
#define USE_SACKS_IN_GOODPUT_CALC
#ifdef USE_SACKS_IN_GOODPUT_CALC
// to incorporate SACKED segments into goodput calculation,
// need to keep track of all the SACK blocks we haven't yet
// fully ACKed.
// I expect this to be _relatively_ small, so using vector to store
// them. If this performs badly, it can be refactored with std::list
// or std::map.
typedef std::pair<guint32, guint32> sack_t;
typedef std::vector<sack_t> sack_list_t;
static inline bool compare_sack(const sack_t& s1, const sack_t& s2) {
return tcp_seq_before(s1.first, s2.first);
}
// Helper function to adjust an acked seglen for goodput:
// - removes previously sacked ranges from seglen (and from old_sacks),
// - adds newly sacked ranges to seglen (and to old_sacks)
static void
goodput_adjust_for_sacks(guint32 *seglen, guint32 last_ack,
sack_list_t& new_sacks, guint8 num_sack_ranges,
sack_list_t& old_sacks) {
// Step 1 - For any old_sacks acked by last_ack,
// delete their acked length from seglen,
// and remove the sack block (or portion)
// from (sorted) old_sacks.
sack_list_t::iterator unacked = old_sacks.begin();
while (unacked != old_sacks.end()) {
// break on first sack not fully acked
if (tcp_seq_before(last_ack, unacked->second)) {
if (tcp_seq_after(last_ack, unacked->first)) {
// partially acked - modify to remove acked part
*seglen -= (last_ack - unacked->first);
unacked->first = last_ack;
}
break;
}
// remove fully acked sacks from seglen and move on
// (we'll actually remove from the list when loop is done)
*seglen -= (unacked->second - unacked->first);
++unacked;
}
// actually remove all fully acked sacks from old_sacks list
if (unacked != old_sacks.begin())
old_sacks.erase(old_sacks.begin(), unacked);
// Step 2 - for any new_sacks that precede last_ack,
// ignore them. (These would generally be SACKed dup-acks of
// a retransmitted seg).
// [ in the unlikely case that any new SACK straddles last_ack,
// the sack block will be modified to remove the acked portion ]
int next_new_idx = 0;
while (next_new_idx < num_sack_ranges) {
if (tcp_seq_before(last_ack, new_sacks[next_new_idx].second)) {
// if a new SACK block is unacked by its own packet, then it's
// likely fully unacked, but let's check for partial ack anyway,
// and truncate the SACK so that it's fully unacked:
if (tcp_seq_before(new_sacks[next_new_idx].first, last_ack))
new_sacks[next_new_idx].first = last_ack;
break;
}
++next_new_idx;
}
// Step 3 - for any byte ranges in remaining new_sacks
// that don't already exist in old_sacks, add
// their length to seglen
// and add that range (by extension, if possible) to
// the list of old_sacks.
sack_list_t::iterator next_old = old_sacks.begin();
while (next_new_idx < num_sack_ranges &&
next_old != old_sacks.end()) {
sack_t* next_new = &new_sacks[next_new_idx];
// Assumptions / Invariants:
// - new and old lists are sorted
// - span of leftmost to rightmost endpt. is less than half uint32 range
// [ensures transitivity - e.g. before(a,b) and before(b,c) ==> before(a,c)]
// - all SACKs are non-empty (sack.left before sack.right)
// - adjacent SACKs in list always have a gap between them
// (sack.right before next_sack.left)
// Given these assumptions, and noting that there are only three
// possible comparisons for a pair of points (before/equal/after),
// there are only a few possible relative configurations
// of next_old and next_new:
// next_new:
// [-------------)
// next_old:
// 1. [---)
// 2. [-------)
// 3. [----------------)
// 4. [---------------------)
// 5. [----------------------------)
// 6. [--------)
// 7. [-------------)
// 8. [--------------------)
// 9. [---)
// 10. [--------)
// 11. [---------------)
// 12. [------)
// 13. [--)
// Case 1: end of next_old is before beginning of next_new
// next_new:
// [-------------) ... <end>
// next_old:
// 1. [---) ... <end>
if (tcp_seq_before(next_old->second, next_new->first)) {
// Actions:
// advance to the next sack in old_sacks
++next_old;
// retry from the top
continue;
}
// Case 13: end of next_new is before beginning of next_old
// next_new:
// [-------------) ... <end>
// next_old:
// 13. [--) ... <end>
if (tcp_seq_before(next_new->second, next_old->first)) {
// Actions:
// add then entire length of next_new into seglen
*seglen += (next_new->second - next_new->first);
// insert next_new before next_old in old_sacks
// (be sure to save and restore next_old iterator around insert!)
int next_old_idx = int(next_old - old_sacks.begin());
old_sacks.insert(next_old, *next_new);
next_old = old_sacks.begin() + next_old_idx + 1;
// advance to the next remaining sack in new_sacks
++next_new_idx;
// retry from the top
continue;
}
// Remaining possible configurations:
// next_new:
// [-------------)
// next_old:
// 2. [-------)
// 3. [----------------)
// 4. [---------------------)
// 5. [----------------------------)
// 6. [--------)
// 7. [-------------)
// 8. [--------------------)
// 9. [---)
// 10. [--------)
// 11. [---------------)
// 12. [------)
// Cases 2,3,6,9: end of next_old is before end of next_new
// next_new:
// [-------------)
// next_old:
// 2. [-------)
// 3. [----------------)
// 6. [--------)
// 9. [---)
// Actions:
// until end of next_old is equal or after end of next_new,
// repeatedly extend next_old, coalescing with next_next_old
// if necessary. (and add extended bytes to seglen)
while (tcp_seq_before(next_old->second, next_new->second)) {
// if end of next_new doesn't collide with start of next_next_old,
if (((next_old+1) == old_sacks.end()) ||
tcp_seq_before(next_new->second, (next_old + 1)->first)) {
// extend end of next_old up to end of next_new,
// adding extended bytes to seglen
*seglen += (next_new->second - next_old->second);
next_old->second = next_new->second;
}
// otherwise, coalesce next_old with next_next_old
else {
// add bytes to close gap between sacks to seglen
*seglen += ((next_old + 1)->first - next_old->second);
// coalesce next_next_old into next_old
next_old->second = (next_old + 1)->second;
old_sacks.erase(next_old + 1);
}
}
// This operation turns:
// Cases 2 and 3 into Case 4 or 5
// Case 6 into Case 7
// Case 9 into Case 10
// Leaving:
// Remaining possible configurations:
// next_new:
// [-------------)
// next_old:
// 4. [---------------------)
// 5. [----------------------------)
// 7. [-------------)
// 8. [--------------------)
// 10. [--------)
// 11. [---------------)
// 12. [------)
// Cases 10,11,12: start of next_new is before start of next_old
// next_new:
// [-------------)
// next_old:
// 10. [--------)
// 11. [---------------)
// 12. [------)
if (tcp_seq_before(next_new->first, next_old->first)) {
// Actions:
// add the unaccounted bytes in next_new to seglen
*seglen += (next_old->first - next_new->first);
// then pull the start of next_old back to the start of next_new
next_old->first = next_new->first;
}
// This operation turns:
// Case 10 into Case 7
// Cases 11 and 12 into Case 8
// Leaving:
// Remaining possible configurations:
// next_new:
// [-------------)
// next_old:
// 4. [---------------------)
// 5. [----------------------------)
// 7. [-------------)
// 8. [--------------------)
// In these cases, the bytes in next_new are fully accounted
// by the bytes in next_old, so we can move on to look at
// the next sack block in new_sacks
++next_new_idx;
}
// Conditions for leaving loop:
// - we processed all remaining new_sacks - nothing left to do
// (next_new_idx == num_sack_ranges)
// OR
// - all remaining new_sacks start at least one byte after
// the rightmost edge of the last old_sack
// (meaning we can just add the remaining new_sacks to old_sacks list,
// and add them directly to the goodput seglen)
while (next_new_idx < num_sack_ranges) {
sack_t* next_new = &new_sacks[next_new_idx];
*seglen += (next_new->second - next_new->first);
old_sacks.push_back(*next_new);
++next_new_idx;
}
}
#endif // USE_SACKS_IN_GOODPUT_CALC
void TCPStreamDialog::fillThroughput()
{
QString dlg_title = QString(tr("Throughput")) + streamDescription();
#ifdef MA_1_SECOND
dlg_title.append(tr(" (MA)"));
#else
dlg_title.append(QString(tr(" (%1 Segment MA)")).arg(moving_avg_period_));
#endif
setWindowTitle(dlg_title);
title_->setText(dlg_title);
QCustomPlot *sp = ui->streamPlot;
sp->yAxis->setLabel(segment_length_label_);
sp->yAxis2->setLabel(average_throughput_label_);
sp->yAxis2->setLabelColor(QColor(graph_color_2));
sp->yAxis2->setTickLabelColor(QColor(graph_color_2));
sp->yAxis2->setVisible(true);
base_graph_->setVisible(ui->showSegLengthCheckBox->isChecked());
tput_graph_->setVisible(ui->showThroughputCheckBox->isChecked());
goodput_graph_->setVisible(ui->showGoodputCheckBox->isChecked());
#ifdef MA_1_SECOND
if (!graph_.segments) {
#else
if (!graph_.segments || !graph_.segments->next) {
#endif
dlg_title.append(tr(" [not enough data]"));
return;
}
QVector<double> seg_rel_times, ack_rel_times;
QVector<double> seg_lens, ack_lens;
QVector<double> tput_times, gput_times;
QVector<double> tputs, gputs;
int oldest_seg = 0, oldest_ack = 0;
guint64 seg_sum = 0, ack_sum = 0;
guint32 seglen = 0;
#ifdef USE_SACKS_IN_GOODPUT_CALC
// to incorporate SACKED segments into goodput calculation,
// need to keep track of all the SACK blocks we haven't yet
// fully ACKed.
sack_list_t old_sacks, new_sacks;
new_sacks.reserve(MAX_TCP_SACK_RANGES);
// statically allocate current_sacks vector
// [ std::array might be better, but that is C++11 ]
for (int i = 0; i < MAX_TCP_SACK_RANGES; ++i) {
new_sacks.push_back(sack_t(0,0));
}
old_sacks.reserve(2*MAX_TCP_SACK_RANGES);
#endif // USE_SACKS_IN_GOODPUT_CALC
// need first acked sequence number to jump-start
// computation of acked bytes per packet
guint32 last_ack = 0;
for (struct segment *seg = graph_.segments; seg != NULL; seg = seg->next) {
// first reverse packet with ACK flag tells us first acked sequence #
if (!compareHeaders(seg) && (seg->th_flags & TH_ACK)) {
last_ack = seg->th_ack;
break;
}
}
// Financial charts don't show MA data until a full period has elapsed.
// [ NOTE - this is because they assume that there's old data that they
// don't have access to - but in our case we know that there's NO
// data prior to the first packet in the stream - so it's fine to
// spit out the MA immediately... ]
// The Rosetta Code MA examples start spitting out values immediately.
// For now use not-really-correct initial values just to keep our vector
// lengths the same.
#ifdef MA_1_SECOND
// NOTE that for the time-based MA case, you certainly can start with the
// first segment!
for (struct segment *seg = graph_.segments; seg != NULL; seg = seg->next) {
#else
for (struct segment *seg = graph_.segments->next; seg != NULL; seg = seg->next) {
#endif
bool is_forward_seg = compareHeaders(seg);
QVector<double>& r_pkt_times = is_forward_seg ? seg_rel_times : ack_rel_times;
QVector<double>& r_lens = is_forward_seg ? seg_lens : ack_lens;
QVector<double>& r_Xput_times = is_forward_seg ? tput_times : gput_times;
QVector<double>& r_Xputs = is_forward_seg ? tputs : gputs;
int& r_oldest = is_forward_seg ? oldest_seg : oldest_ack;
guint64& r_sum = is_forward_seg ? seg_sum : ack_sum;
double ts = (seg->rel_secs + seg->rel_usecs / 1000000.0) - ts_offset_;
if (is_forward_seg) {
seglen = seg->th_seglen;
} else {
if ((seg->th_flags & TH_ACK) &&
tcp_seq_eq_or_after(seg->th_ack, last_ack)) {
seglen = seg->th_ack - last_ack;
last_ack = seg->th_ack;
#ifdef USE_SACKS_IN_GOODPUT_CALC
// copy any sack_ranges into new_sacks, and sort.
for (int i = 0; i < seg->num_sack_ranges; ++i) {
new_sacks[i].first = seg->sack_left_edge[i];
new_sacks[i].second = seg->sack_right_edge[i];
}
std::sort(new_sacks.begin(),
new_sacks.begin() + seg->num_sack_ranges,
compare_sack);
// adjust the seglen based on new and old sacks,
// and update the old_sacks list
goodput_adjust_for_sacks(&seglen, last_ack,
new_sacks, seg->num_sack_ranges,
old_sacks);
#endif // USE_SACKS_IN_GOODPUT_CALC
} else {
seglen = 0;
}
}
r_pkt_times.append(ts);
r_lens.append(seglen);
#ifdef MA_1_SECOND
while (r_oldest < r_pkt_times.size() && ts - r_pkt_times[r_oldest] > ma_window_size_) {
r_sum -= r_lens[r_oldest];
// append points where a packet LEAVES the MA window
// (as well as, below, where they ENTER the MA window)
r_Xputs.append(r_sum * 8.0 / ma_window_size_);
r_Xput_times.append(r_pkt_times[r_oldest] + ma_window_size_);
r_oldest++;
}
#else
if (r_lens.size() > moving_avg_period_) {
r_sum -= r_lens[r_oldest];
r_oldest++;
}
#endif
// av_Xput computes Xput, i.e.:
// throughput for forward packets
// goodput for reverse packets
double av_Xput;
r_sum += seglen;
#ifdef MA_1_SECOND
// for time-based MA, delta_t is constant
av_Xput = r_sum * 8.0 / ma_window_size_;
#else
double dtime = 0.0;
if (r_oldest > 0)
dtime = ts - r_pkt_times[r_oldest-1];
if (dtime > 0.0) {
av_Xput = r_sum * 8.0 / dtime;
} else {
av_Xput = 0.0;
}
#endif
// Add a data point only if our time window has advanced. Otherwise
// update the most recent point. (We might want to show a warning
// for out-of-order packets.)
if (r_Xput_times.size() > 0 && ts <= r_Xput_times.last()) {
r_Xputs[r_Xputs.size() - 1] = av_Xput;
} else {
r_Xputs.append(av_Xput);
r_Xput_times.append(ts);
}
}
base_graph_->setData(seg_rel_times, seg_lens);
tput_graph_->setData(tput_times, tputs);
goodput_graph_->setData(gput_times, gputs);
}
// rtt_selectively_ack_range:
// "Helper" function for fillRoundTripTime
// given an rtt_unack list, two pointers to a range of segments in the list,
// and the [left,right) edges of a SACK block, selectively ACKs the range
// from "begin" to "end" - possibly splitting one segment in the range
// into two (and relinking the new segment in order after the first)
//
// Assumptions:
// "begin must be non-NULL
// "begin" must precede "end" (or "end" must be NULL)
// [ there are minor optimizations that could be added if
// the range from "begin" to "end" are in sequence number order.
// (this function would preserve that as an invariant). ]
static struct rtt_unack *
rtt_selectively_ack_range(QVector<double>& x_vals, bool bySeqNumber,
QVector<double>& rtt,
struct rtt_unack **list,
struct rtt_unack *begin, struct rtt_unack *end,
unsigned int left, unsigned int right, double rt_val) {
struct rtt_unack *cur, *next;
// sanity check:
if (tcp_seq_eq_or_after(left, right))
return begin;
// real work:
for (cur = begin; cur != end; cur = next) {
next = cur->next;
// check #1: does [left,right) intersect current unack at all?
// (if not, we can just move on to the next unack)
if (tcp_seq_eq_or_after(cur->seqno, right) ||
tcp_seq_eq_or_after(left, cur->end_seqno)) {
// no intersection - just skip this.
continue;
}
// yes, we intersect!
int left_end_acked = tcp_seq_eq_or_after(cur->seqno, left);
int right_end_acked = tcp_seq_eq_or_after(right, cur->end_seqno);
// check #2 - did we fully ack the current unack?
// (if so, we can delete it and move on)
if (left_end_acked && right_end_acked) {
// ACK the whole segment
if (bySeqNumber) {
x_vals.append(cur->seqno);
} else {
x_vals.append(cur->time);
}
rtt.append((rt_val - cur->time) * 1000.0);
// in this case, we will delete current unack
// [ update "begin" if necessary - we will return it to the
// caller to let them know we deleted it ]
if (cur == begin)
begin = next;
rtt_delete_unack_from_list(list, cur);
continue;
}
// check #3 - did we ACK the left-hand side of the current unack?
// (if so, we can just modify it and move on)
if (left_end_acked) { // and right_end_not_acked
// ACK the left end
if (bySeqNumber) {
x_vals.append(cur->seqno);
} else {
x_vals.append(cur->time);
}
rtt.append((rt_val - cur->time) * 1000.0);
// in this case, "right" marks the start of remaining bytes
cur->seqno = right;
continue;
}
// check #4 - did we ACK the right-hand side of the current unack?
// (if so, we can just modify it and move on)
if (right_end_acked) { // and left_end_not_acked
// ACK the right end
if (bySeqNumber) {
x_vals.append(left);
} else {
x_vals.append(cur->time);
}
rtt.append((rt_val - cur->time) * 1000.0);
// in this case, "left" is just beyond the remaining bytes
cur->end_seqno = left;
continue;
}
// at this point, we know:
// - the SACK block does intersect this unack, but
// - it does not intersect the left or right endpoints
// Therefore, it must intersect the middle, so we must split the unack
// into left and right unacked segments:
// ACK the SACK block
if (bySeqNumber) {
x_vals.append(left);
} else {
x_vals.append(cur->time);
}
rtt.append((rt_val - cur->time) * 1000.0);
// then split cur into two unacked segments
// (linking the right-hand unack after the left)
cur->next = rtt_get_new_unack(cur->time, right, cur->end_seqno - right);
cur->next->next = next;
cur->end_seqno = left;
}
return begin;
}
void TCPStreamDialog::fillRoundTripTime()
{
QString dlg_title = QString(tr("Round Trip Time")) + streamDescription();
setWindowTitle(dlg_title);
title_->setText(dlg_title);
QCustomPlot *sp = ui->streamPlot;
bool bySeqNumber = ui->bySeqNumberCheckBox->isChecked();
if (bySeqNumber) {
sequence_num_map_.clear();
sp->xAxis->setLabel(sequence_number_label_);
sp->xAxis->setNumberFormat("f");
sp->xAxis->setNumberPrecision(0);
}
sp->yAxis->setLabel(round_trip_time_ms_label_);
sp->yAxis->setNumberFormat("gb");
sp->yAxis->setNumberPrecision(3);
base_graph_->setLineStyle(QCPGraph::lsLine);
QVector<double> x_vals, rtt;
guint32 seq_base = 0;
struct rtt_unack *unack_list = NULL, *u = NULL;
for (struct segment *seg = graph_.segments; seg != NULL; seg = seg->next) {
if (compareHeaders(seg)) {
seq_base = seg->th_seq;
break;
}
}
for (struct segment *seg = graph_.segments; seg != NULL; seg = seg->next) {
if (compareHeaders(seg)) {
guint32 seqno = seg->th_seq - seq_base;
if (seg->th_seglen && !rtt_is_retrans(unack_list, seqno)) {
double rt_val = seg->rel_secs + seg->rel_usecs / 1000000.0;
rt_val -= ts_offset_;
u = rtt_get_new_unack(rt_val, seqno, seg->th_seglen);
if (!u) {
// make sure to free list before returning!
rtt_destroy_unack_list(&unack_list);
return;
}
rtt_put_unack_on_list(&unack_list, u);
}
} else {
guint32 ack_no = seg->th_ack - seq_base;
double rt_val = seg->rel_secs + seg->rel_usecs / 1000000.0;
rt_val -= ts_offset_;
struct rtt_unack *v;
for (u = unack_list; u; u = v) {
if (tcp_seq_after(ack_no, u->seqno)) {
// full or partial ack of seg by ack_no
if (bySeqNumber) {
x_vals.append(u->seqno);
sequence_num_map_.insert(u->seqno, seg);
} else {
x_vals.append(u->time);
}
rtt.append((rt_val - u->time) * 1000.0);
if (tcp_seq_eq_or_after(ack_no, u->end_seqno)) {
// fully acked segment - nothing more to see here
v = u->next;
rtt_delete_unack_from_list(&unack_list, u);
// no need to compare SACK blocks for fully ACKed seg
continue;
} else {
// partial ack of GSO seg
u->seqno = ack_no;
// (keep going - still need to compare SACK blocks...)
}
}
v = u->next;
// selectively acking u more than once
// can shatter it into multiple intervals.
// If we link those back into the list between u and v,
// then each subsequent SACK selectively ACKs that range.
for (int i = 0; i < seg->num_sack_ranges; ++i) {
guint32 left = seg->sack_left_edge[i] - seq_base;
guint32 right = seg->sack_right_edge[i] - seq_base;
u = rtt_selectively_ack_range(x_vals, bySeqNumber, rtt,
&unack_list, u, v,
left, right, rt_val);
// if range is empty after selective ack, we can
// skip the rest of the SACK blocks
if (u == v) break;
}
}
}
}
// it's possible there's still unacked segs - so be sure to free list!
rtt_destroy_unack_list(&unack_list);
base_graph_->setData(x_vals, rtt);
}
void TCPStreamDialog::fillWindowScale()
{
QString dlg_title = QString(tr("Window Scaling")) + streamDescription();
setWindowTitle(dlg_title);
title_->setText(dlg_title);
QCustomPlot *sp = ui->streamPlot;
// use base_graph_ to represent unacked window size
// (estimate of congestion window)
base_graph_->setLineStyle(QCPGraph::lsStepLeft);
// use rwin_graph_ here to show rwin window scale
// (derived from ACK packets)
base_graph_->setVisible(ui->showBytesOutCheckBox->isChecked());
rwin_graph_->setVisible(ui->showRcvWinCheckBox->isChecked());
QVector<double> rel_time, win_size;
QVector<double> cwnd_time, cwnd_size;
guint32 last_ack = 0;
bool found_first_ack = false;
for (struct segment *seg = graph_.segments; seg != NULL; seg = seg->next) {
double ts = seg->rel_secs + seg->rel_usecs / 1000000.0;
// The receive window that applies to this flow comes
// from packets in the opposite direction
if (compareHeaders(seg)) {
// compute bytes_in_flight for cwnd graph
guint32 end_seq = seg->th_seq + seg->th_seglen;
if (found_first_ack &&
tcp_seq_eq_or_after(end_seq, last_ack)) {
cwnd_time.append(ts - ts_offset_);
cwnd_size.append((double)(end_seq - last_ack));
}
} else {
// packet in opposite direction - has advertised rwin
guint16 flags = seg->th_flags;
if ((flags & (TH_SYN|TH_RST)) == 0) {
rel_time.append(ts - ts_offset_);
win_size.append(seg->th_win);
}
if ((flags & (TH_ACK)) != 0) {
// use this to update last_ack
if (!found_first_ack ||
tcp_seq_eq_or_after(seg->th_ack, last_ack)) {
last_ack = seg->th_ack;
found_first_ack = true;
}
}
}
}
base_graph_->setData(cwnd_time, cwnd_size);
rwin_graph_->setData(rel_time, win_size);
sp->yAxis->setLabel(window_size_label_);
}
QString TCPStreamDialog::streamDescription()
{
QString description(tr(" for %1:%2 %3 %4:%5")
.arg(address_to_qstring(&graph_.src_address))
.arg(graph_.src_port)
.arg(UTF8_RIGHTWARDS_ARROW)
.arg(address_to_qstring(&graph_.dst_address))
.arg(graph_.dst_port));
return description;
}
bool TCPStreamDialog::compareHeaders(segment *seg)
{
return (compare_headers(&graph_.src_address, &graph_.dst_address,
graph_.src_port, graph_.dst_port,
&seg->ip_src, &seg->ip_dst,
seg->th_sport, seg->th_dport,
COMPARE_CURR_DIR));
}
void TCPStreamDialog::toggleTracerStyle(bool force_default)
{
if (!tracer_->visible() && !force_default) return;
QPen sp_pen = ui->streamPlot->graph(0)->pen();
QCPItemTracer::TracerStyle tstyle = QCPItemTracer::tsCrosshair;
QPen tr_pen = QPen(tracer_->pen());
QColor tr_color = sp_pen.color();
if (force_default || tracer_->style() != QCPItemTracer::tsCircle) {
tstyle = QCPItemTracer::tsCircle;
tr_color.setAlphaF(1.0);
tr_pen.setWidthF(1.5);
} else {
tr_color.setAlphaF(0.5);
tr_pen.setWidthF(1.0);
}
tracer_->setStyle(tstyle);
tr_pen.setColor(tr_color);
tracer_->setPen(tr_pen);
ui->streamPlot->replot();
}
QRectF TCPStreamDialog::getZoomRanges(QRect zoom_rect)
{
QRectF zoom_ranges = QRectF();
QCustomPlot *sp = ui->streamPlot;
QRect zr = zoom_rect.normalized();
if (zr.width() < min_zoom_pixels_ && zr.height() < min_zoom_pixels_) {
return zoom_ranges;
}
QRect ar = sp->axisRect()->rect();
if (ar.intersects(zr)) {
QRect zsr = ar.intersected(zr);
zoom_ranges.setX(sp->xAxis->range().lower
+ sp->xAxis->range().size() * (zsr.left() - ar.left()) / ar.width());
zoom_ranges.setWidth(sp->xAxis->range().size() * zsr.width() / ar.width());
// QRects grow down
zoom_ranges.setY(sp->yAxis->range().lower
+ sp->yAxis->range().size() * (ar.bottom() - zsr.bottom()) / ar.height());
zoom_ranges.setHeight(sp->yAxis->range().size() * zsr.height() / ar.height());
}
return zoom_ranges;
}
void TCPStreamDialog::graphClicked(QMouseEvent *event)
{
QCustomPlot *sp = ui->streamPlot;
// mouse press on graph should reset focus to graph
sp->setFocus();
if (event->button() == Qt::RightButton) {
// XXX We should find some way to get streamPlot to handle a
// contextMenuEvent instead.
#if QT_VERSION >= QT_VERSION_CHECK(6, 0 ,0)
ctx_menu_.popup(event->globalPosition().toPoint());
#else
ctx_menu_.popup(event->globalPos());
#endif
} else if (mouse_drags_) {
if (sp->axisRect()->rect().contains(event->pos())) {
sp->setCursor(QCursor(Qt::ClosedHandCursor));
}
on_actionGoToPacket_triggered();
} else {
if (!rubber_band_) {
rubber_band_ = new QRubberBand(QRubberBand::Rectangle, sp);
}
rb_origin_ = event->pos();
rubber_band_->setGeometry(QRect(rb_origin_, QSize()));
rubber_band_->show();
}
}
void TCPStreamDialog::axisClicked(QCPAxis *axis, QCPAxis::SelectablePart, QMouseEvent *)
{
QCustomPlot *sp = ui->streamPlot;
if (axis == sp->xAxis) {
switch (graph_.type) {
case GRAPH_THROUGHPUT:
case GRAPH_TSEQ_STEVENS:
case GRAPH_TSEQ_TCPTRACE:
case GRAPH_WSCALE:
case GRAPH_RTT:
ts_origin_conn_ = ts_origin_conn_ ? false : true;
fillGraph();
break;
default:
break;
}
} else if (axis == sp->yAxis) {
switch (graph_.type) {
case GRAPH_TSEQ_STEVENS:
case GRAPH_TSEQ_TCPTRACE:
seq_origin_zero_ = seq_origin_zero_ ? false : true;
fillGraph();
break;
default:
break;
}
}
}
// Setting mouseTracking on our streamPlot may not be as reliable
// as we need. If it's not we might want to poll the mouse position
// using a QTimer instead.
void TCPStreamDialog::mouseMoved(QMouseEvent *event)
{
QCustomPlot *sp = ui->streamPlot;
Qt::CursorShape shape = Qt::ArrowCursor;
if (event) {
if (event->buttons().testFlag(Qt::LeftButton)) {
if (mouse_drags_) {
shape = Qt::ClosedHandCursor;
} else {
shape = Qt::CrossCursor;
}
} else {
if (sp->axisRect()->rect().contains(event->pos())) {
if (mouse_drags_) {
shape = Qt::OpenHandCursor;
} else {
shape = Qt::CrossCursor;
}
}
}
}
sp->setCursor(QCursor(shape));
QString hint = "<small><i>";
if (mouse_drags_) {
double tr_key = tracer_->position->key();
struct segment *packet_seg = NULL;
packet_num_ = 0;
// XXX If we have multiple packets with the same timestamp tr_key
// may not return the packet we want. It might be possible to fudge
// unique keys using nextafter().
if (event && tracer_->graph() && tracer_->position->axisRect()->rect().contains(event->pos())) {
switch (graph_.type) {
case GRAPH_TSEQ_STEVENS:
case GRAPH_TSEQ_TCPTRACE:
case GRAPH_THROUGHPUT:
case GRAPH_WSCALE:
packet_seg = time_stamp_map_.value(tr_key, NULL);
break;
case GRAPH_RTT:
if (ui->bySeqNumberCheckBox->isChecked())
packet_seg = sequence_num_map_.value(tr_key, NULL);
else
packet_seg = time_stamp_map_.value(tr_key, NULL);
default:
break;
}
}
if (!packet_seg) {
tracer_->setVisible(false);
hint += "Hover over the graph for details. " + stream_desc_ + "</i></small>";
ui->hintLabel->setText(hint);
ui->streamPlot->replot();
return;
}
tracer_->setVisible(true);
packet_num_ = packet_seg->num;
hint += tr("%1 %2 (%3s len %4 seq %5 ack %6 win %7)")
.arg(cap_file_ ? tr("Click to select packet") : tr("Packet"))
.arg(packet_num_)
.arg(QString::number(packet_seg->rel_secs + packet_seg->rel_usecs / 1000000.0, 'g', 4))
.arg(packet_seg->th_seglen)
.arg(packet_seg->th_seq)
.arg(packet_seg->th_ack)
.arg(packet_seg->th_win);
tracer_->setGraphKey(ui->streamPlot->xAxis->pixelToCoord(event->pos().x()));
sp->replot();
} else {
if (rubber_band_ && rubber_band_->isVisible() && event) {
rubber_band_->setGeometry(QRect(rb_origin_, event->pos()).normalized());
QRectF zoom_ranges = getZoomRanges(QRect(rb_origin_, event->pos()));
if (zoom_ranges.width() > 0.0 && zoom_ranges.height() > 0.0) {
hint += tr("Release to zoom, x = %1 to %2, y = %3 to %4")
.arg(zoom_ranges.x())
.arg(zoom_ranges.x() + zoom_ranges.width())
.arg(zoom_ranges.y())
.arg(zoom_ranges.y() + zoom_ranges.height());
} else {
hint += tr("Unable to select range.");
}
} else {
hint += tr("Click to select a portion of the graph.");
}
}
hint += " " + stream_desc_ + "</i></small>";
ui->hintLabel->setText(hint);
}
void TCPStreamDialog::mouseReleased(QMouseEvent *event)
{
if (rubber_band_ && rubber_band_->isVisible()) {
rubber_band_->hide();
if (!mouse_drags_) {
QRectF zoom_ranges = getZoomRanges(QRect(rb_origin_, event->pos()));
if (zoom_ranges.width() > 0.0 && zoom_ranges.height() > 0.0) {
QCustomPlot *sp = ui->streamPlot;
sp->xAxis->setRangeLower(zoom_ranges.x());
sp->xAxis->setRangeUpper(zoom_ranges.x() + zoom_ranges.width());
sp->yAxis->setRangeLower(zoom_ranges.y());
sp->yAxis->setRangeUpper(zoom_ranges.y() + zoom_ranges.height());
sp->replot();
}
}
} else if (ui->streamPlot->cursor().shape() == Qt::ClosedHandCursor) {
ui->streamPlot->setCursor(QCursor(Qt::OpenHandCursor));
}
}
void TCPStreamDialog::transformYRange(const QCPRange &y_range1)
{
if (y_axis_xfrm_.isIdentity()) return;
QCustomPlot *sp = ui->streamPlot;
QLineF yp1 = QLineF(1.0, y_range1.lower, 1.0, y_range1.upper);
QLineF yp2 = y_axis_xfrm_.map(yp1);
sp->yAxis2->setRangeUpper(yp2.y2());
sp->yAxis2->setRangeLower(yp2.y1());
}
// XXX - We have similar code in io_graph_dialog and packet_diagram. Should this be a common routine?
void TCPStreamDialog::on_buttonBox_accepted()
{
QString file_name, extension;
QDir path(mainApp->lastOpenDir());
QString pdf_filter = tr("Portable Document Format (*.pdf)");
QString png_filter = tr("Portable Network Graphics (*.png)");
QString bmp_filter = tr("Windows Bitmap (*.bmp)");
// Gaze upon my beautiful graph with lossy artifacts!
QString jpeg_filter = tr("JPEG File Interchange Format (*.jpeg *.jpg)");
QString filter = QString("%1;;%2;;%3;;%4")
.arg(pdf_filter)
.arg(png_filter)
.arg(bmp_filter)
.arg(jpeg_filter);
file_name = WiresharkFileDialog::getSaveFileName(this, mainApp->windowTitleString(tr("Save Graph As…")),
path.canonicalPath(), filter, &extension);
if (file_name.length() > 0) {
bool save_ok = false;
if (extension.compare(pdf_filter) == 0) {
save_ok = ui->streamPlot->savePdf(file_name);
} else if (extension.compare(png_filter) == 0) {
save_ok = ui->streamPlot->savePng(file_name);
} else if (extension.compare(bmp_filter) == 0) {
save_ok = ui->streamPlot->saveBmp(file_name);
} else if (extension.compare(jpeg_filter) == 0) {
save_ok = ui->streamPlot->saveJpg(file_name);
}
// else error dialog?
if (save_ok) {
mainApp->setLastOpenDirFromFilename(file_name);
}
}
}
void TCPStreamDialog::on_graphTypeComboBox_currentIndexChanged(int index)
{
if (index < 0) return;
graph_.type = static_cast<tcp_graph_type>(ui->graphTypeComboBox->itemData(index).toInt());
showWidgetsForGraphType();
fillGraph(/*reset_axes=*/true, /*set_focus=*/false);
}
void TCPStreamDialog::on_resetButton_clicked()
{
resetAxes();
}
void TCPStreamDialog::setCaptureFile(capture_file *cf)
{
if (!cf) { // We only want to know when the file closes.
cap_file_ = NULL;
}
}
void TCPStreamDialog::updateGraph()
{
graph_updater_.doUpdate();
}
void TCPStreamDialog::on_streamNumberSpinBox_valueChanged(int new_stream)
{
if (new_stream >= 0 && new_stream < int(get_tcp_stream_count())) {
graph_updater_.triggerUpdate(1000, /*reset_axes =*/true);
}
}
void TCPStreamDialog::on_streamNumberSpinBox_editingFinished()
{
updateGraph();
}
void TCPStreamDialog::on_maWindowSizeSpinBox_valueChanged(double new_ma_size)
{
if (new_ma_size > 0.0) {
ma_window_size_ = new_ma_size;
graph_updater_.triggerUpdate(1000, /*reset_axes =*/false);
}
}
void TCPStreamDialog::on_maWindowSizeSpinBox_editingFinished()
{
updateGraph();
}
void TCPStreamDialog::on_selectSACKsCheckBox_stateChanged(int /* state */)
{
fillGraph(/*reset_axes=*/false, /*set_focus=*/false);
}
void TCPStreamDialog::on_otherDirectionButton_clicked()
{
on_actionSwitchDirection_triggered();
}
void TCPStreamDialog::on_dragRadioButton_toggled(bool checked)
{
if (checked) {
mouse_drags_ = true;
if (rubber_band_ && rubber_band_->isVisible())
rubber_band_->hide();
ui->streamPlot->setInteractions(
QCP::iRangeDrag |
QCP::iRangeZoom
);
}
}
void TCPStreamDialog::on_zoomRadioButton_toggled(bool checked)
{
if (checked) {
mouse_drags_ = false;
ui->streamPlot->setInteractions(QCP::Interactions());
}
}
void TCPStreamDialog::on_bySeqNumberCheckBox_stateChanged(int /* state */)
{
fillGraph(/*reset_axes=*/true, /*set_focus=*/false);
}
void TCPStreamDialog::on_showSegLengthCheckBox_stateChanged(int state)
{
bool visible = (state != 0);
if (graph_.type == GRAPH_THROUGHPUT && base_graph_ != NULL) {
base_graph_->setVisible(visible);
tracer_->setGraph(visible ? base_graph_ : NULL);
ui->streamPlot->replot();
}
}
void TCPStreamDialog::on_showThroughputCheckBox_stateChanged(int state)
{
bool visible = (state != 0);
if (graph_.type == GRAPH_THROUGHPUT && tput_graph_ != NULL) {
tput_graph_->setVisible(visible);
ui->streamPlot->replot();
}
}
void TCPStreamDialog::on_showGoodputCheckBox_stateChanged(int state)
{
bool visible = (state != 0);
if (graph_.type == GRAPH_THROUGHPUT && goodput_graph_ != NULL) {
goodput_graph_->setVisible(visible);
ui->streamPlot->replot();
}
}
void TCPStreamDialog::on_showRcvWinCheckBox_stateChanged(int state)
{
bool visible = (state != 0);
if (graph_.type == GRAPH_WSCALE && rwin_graph_ != NULL) {
rwin_graph_->setVisible(visible);
ui->streamPlot->replot();
}
}
void TCPStreamDialog::on_showBytesOutCheckBox_stateChanged(int state)
{
bool visible = (state != 0);
if (graph_.type == GRAPH_WSCALE && base_graph_ != NULL) {
base_graph_->setVisible(visible);
tracer_->setGraph(visible ? base_graph_ : NULL);
ui->streamPlot->replot();
}
}
void TCPStreamDialog::on_actionZoomIn_triggered()
{
zoomAxes(true);
}
void TCPStreamDialog::on_actionZoomInX_triggered()
{
zoomXAxis(true);
}
void TCPStreamDialog::on_actionZoomInY_triggered()
{
zoomYAxis(true);
}
void TCPStreamDialog::on_actionZoomOut_triggered()
{
zoomAxes(false);
}
void TCPStreamDialog::on_actionZoomOutX_triggered()
{
zoomXAxis(false);
}
void TCPStreamDialog::on_actionZoomOutY_triggered()
{
zoomYAxis(false);
}
void TCPStreamDialog::on_actionReset_triggered()
{
on_resetButton_clicked();
}
void TCPStreamDialog::on_actionMoveRight10_triggered()
{
panAxes(10, 0);
}
void TCPStreamDialog::on_actionMoveLeft10_triggered()
{
panAxes(-10, 0);
}
void TCPStreamDialog::on_actionMoveUp10_triggered()
{
panAxes(0, 10);
}
void TCPStreamDialog::on_actionMoveDown10_triggered()
{
panAxes(0, -10);
}
void TCPStreamDialog::on_actionMoveRight1_triggered()
{
panAxes(1, 0);
}
void TCPStreamDialog::on_actionMoveLeft1_triggered()
{
panAxes(-1, 0);
}
void TCPStreamDialog::on_actionMoveUp1_triggered()
{
panAxes(0, 1);
}
void TCPStreamDialog::on_actionMoveDown1_triggered()
{
panAxes(0, -1);
}
void TCPStreamDialog::on_actionNextStream_triggered()
{
if (int(graph_.stream) < int(get_tcp_stream_count()) - 1) {
ui->streamNumberSpinBox->setValue(graph_.stream + 1);
updateGraph();
}
}
void TCPStreamDialog::on_actionPreviousStream_triggered()
{
if (graph_.stream > 0) {
ui->streamNumberSpinBox->setValue(graph_.stream - 1);
updateGraph();
}
}
void TCPStreamDialog::on_actionSwitchDirection_triggered()
{
address tmp_addr;
guint16 tmp_port;
copy_address(&tmp_addr, &graph_.src_address);
tmp_port = graph_.src_port;
free_address(&graph_.src_address);
copy_address(&graph_.src_address, &graph_.dst_address);
graph_.src_port = graph_.dst_port;
free_address(&graph_.dst_address);
copy_address(&graph_.dst_address, &tmp_addr);
graph_.dst_port = tmp_port;
free_address(&tmp_addr);
fillGraph(/*reset_axes=*/true, /*set_focus=*/false);
}
void TCPStreamDialog::on_actionGoToPacket_triggered()
{
if (tracer_->visible() && cap_file_ && packet_num_ > 0) {
emit goToPacket(packet_num_);
}
}
void TCPStreamDialog::on_actionDragZoom_triggered()
{
if (mouse_drags_) {
ui->zoomRadioButton->toggle();
} else {
ui->dragRadioButton->toggle();
}
}
void TCPStreamDialog::on_actionToggleSequenceNumbers_triggered()
{
seq_origin_zero_ = seq_origin_zero_ ? false : true;
fillGraph();
}
void TCPStreamDialog::on_actionToggleTimeOrigin_triggered()
{
ts_origin_conn_ = ts_origin_conn_ ? false : true;
fillGraph();
}
void TCPStreamDialog::on_actionRoundTripTime_triggered()
{
ui->graphTypeComboBox->setCurrentIndex(ui->graphTypeComboBox->findData(GRAPH_RTT));
}
void TCPStreamDialog::on_actionThroughput_triggered()
{
ui->graphTypeComboBox->setCurrentIndex(ui->graphTypeComboBox->findData(GRAPH_THROUGHPUT));
}
void TCPStreamDialog::on_actionStevens_triggered()
{
ui->graphTypeComboBox->setCurrentIndex(ui->graphTypeComboBox->findData(GRAPH_TSEQ_STEVENS));
}
void TCPStreamDialog::on_actionTcptrace_triggered()
{
ui->graphTypeComboBox->setCurrentIndex(ui->graphTypeComboBox->findData(GRAPH_TSEQ_TCPTRACE));
}
void TCPStreamDialog::on_actionWindowScaling_triggered()
{
ui->graphTypeComboBox->setCurrentIndex(ui->graphTypeComboBox->findData(GRAPH_WSCALE));
}
void TCPStreamDialog::GraphUpdater::triggerUpdate(int timeout, bool reset_axes)
{
if (!hasPendingUpdate()) {
graph_update_timer_ = new QTimer(dialog_);
graph_update_timer_->setSingleShot(true);
dialog_->connect(graph_update_timer_, SIGNAL(timeout()), dialog_, SLOT(updateGraph()));
}
reset_axes_ = (reset_axes_ || reset_axes);
graph_update_timer_->start(timeout);
}
void TCPStreamDialog::GraphUpdater::clearPendingUpdate()
{
if (hasPendingUpdate()) {
if (graph_update_timer_->isActive())
graph_update_timer_->stop();
delete graph_update_timer_;
graph_update_timer_ = NULL;
reset_axes_ = false;
}
}
void TCPStreamDialog::GraphUpdater::doUpdate()
{
if (hasPendingUpdate()) {
bool reset_axes = reset_axes_;
clearPendingUpdate();
// if the stream has changed, update the data here
int new_stream = dialog_->ui->streamNumberSpinBox->value();
if ((int(dialog_->graph_.stream) != new_stream) &&
(new_stream >= 0 && new_stream < int(get_tcp_stream_count()))) {
dialog_->graph_.stream = new_stream;
dialog_->findStream();
}
dialog_->fillGraph(reset_axes, /*set_focus =*/false);
}
}
void TCPStreamDialog::on_buttonBox_helpRequested()
{
mainApp->helpTopicAction(HELP_STATS_TCP_STREAM_GRAPHS_DIALOG);
}
Reference in New Issue View Git Blame Copy Permalink