using pv::data::SignalData;
using pv::data::Segment;
using pv::util::format_time;
+using pv::util::TimeUnit;
+using pv::util::Timestamp;
using std::deque;
using std::dynamic_pointer_cast;
namespace pv {
namespace view {
-const double View::MaxScale = 1e9;
-const double View::MinScale = 1e-15;
+const Timestamp View::MaxScale("1e9");
+const Timestamp View::MinScale("1e-12");
const int View::MaxScrollValue = INT_MAX / 2;
+const int View::MaxViewAutoUpdateRate = 25; // No more than 25 Hz with sticky scrolling
const int View::ScaleUnits[3] = {1, 2, 5};
scale_(1e-3),
offset_(0),
updating_scroll_(false),
+ sticky_scrolling_(false), // Default setting is set in MainWindow::setup_ui()
+ always_zoom_to_fit_(false),
tick_period_(0.0),
tick_prefix_(0),
+ tick_precision_(0),
+ time_unit_(util::Time),
show_cursors_(false),
cursors_(new CursorPair(*this)),
next_flag_text_('A'),
connect(&session_, SIGNAL(signals_changed()),
this, SLOT(signals_changed()));
connect(&session_, SIGNAL(capture_state_changed(int)),
- this, SLOT(data_updated()));
+ this, SLOT(capture_state_updated(int)));
connect(&session_, SIGNAL(data_received()),
this, SLOT(data_updated()));
connect(&session_, SIGNAL(frame_ended()),
this, SLOT(process_sticky_events()));
lazy_event_handler_.setSingleShot(true);
+ connect(&delayed_view_updater_, SIGNAL(timeout()),
+ this, SLOT(perform_delayed_view_update()));
+ delayed_view_updater_.setSingleShot(true);
+ delayed_view_updater_.setInterval(1000 / MaxViewAutoUpdateRate);
+
setViewport(viewport_);
viewport_->installEventFilter(this);
return scale_;
}
-double View::offset() const
+const Timestamp& View::offset() const
{
return offset_;
}
return tick_prefix_;
}
+unsigned int View::tick_precision() const
+{
+ return tick_precision_;
+}
+
double View::tick_period() const
{
return tick_period_;
}
+TimeUnit View::time_unit() const
+{
+ return time_unit_;
+}
+
void View::zoom(double steps)
{
zoom(steps, viewport_->width() / 2);
set_zoom(scale_ * pow(3.0/2.0, -steps), offset);
}
-void View::zoom_fit()
+void View::zoom_fit(bool gui_state)
{
- const pair<double, double> extents = get_time_extents();
- const double delta = extents.second - extents.first;
- if (delta < 1e-12)
+ // Act as one-shot when stopped, toggle along with the GUI otherwise
+ if (session_.get_capture_state() == Session::Stopped) {
+ always_zoom_to_fit_ = false;
+ always_zoom_to_fit_changed(false);
+ } else {
+ always_zoom_to_fit_ = gui_state;
+ always_zoom_to_fit_changed(gui_state);
+ }
+
+ const pair<Timestamp, Timestamp> extents = get_time_extents();
+ const Timestamp delta = extents.second - extents.first;
+ if (delta < Timestamp("1e-12"))
return;
assert(viewport_);
if (w <= 0)
return;
- const double scale = max(min(delta / w, MaxScale), MinScale);
- set_scale_offset(scale, extents.first);
+ const Timestamp scale = max(min(delta / w, MaxScale), MinScale);
+ set_scale_offset(scale.convert_to<double>(), extents.first);
}
void View::zoom_one_to_one()
set_zoom(1.0 / samplerate, w / 2);
}
-void View::set_scale_offset(double scale, double offset)
+void View::set_scale_offset(double scale, const Timestamp& offset)
{
+ // Disable sticky scrolling / always zoom to fit when acquisition runs
+ // and user drags the viewport
+ if ((scale_ == scale) && (offset_ != offset) &&
+ (session_.get_capture_state() == Session::Running)) {
+
+ if (sticky_scrolling_) {
+ sticky_scrolling_ = false;
+ sticky_scrolling_changed(false);
+ }
+
+ if (always_zoom_to_fit_) {
+ always_zoom_to_fit_ = false;
+ always_zoom_to_fit_changed(false);
+ }
+ }
+
scale_ = scale;
offset_ = offset;
return visible_data;
}
-pair<double, double> View::get_time_extents() const
+pair<Timestamp, Timestamp> View::get_time_extents() const
{
- double left_time = DBL_MAX, right_time = DBL_MIN;
+ boost::optional<Timestamp> left_time, right_time;
const set< shared_ptr<SignalData> > visible_data = get_visible_data();
for (const shared_ptr<SignalData> d : visible_data)
{
double samplerate = s->samplerate();
samplerate = (samplerate <= 0.0) ? 1.0 : samplerate;
- const double start_time = s->start_time();
- left_time = min(left_time, start_time);
- right_time = max(right_time, start_time +
- d->max_sample_count() / samplerate);
+ const Timestamp start_time = s->start_time();
+ left_time = left_time ?
+ min(*left_time, start_time) :
+ start_time;
+ right_time = right_time ?
+ max(*right_time, start_time + d->max_sample_count() / samplerate) :
+ start_time + d->max_sample_count() / samplerate;
}
}
- if (left_time == DBL_MAX && right_time == DBL_MIN)
- return make_pair(0.0, 0.0);
+ if (!left_time || !right_time)
+ return make_pair(0, 0);
- assert(left_time < right_time);
- return make_pair(left_time, right_time);
+ assert(*left_time < *right_time);
+ return make_pair(*left_time, *right_time);
+}
+
+void View::enable_sticky_scrolling(bool state)
+{
+ sticky_scrolling_ = state;
}
bool View::cursors_shown() const
return cursors_;
}
-void View::add_flag(double time)
+void View::add_flag(const Timestamp& time)
{
flags_.push_back(shared_ptr<Flag>(new Flag(*this, time,
QString("%1").arg(next_flag_text_))));
r->animate_to_layout_v_offset();
}
-void View::get_scroll_layout(double &length, double &offset) const
+void View::get_scroll_layout(double &length, Timestamp &offset) const
{
- const pair<double, double> extents = get_time_extents();
- length = (extents.second - extents.first) / scale_;
+ const pair<Timestamp, Timestamp> extents = get_time_extents();
+ length = ((extents.second - extents.first) / scale_).convert_to<double>();
offset = offset_ / scale_;
}
void View::set_zoom(double scale, int offset)
{
- const double cursor_offset = offset_ + scale_ * offset;
- const double new_scale = max(min(scale, MaxScale), MinScale);
- const double new_offset = cursor_offset - new_scale * offset;
- set_scale_offset(new_scale, new_offset);
+ // Reset the "always zoom to fit" feature as the user changed the zoom
+ always_zoom_to_fit_ = false;
+ always_zoom_to_fit_changed(false);
+
+ const Timestamp cursor_offset = offset_ + scale_ * offset;
+ const Timestamp new_scale = max(min(Timestamp(scale), MaxScale), MinScale);
+ const Timestamp new_offset = cursor_offset - new_scale * offset;
+ set_scale_offset(new_scale.convert_to<double>(), new_offset);
}
void View::calculate_tick_spacing()
{
- const double SpacingIncrement = 32.0f;
- const double MinValueSpacing = 32.0f;
+ const double SpacingIncrement = 10.0f;
+ const double MinValueSpacing = 40.0f;
+
+ // Figure out the highest numeric value visible on a label
+ const QSize areaSize = viewport_->size();
+ const Timestamp max_time = max(fabs(offset_),
+ fabs(offset_ + scale_ * areaSize.width()));
- double min_width = SpacingIncrement, typical_width;
+ double min_width = SpacingIncrement;
+ double label_width, tick_period_width;
QFontMetrics m(QApplication::font());
const int order = (int)floorf(log10f(min_period));
const double order_decimal = pow(10.0, order);
+ // Allow for a margin of error so that a scale unit of 1 can be used.
+ // Otherwise, for a SU of 1 the tick period will almost always be below
+ // the min_period by a small amount - and thus skipped in favor of 2.
+ // Note: margin assumes that SU[0] and SU[1] contain the smallest values
+ double tp_margin = (ScaleUnits[0] + ScaleUnits[1]) / 2.0;
+ double tp_with_margin;
unsigned int unit = 0;
do {
- tick_period_ = order_decimal * ScaleUnits[unit++];
- } while (tick_period_ < min_period &&
- unit < countof(ScaleUnits));
+ tp_with_margin = order_decimal * (ScaleUnits[unit++] + tp_margin);
+ } while (tp_with_margin < min_period && unit < countof(ScaleUnits));
+ tick_period_ = order_decimal * ScaleUnits[unit - 1];
tick_prefix_ = (order - pv::util::FirstSIPrefixPower) / 3;
- typical_width = m.boundingRect(0, 0, INT_MAX, INT_MAX,
- Qt::AlignLeft | Qt::AlignTop,
- format_time(offset_, tick_prefix_)).width() +
+ // Precision is the number of fractional digits required, not
+ // taking the prefix into account (and it must never be negative)
+ tick_precision_ = std::max((int)ceil(log10f(1 / tick_period_)), 0);
+
+ tick_period_width = tick_period_ / scale_;
+
+ const QString label_text =
+ format_time(max_time, tick_prefix_, time_unit_, tick_precision_);
+
+ label_width = m.boundingRect(0, 0, INT_MAX, INT_MAX,
+ Qt::AlignLeft | Qt::AlignTop, label_text).width() +
MinValueSpacing;
min_width += SpacingIncrement;
- } while(typical_width > tick_period_ / scale_);
+ } while (tick_period_width < label_width);
}
void View::update_scroll()
const QSize areaSize = viewport_->size();
// Set the horizontal scroll bar
- double length = 0, offset = 0;
+ double length = 0;
+ Timestamp offset;
get_scroll_layout(length, offset);
length = max(length - areaSize.width(), 0.0);
if (length < MaxScrollValue) {
horizontalScrollBar()->setRange(0, length);
- horizontalScrollBar()->setSliderPosition(offset);
+ horizontalScrollBar()->setSliderPosition(offset.convert_to<double>());
} else {
horizontalScrollBar()->setRange(0, MaxScrollValue);
horizontalScrollBar()->setSliderPosition(
- offset_ * MaxScrollValue / (scale_ * length));
+ (offset_ * MaxScrollValue / (scale_ * length)).convert_to<double>());
}
updating_scroll_ = false;
return filtered_traces;
}
+void View::determine_time_unit()
+{
+ // Check whether we know the sample rate and hence can use time as the unit
+ if (time_unit_ == util::Samples) {
+ shared_lock<shared_mutex> lock(session().signals_mutex());
+ const unordered_set< shared_ptr<Signal> > &sigs(session().signals());
+
+ // Check all signals but...
+ for (const shared_ptr<Signal> signal : sigs) {
+ const shared_ptr<SignalData> data = signal->data();
+
+ // ...only check first segment of each
+ const vector< shared_ptr<Segment> > segments = data->segments();
+ if (!segments.empty())
+ if (segments[0]->samplerate()) {
+ time_unit_ = util::Time;
+ break;
+ }
+ }
+ }
+}
+
bool View::eventFilter(QObject *object, QEvent *event)
{
const QEvent::Type type = event->type();
if (updating_scroll_)
return;
+ // Disable sticky scrolling when user moves the horizontal scroll bar
+ // during a running acquisition
+ if (sticky_scrolling_ && (session_.get_capture_state() == Session::Running)) {
+ sticky_scrolling_ = false;
+ sticky_scrolling_changed(false);
+ }
+
const int range = horizontalScrollBar()->maximum();
if (range < MaxScrollValue)
offset_ = scale_ * value;
else {
- double length = 0, offset;
+ double length = 0;
+ Timestamp offset;
get_scroll_layout(length, offset);
offset_ = scale_ * length * value / MaxScrollValue;
}
viewport_->update();
}
+void View::capture_state_updated(int state)
+{
+ if (state == Session::Running)
+ time_unit_ = util::Samples;
+
+ if (state == Session::Stopped) {
+ // After acquisition has stopped we need to re-calculate the ticks once
+ // as it's otherwise done when the user pans or zooms, which is too late
+ calculate_tick_spacing();
+
+ // Reset "always zoom to fit", the acquisition has stopped
+ if (always_zoom_to_fit_) {
+ always_zoom_to_fit_ = false;
+ always_zoom_to_fit_changed(false);
+ }
+ }
+}
+
void View::data_updated()
{
- // Update the scroll bars
- update_scroll();
+ if (always_zoom_to_fit_ || sticky_scrolling_) {
+ if (!delayed_view_updater_.isActive())
+ delayed_view_updater_.start();
+ } else {
+ determine_time_unit();
+ update_scroll();
+ ruler_->update();
+ viewport_->update();
+ }
+}
+
+void View::perform_delayed_view_update()
+{
+ if (always_zoom_to_fit_)
+ zoom_fit(true);
- // Repaint the view
+ if (sticky_scrolling_) {
+ // Make right side of the view sticky
+ double length = 0;
+ Timestamp offset;
+ get_scroll_layout(length, offset);
+
+ const QSize areaSize = viewport_->size();
+ length = max(length - areaSize.width(), 0.0);
+
+ offset_ = scale_ * length;
+ }
+
+ determine_time_unit();
+ update_scroll();
+ ruler_->update();
viewport_->update();
}