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mirror of synced 2024-12-15 09:11:15 +01:00
ImHex/plugins/visualizers/source/content/pl_visualizers/digital_signal.cpp

101 lines
3.8 KiB
C++

#include <hex/helpers/utils.hpp>
#include <content/visualizer_helpers.hpp>
#include <implot.h>
#include <imgui.h>
#include <hex/helpers/logger.hpp>
#include <hex/ui/imgui_imhex_extensions.h>
#include <pl/patterns/pattern_bitfield.hpp>
namespace hex::plugin::visualizers {
void drawDigitalSignalVisualizer(pl::ptrn::Pattern &pattern, pl::ptrn::IIterable &iterable, bool shouldReset, std::span<const pl::core::Token::Literal>) {
auto *bitfield = dynamic_cast<pl::ptrn::PatternBitfield*>(&pattern);
if (bitfield == nullptr)
throw std::logic_error("Digital signal visualizer only works with bitfields.");
struct DataPoint {
std::array<ImVec2, 2> points;
std::string label;
std::string value;
ImColor color;
};
static std::vector<DataPoint> dataPoints;
static ImVec2 lastPoint;
if (shouldReset) {
dataPoints.clear();
lastPoint = { 0, 0 };
iterable.forEachEntry(0, iterable.getEntryCount(), [&](u64, pl::ptrn::Pattern *entry) {
size_t bitSize = 0;
if (auto bitfieldField = dynamic_cast<pl::ptrn::PatternBitfieldField*>(entry); bitfieldField != nullptr)
bitSize = bitfieldField->getBitSize();
else
bitSize = entry->getSize() * 8;
auto value = entry->getValue();
bool high = value.toUnsigned() > 0;
dataPoints.emplace_back(
std::array<ImVec2, 2> { lastPoint, { lastPoint.x, high ? 1.0F : 0.0F } },
entry->getDisplayName(),
entry->getFormattedValue(),
entry->getColor()
);
lastPoint = dataPoints.back().points[1];
lastPoint.x += bitSize;
});
dataPoints.push_back({
.points = { lastPoint, { lastPoint.x, 0 } },
.label = "",
.value = "",
.color = ImColor(0x00)
});
}
if (ImPlot::BeginPlot("##Signal", ImVec2(600_scaled, 200_scaled), ImPlotFlags_NoLegend | ImPlotFlags_NoFrame | ImPlotFlags_NoMenus | ImPlotFlags_NoMouseText)) {
ImPlot::SetupAxisLimitsConstraints(ImAxis_X1, 0, lastPoint.x);
ImPlot::SetupAxis(ImAxis_Y1, "", ImPlotAxisFlags_LockMin | ImPlotAxisFlags_LockMax);
ImPlot::SetupAxisFormat(ImAxis_Y1, "");
ImPlot::SetupAxisLimits(ImAxis_Y1, -0.1F, 1.1F);
for (size_t i = 0; i < dataPoints.size() - 1; i += 1) {
const auto &left = dataPoints[i];
const auto &right = dataPoints[i + 1];
{
auto x = left.points[1].x + (right.points[0].x - left.points[1].x) / 2;
ImPlot::Annotation(x, 0.55F, left.color, {}, false, "%s", left.label.c_str());
ImPlot::Annotation(x, 0.40F, left.color, {}, false, "%s", left.value.c_str());
}
{
ImVec2 min = ImPlot::PlotToPixels(ImPlotPoint(left.points[0].x, 0));
ImVec2 max = ImPlot::PlotToPixels(ImPlotPoint(right.points[1].x, 1));
ImPlot::PushPlotClipRect();
auto transparentColor = left.color;
transparentColor.Value.w = 0.4F;
ImPlot::GetPlotDrawList()->AddRectFilled(min, max, transparentColor);
ImPlot::PopPlotClipRect();
}
}
ImPlot::PushStyleVar(ImPlotStyleVar_LineWeight, 2_scaled);
ImPlot::PlotLineG("Signal", [](int idx, void*) -> ImPlotPoint {
return dataPoints[idx / 2].points[idx % 2];
}, nullptr, dataPoints.size() * 2);
ImPlot::PopStyleVar();
ImPlot::EndPlot();
}
}
}