using pv::data::LogicSegment;
using pv::data::SignalBase;
using pv::util::SIPrefix;
+using pv::util::determine_value_prefix;
namespace pv {
namespace views {
namespace trace {
-const QColor AnalogSignal::SignalColors[4] = {
- QColor(0xC4, 0xA0, 0x00), // Yellow
- QColor(0x87, 0x20, 0x7A), // Magenta
- QColor(0x20, 0x4A, 0x87), // Blue
- QColor(0x4E, 0x9A, 0x06) // Green
-};
-
const QPen AnalogSignal::AxisPen(QColor(0, 0, 0, 30 * 256 / 100), 2);
const QColor AnalogSignal::GridMajorColor = QColor(0, 0, 0, 40 * 256 / 100);
const QColor AnalogSignal::GridMinorColor = QColor(0, 0, 0, 20 * 256 / 100);
-const QColor AnalogSignal::SamplingPointColor(0x77, 0x77, 0x77);
const QColor AnalogSignal::SamplingPointColorLo = QColor(200, 0, 0, 80 * 256 / 100);
const QColor AnalogSignal::SamplingPointColorNe = QColor(0, 0, 0, 80 * 256 / 100);
const QColor AnalogSignal::SamplingPointColorHi = QColor(0, 200, 0, 80 * 256 / 100);
const float AnalogSignal::EnvelopeThreshold = 64.0f;
const int AnalogSignal::MaximumVDivs = 10;
-const int AnalogSignal::MinScaleIndex = -6;
-const int AnalogSignal::MaxScaleIndex = 7;
+const int AnalogSignal::MinScaleIndex = -6; // 0.01 units/div
+const int AnalogSignal::MaxScaleIndex = 10; // 1000 units/div
const int AnalogSignal::InfoTextMarginRight = 20;
const int AnalogSignal::InfoTextMarginBottom = 5;
-AnalogSignal::AnalogSignal(
- pv::Session &session,
- shared_ptr<data::SignalBase> base) :
- Signal(session, base),
+AnalogSignal::AnalogSignal(pv::Session &session, shared_ptr<data::SignalBase> base) :
+ LogicSignal(session, base),
+ value_at_hover_pos_(std::numeric_limits<float>::quiet_NaN()),
scale_index_(4), // 20 per div
pos_vdivs_(1),
neg_vdivs_(1),
resolution_(0),
- display_type_(DisplayBoth),
- autoranging_(true),
- value_at_hover_pos_(std::numeric_limits<float>::quiet_NaN())
+ display_type_(DisplayAnalog),
+ autoranging_(true)
{
axis_pen_ = AxisPen;
pv::data::Analog* analog_data =
- dynamic_cast<pv::data::Analog*>(data().get());
+ dynamic_cast<pv::data::Analog*>(base_->analog_data().get());
connect(analog_data, SIGNAL(min_max_changed(float, float)),
this, SLOT(on_min_max_changed(float, float)));
settings.value(GlobalSettings::Key_View_ConversionThresholdDispMode).toInt();
div_height_ = settings.value(GlobalSettings::Key_View_DefaultDivHeight).toInt();
- base_->set_color(SignalColors[base_->index() % countof(SignalColors)]);
+ update_logic_level_offsets();
update_scale();
}
-shared_ptr<pv::data::SignalData> AnalogSignal::data() const
+std::map<QString, QVariant> AnalogSignal::save_settings() const
{
- return base_->analog_data();
-}
+ LogicSignal::save_settings();
-void AnalogSignal::save_settings(QSettings &settings) const
-{
- settings.setValue("pos_vdivs", pos_vdivs_);
- settings.setValue("neg_vdivs", neg_vdivs_);
- settings.setValue("scale_index", scale_index_);
- settings.setValue("display_type", display_type_);
- settings.setValue("autoranging", autoranging_);
- settings.setValue("div_height", div_height_);
+ std::map<QString, QVariant> result;
+
+ result["pos_vdivs"] = pos_vdivs_;
+ result["neg_vdivs"] = neg_vdivs_;
+ result["scale_index"] = scale_index_;
+ result["display_type"] = display_type_;
+ result["autoranging"] = autoranging_;
+ result["div_height"] = div_height_;
+
+ return result;
}
-void AnalogSignal::restore_settings(QSettings &settings)
+void AnalogSignal::restore_settings(std::map<QString, QVariant> settings)
{
- if (settings.contains("pos_vdivs"))
- pos_vdivs_ = settings.value("pos_vdivs").toInt();
+ LogicSignal::restore_settings(settings);
+
+ auto entry = settings.find("pos_vdivs");
+ if (entry != settings.end())
+ pos_vdivs_ = settings["pos_vdivs"].toInt();
- if (settings.contains("neg_vdivs"))
- neg_vdivs_ = settings.value("neg_vdivs").toInt();
+ entry = settings.find("neg_vdivs");
+ if (entry != settings.end())
+ neg_vdivs_ = settings["neg_vdivs"].toInt();
- if (settings.contains("scale_index")) {
- scale_index_ = settings.value("scale_index").toInt();
+ entry = settings.find("scale_index");
+ if (entry != settings.end()) {
+ scale_index_ = settings["scale_index"].toInt();
update_scale();
}
- if (settings.contains("display_type"))
- display_type_ = (DisplayType)(settings.value("display_type").toInt());
+ entry = settings.find("display_type");
+ if (entry != settings.end())
+ display_type_ = (DisplayType)(settings["display_type"].toInt());
- if (settings.contains("autoranging"))
- autoranging_ = settings.value("autoranging").toBool();
+ entry = settings.find("autoranging");
+ if (entry != settings.end())
+ autoranging_ = settings["autoranging"].toBool();
- if (settings.contains("div_height")) {
+ entry = settings.find("div_height");
+ if (entry != settings.end()) {
const int old_height = div_height_;
- div_height_ = settings.value("div_height").toInt();
+ div_height_ = settings["div_height"].toInt();
+
+ update_logic_level_offsets();
if ((div_height_ != old_height) && owner_) {
// Call order is important, otherwise the lazy event handler won't work
{
const int ph = pos_vdivs_ * div_height_;
const int nh = neg_vdivs_ * div_height_;
+
return make_pair(-ph, nh);
}
paint_grid(p, y, pp.left(), pp.right());
shared_ptr<pv::data::AnalogSegment> segment = get_analog_segment_to_paint();
- if (!segment || (segment->get_sample_count() == 0))
- return;
-
- const double pixels_offset = pp.pixels_offset();
- const double samplerate = max(1.0, segment->samplerate());
- const pv::util::Timestamp& start_time = segment->start_time();
- const int64_t last_sample = (int64_t)segment->get_sample_count() - 1;
- const double samples_per_pixel = samplerate * pp.scale();
- const pv::util::Timestamp start = samplerate * (pp.offset() - start_time);
- const pv::util::Timestamp end = start + samples_per_pixel * pp.width();
-
- const int64_t start_sample = min(max(floor(start).convert_to<int64_t>(),
- (int64_t)0), last_sample);
- const int64_t end_sample = min(max((ceil(end) + 1).convert_to<int64_t>(),
- (int64_t)0), last_sample);
-
- if (samples_per_pixel < EnvelopeThreshold)
- paint_trace(p, segment, y, pp.left(), start_sample, end_sample,
- pixels_offset, samples_per_pixel);
- else
- paint_envelope(p, segment, y, pp.left(), start_sample, end_sample,
- pixels_offset, samples_per_pixel);
+
+ if (segment && (segment->get_sample_count() > 0)) {
+ const double pixels_offset = pp.pixels_offset();
+ const double samplerate = max(1.0, segment->samplerate());
+ const pv::util::Timestamp& start_time = segment->start_time();
+ const int64_t last_sample = (int64_t)segment->get_sample_count() - 1;
+ const double samples_per_pixel = samplerate * pp.scale();
+ const pv::util::Timestamp start = samplerate * (pp.offset() - start_time);
+ const pv::util::Timestamp end = start + samples_per_pixel * pp.width();
+
+ const int64_t start_sample = min(max(floor(start).convert_to<int64_t>(),
+ (int64_t)0), last_sample);
+ const int64_t end_sample = min(max((ceil(end) + 1).convert_to<int64_t>(),
+ (int64_t)0), last_sample);
+
+ if (samples_per_pixel < EnvelopeThreshold)
+ paint_trace(p, segment, y, pp.left(), start_sample, end_sample,
+ pixels_offset, samples_per_pixel);
+ else
+ paint_envelope(p, segment, y, pp.left(), start_sample, end_sample,
+ pixels_offset, samples_per_pixel);
+ }
}
if ((display_type_ == DisplayConverted) || (display_type_ == DisplayBoth))
- paint_logic_mid(p, pp);
+ if (base_->logic_data())
+ LogicSignal::paint_mid(p, pp);
+
+ const QString err = base_->get_error_message();
+ if (!err.isEmpty())
+ paint_error(p, pp);
}
void AnalogSignal::paint_fore(QPainter &p, ViewItemPaintParams &pp)
QString infotext;
+ SIPrefix prefix;
+ if (fabs(signal_max_) > fabs(signal_min_))
+ prefix = determine_value_prefix(fabs(signal_max_));
+ else
+ prefix = determine_value_prefix(fabs(signal_min_));
+
// Show the info section on the right side of the trace, including
// the value at the hover point when the hover marker is enabled
// and we have corresponding data available
if (show_hover_marker_ && !std::isnan(value_at_hover_pos_)) {
infotext = QString("[%1] %2 V/div")
- .arg(format_value_si(value_at_hover_pos_, SIPrefix::unspecified, 2, "V", false))
+ .arg(format_value_si(value_at_hover_pos_, prefix, 3, "V", false))
.arg(resolution_);
} else
infotext = QString("%1 V/div").arg(resolution_);
v_extents().second - v_extents().first - InfoTextMarginBottom);
p.drawText(bounding_rect, Qt::AlignRight | Qt::AlignBottom, infotext);
+
+ if (show_hover_marker_)
+ paint_hover_marker(p);
}
- if (show_hover_marker_)
- paint_hover_marker(p);
+ if ((display_type_ == DisplayConverted) || (display_type_ == DisplayBoth))
+ LogicSignal::paint_fore(p, pp);
}
void AnalogSignal::paint_grid(QPainter &p, int y, int left, int right)
{
- bool wasAntialiased = p.testRenderHint(QPainter::Antialiasing);
+ bool was_antialiased = p.testRenderHint(QPainter::Antialiasing);
p.setRenderHint(QPainter::Antialiasing, false);
if (pos_vdivs_ > 0) {
}
}
- p.setRenderHint(QPainter::Antialiasing, wasAntialiased);
+ p.setRenderHint(QPainter::Antialiasing, was_antialiased);
}
void AnalogSignal::paint_trace(QPainter &p,
}
delete[] sample_block;
- p.drawPolyline(points, points_count);
+ // QPainter::drawPolyline() is slow, let's paint the lines ourselves
+ for (int64_t i = 1; i < points_count; i++)
+ p.drawLine(points[i - 1], points[i]);
if (show_sampling_points) {
if (paint_thr_dots) {
delete[] e.samples;
}
-void AnalogSignal::paint_logic_mid(QPainter &p, ViewItemPaintParams &pp)
-{
- QLineF *line;
-
- vector< pair<int64_t, bool> > edges;
-
- assert(base_);
-
- const int y = get_visual_y();
-
- if (!base_->enabled() || !base_->logic_data())
- return;
-
- const int signal_margin =
- QFontMetrics(QApplication::font()).height() / 2;
-
- const int ph = min(pos_vdivs_, 1) * div_height_;
- const int nh = min(neg_vdivs_, 1) * div_height_;
- const float high_offset = y - ph + signal_margin + 0.5f;
- const float low_offset = y + nh - signal_margin - 0.5f;
- const float signal_height = low_offset - high_offset;
-
- shared_ptr<pv::data::LogicSegment> segment = get_logic_segment_to_paint();
- if (!segment || (segment->get_sample_count() == 0))
- return;
-
- double samplerate = segment->samplerate();
-
- // Show sample rate as 1Hz when it is unknown
- if (samplerate == 0.0)
- samplerate = 1.0;
-
- const double pixels_offset = pp.pixels_offset();
- const pv::util::Timestamp& start_time = segment->start_time();
- const int64_t last_sample = (int64_t)segment->get_sample_count() - 1;
- const double samples_per_pixel = samplerate * pp.scale();
- const double pixels_per_sample = 1 / samples_per_pixel;
- const pv::util::Timestamp start = samplerate * (pp.offset() - start_time);
- const pv::util::Timestamp end = start + samples_per_pixel * pp.width();
-
- const int64_t start_sample = min(max(floor(start).convert_to<int64_t>(),
- (int64_t)0), last_sample);
- const uint64_t end_sample = min(max(ceil(end).convert_to<int64_t>(),
- (int64_t)0), last_sample);
-
- segment->get_subsampled_edges(edges, start_sample, end_sample,
- samples_per_pixel / LogicSignal::Oversampling, 0);
- assert(edges.size() >= 2);
-
- const float first_sample_x =
- pp.left() + (edges.front().first / samples_per_pixel - pixels_offset);
- const float last_sample_x =
- pp.left() + (edges.back().first / samples_per_pixel - pixels_offset);
-
- // Check whether we need to paint the sampling points
- const bool show_sampling_points = show_sampling_points_ && (samples_per_pixel < 0.25);
- vector<QRectF> sampling_points;
- float sampling_point_x = first_sample_x;
- int64_t sampling_point_sample = start_sample;
- const int w = 2;
-
- if (show_sampling_points)
- sampling_points.reserve(end_sample - start_sample + 1);
-
- vector<QRectF> high_rects;
- float rising_edge_x;
- bool rising_edge_seen = false;
-
- // Paint the edges
- const unsigned int edge_count = edges.size() - 2;
- QLineF *const edge_lines = new QLineF[edge_count];
- line = edge_lines;
-
- if (edges.front().second) {
- // Beginning of trace is high
- rising_edge_x = first_sample_x;
- rising_edge_seen = true;
- }
-
- for (auto i = edges.cbegin() + 1; i != edges.cend() - 1; i++) {
- // Note: multiple edges occupying a single pixel are represented by an edge
- // with undefined logic level. This means that only the first falling edge
- // after a rising edge corresponds to said rising edge - and vice versa. If
- // more edges with the same logic level follow, they denote multiple edges.
-
- const float x = pp.left() + ((*i).first / samples_per_pixel - pixels_offset);
- *line++ = QLineF(x, high_offset, x, low_offset);
-
- if (fill_high_areas_) {
- // Any edge terminates a high area
- if (rising_edge_seen) {
- const int width = x - rising_edge_x;
- if (width > 0)
- high_rects.emplace_back(rising_edge_x, high_offset,
- width, signal_height);
- rising_edge_seen = false;
- }
-
- // Only rising edges start high areas
- if ((*i).second) {
- rising_edge_x = x;
- rising_edge_seen = true;
- }
- }
-
- if (show_sampling_points)
- while (sampling_point_sample < (*i).first) {
- const float y = (*i).second ? low_offset : high_offset;
- sampling_points.emplace_back(
- QRectF(sampling_point_x - (w / 2), y - (w / 2), w, w));
- sampling_point_sample++;
- sampling_point_x += pixels_per_sample;
- };
- }
-
- // Calculate the sample points from the last edge to the end of the trace
- if (show_sampling_points)
- while ((uint64_t)sampling_point_sample <= end_sample) {
- // Signal changed after the last edge, so the level is inverted
- const float y = (edges.cend() - 1)->second ? high_offset : low_offset;
- sampling_points.emplace_back(
- QRectF(sampling_point_x - (w / 2), y - (w / 2), w, w));
- sampling_point_sample++;
- sampling_point_x += pixels_per_sample;
- };
-
- if (fill_high_areas_) {
- // Add last high rectangle if the signal is still high at the end of the trace
- if (rising_edge_seen && (edges.cend() - 1)->second)
- high_rects.emplace_back(rising_edge_x, high_offset,
- last_sample_x - rising_edge_x, signal_height);
-
- p.setPen(high_fill_color_);
- p.setBrush(high_fill_color_);
- p.drawRects((const QRectF*)(high_rects.data()), high_rects.size());
- }
-
- p.setPen(LogicSignal::EdgeColor);
- p.drawLines(edge_lines, edge_count);
- delete[] edge_lines;
-
- // Paint the caps
- const unsigned int max_cap_line_count = edges.size();
- QLineF *const cap_lines = new QLineF[max_cap_line_count];
-
- p.setPen(LogicSignal::HighColor);
- paint_logic_caps(p, cap_lines, edges, true, samples_per_pixel,
- pixels_offset, pp.left(), high_offset);
- p.setPen(LogicSignal::LowColor);
- paint_logic_caps(p, cap_lines, edges, false, samples_per_pixel,
- pixels_offset, pp.left(), low_offset);
-
- delete[] cap_lines;
-
- // Paint the sampling points
- if (show_sampling_points) {
- p.setPen(SamplingPointColor);
- p.drawRects(sampling_points.data(), sampling_points.size());
- }
-}
-
-void AnalogSignal::paint_logic_caps(QPainter &p, QLineF *const lines,
- vector< pair<int64_t, bool> > &edges, bool level,
- double samples_per_pixel, double pixels_offset, float x_offset,
- float y_offset)
-{
- QLineF *line = lines;
-
- for (auto i = edges.begin(); i != (edges.end() - 1); i++)
- if ((*i).second == level) {
- *line++ = QLineF(
- ((*i).first / samples_per_pixel -
- pixels_offset) + x_offset, y_offset,
- ((*(i+1)).first / samples_per_pixel -
- pixels_offset) + x_offset, y_offset);
- }
-
- p.drawLines(lines, line - lines);
-}
-
shared_ptr<pv::data::AnalogSegment> AnalogSignal::get_analog_segment_to_paint() const
{
shared_ptr<pv::data::AnalogSegment> segment;
segment = segments.back();
if ((segment_display_mode_ == ShowSingleSegmentOnly) ||
- (segment_display_mode_ == ShowLastCompleteSegmentOnly)) {
+ (segment_display_mode_ == ShowLastCompleteSegmentOnly)) {
try {
segment = segments.at(current_segment_);
} catch (out_of_range&) {
return segment;
}
-shared_ptr<pv::data::LogicSegment> AnalogSignal::get_logic_segment_to_paint() const
-{
- shared_ptr<pv::data::LogicSegment> segment;
-
- const deque< shared_ptr<pv::data::LogicSegment> > &segments =
- base_->logic_data()->logic_segments();
-
- if (!segments.empty()) {
- if (segment_display_mode_ == ShowLastSegmentOnly)
- segment = segments.back();
-
- if ((segment_display_mode_ == ShowSingleSegmentOnly) ||
- (segment_display_mode_ == ShowLastCompleteSegmentOnly)) {
- try {
- segment = segments.at(current_segment_);
- } catch (out_of_range&) {
- qDebug() << "Current logic segment out of range for signal" << base_->name() << ":" << current_segment_;
- }
- }
- }
-
- return segment;
-}
-
float AnalogSignal::get_resolution(int scale_index)
{
const float seq[] = {1.0f, 2.0f, 5.0f};
scale_ = div_height_ / resolution_;
}
+void AnalogSignal::update_logic_level_offsets()
+{
+ const int signal_margin = QFontMetrics(QApplication::font()).height() / 2;
+
+ const int ph = min(pos_vdivs_, 1) * div_height_;
+ const int nh = min(neg_vdivs_, 1) * div_height_;
+
+ high_level_offset_ = -ph + signal_margin + 0.5f;
+ low_level_offset_ = nh - signal_margin - 0.5f;
+}
+
void AnalogSignal::update_conversion_widgets()
{
SignalBase::ConversionType conv_type = base_->get_conversion_type();
if (segments.empty())
return;
- static double prev_min = 0, prev_max = 0;
double min = 0, max = 0;
for (const shared_ptr<pv::data::AnalogSegment>& segment : segments) {
max = std::max(max, mm.second);
}
- if ((min == prev_min) && (max == prev_max) && !force_update)
+ if ((min == signal_min_) && (max == signal_max_) && !force_update)
return;
- prev_min = min;
- prev_max = max;
+ signal_min_ = min;
+ signal_max_ = max;
// If we're allowed to alter the div assignment...
if (!keep_divs) {
}
}
+ const bool showing_logic = (display_type_ == DisplayConverted) || (display_type_ == DisplayBoth);
+
// If there is still no positive div when we need it, add one
// (this can happen when pos_vdivs==neg_vdivs==0)
- if ((max > 0) && (pos_vdivs_ == 0)) {
+ if (((max > 0) && (pos_vdivs_ == 0)) || showing_logic) {
pos_vdivs_ = 1;
owner_->extents_changed(false, true);
}
// If there is still no negative div when we need it, add one
// (this can happen when pos_vdivs was 0 or 1 when trying to split)
- if ((min < 0) && (neg_vdivs_ == 0)) {
+ if (((min < 0) && (neg_vdivs_ == 0)) || showing_logic) {
neg_vdivs_ = 1;
owner_->extents_changed(false, true);
}
// Add the standard options
Signal::populate_popup_form(parent, form);
- QFormLayout *const layout = new QFormLayout;
-
// Add div-related settings
pvdiv_sb_ = new QSpinBox(parent);
pvdiv_sb_->setRange(0, MaximumVDivs);
pvdiv_sb_->setValue(pos_vdivs_);
+ pvdiv_sb_->setEnabled(!autoranging_);
connect(pvdiv_sb_, SIGNAL(valueChanged(int)),
this, SLOT(on_pos_vdivs_changed(int)));
- layout->addRow(tr("Number of pos vertical divs"), pvdiv_sb_);
+ form->addRow(tr("Number of pos vertical divs"), pvdiv_sb_);
nvdiv_sb_ = new QSpinBox(parent);
nvdiv_sb_->setRange(0, MaximumVDivs);
nvdiv_sb_->setValue(neg_vdivs_);
+ nvdiv_sb_->setEnabled(!autoranging_);
connect(nvdiv_sb_, SIGNAL(valueChanged(int)),
this, SLOT(on_neg_vdivs_changed(int)));
- layout->addRow(tr("Number of neg vertical divs"), nvdiv_sb_);
+ form->addRow(tr("Number of neg vertical divs"), nvdiv_sb_);
div_height_sb_ = new QSpinBox(parent);
div_height_sb_->setRange(20, 1000);
div_height_sb_->setValue(div_height_);
connect(div_height_sb_, SIGNAL(valueChanged(int)),
this, SLOT(on_div_height_changed(int)));
- layout->addRow(tr("Div height"), div_height_sb_);
+ form->addRow(tr("Div height"), div_height_sb_);
// Add the vertical resolution
resolution_cb_ = new QComboBox(parent);
+ resolution_cb_->setEnabled(!autoranging_);
for (int i = MinScaleIndex; i < MaxScaleIndex; i++) {
const QString label = QString("%1").arg(get_resolution(i));
vdiv_layout->addWidget(resolution_cb_, 0, 0);
vdiv_layout->addWidget(vdiv_unit, 0, 1);
- layout->addRow(tr("Vertical resolution"), vdiv_layout);
+ form->addRow(tr("Vertical resolution"), vdiv_layout);
// Add the autoranging checkbox
QCheckBox* autoranging_cb = new QCheckBox();
connect(autoranging_cb, SIGNAL(stateChanged(int)),
this, SLOT(on_autoranging_changed(int)));
- layout->addRow(tr("Autoranging"), autoranging_cb);
+ form->addRow(tr("Autoranging"), autoranging_cb);
// Add the conversion type dropdown
conversion_cb_ = new QComboBox();
cur_idx = conversion_cb_->findData(QVariant(base_->get_conversion_type()));
conversion_cb_->setCurrentIndex(cur_idx);
- layout->addRow(tr("Conversion"), conversion_cb_);
+ form->addRow(tr("Conversion"), conversion_cb_);
connect(conversion_cb_, SIGNAL(currentIndexChanged(int)),
this, SLOT(on_conversion_changed(int)));
conv_threshold_cb_ = new QComboBox();
conv_threshold_cb_->setEditable(true);
- layout->addRow(tr("Conversion threshold(s)"), conv_threshold_cb_);
+ form->addRow(tr("Conversion threshold(s)"), conv_threshold_cb_);
connect(conv_threshold_cb_, SIGNAL(currentIndexChanged(int)),
this, SLOT(on_conv_threshold_changed(int)));
cur_idx = display_type_cb_->findData(QVariant(display_type_));
display_type_cb_->setCurrentIndex(cur_idx);
- layout->addRow(tr("Show traces for"), display_type_cb_);
+ form->addRow(tr("Show traces for"), display_type_cb_);
connect(display_type_cb_, SIGNAL(currentIndexChanged(int)),
this, SLOT(on_display_type_changed(int)));
// Update the conversion widget contents and states
update_conversion_widgets();
-
- form->addRow(layout);
}
void AnalogSignal::hover_point_changed(const QPoint &hp)
if (hp.x() <= 0) {
value_at_hover_pos_ = std::numeric_limits<float>::quiet_NaN();
} else {
- try {
+ if ((size_t)hp.x() < value_at_pixel_pos_.size())
value_at_hover_pos_ = value_at_pixel_pos_.at(hp.x());
- } catch (out_of_range&) {
+ else
value_at_hover_pos_ = std::numeric_limits<float>::quiet_NaN();
- }
}
}
void AnalogSignal::on_min_max_changed(float min, float max)
{
- (void)min;
- (void)max;
-
if (autoranging_)
perform_autoranging(false, false);
+ else {
+ if (min < signal_min_) signal_min_ = min;
+ if (max > signal_max_) signal_max_ = max;
+ }
}
void AnalogSignal::on_pos_vdivs_changed(int vdivs)
}
}
+ update_logic_level_offsets();
+
if (owner_) {
// Call order is important, otherwise the lazy event handler won't work
owner_->extents_changed(false, true);
}
}
+ update_logic_level_offsets();
+
if (owner_) {
// Call order is important, otherwise the lazy event handler won't work
owner_->extents_changed(false, true);
void AnalogSignal::on_div_height_changed(int height)
{
div_height_ = height;
+ update_logic_level_offsets();
update_scale();
if (owner_) {
{
autoranging_ = (state == Qt::Checked);
+ if (pvdiv_sb_)
+ pvdiv_sb_->setEnabled(!autoranging_);
+ if (nvdiv_sb_)
+ nvdiv_sb_->setEnabled(!autoranging_);
+ if (resolution_cb_)
+ resolution_cb_->setEnabled(!autoranging_);
+
if (autoranging_)
perform_autoranging(false, true);
base_->set_conversion_type(conv_type);
update_conversion_widgets();
+ if (conv_type == SignalBase::ConversionType::NoConversion)
+ on_display_type_changed(DisplayType::DisplayAnalog);
+ else
+ on_display_type_changed(DisplayType::DisplayBoth);
+
if (owner_)
owner_->row_item_appearance_changed(false, true);
}
void AnalogSignal::on_display_type_changed(int index)
{
+ const bool prev_showing_logic = (display_type_ == DisplayConverted) || (display_type_ == DisplayBoth);
+
display_type_ = (DisplayType)(display_type_cb_->itemData(index).toInt());
+ const bool showing_logic = (display_type_ == DisplayConverted) || (display_type_ == DisplayBoth);
+
+ // If we show a logic trace, make sure we have at least one div for each
+ // polarity as that's where we paint it
+ if (showing_logic && !prev_showing_logic) {
+ if (pos_vdivs_ == 0)
+ on_pos_vdivs_changed(1);
+ if (neg_vdivs_ == 0)
+ on_neg_vdivs_changed(1);
+ }
+
if (owner_)
owner_->row_item_appearance_changed(false, true);
}