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f742710758
Summary: * `NULL` -> `nullptr` * `gui` -> Function `getGUI()` * `pluginFactory` -> Function `getPluginFactory()` * `assert` (redefinition) -> using `NDEBUG` instead, which standard `assert` respects. * `powf` (C stdlib symbol clash) -> removed and all expansions replaced with calls to `std::pow`. * `exp10` (nonstandard function symbol clash) -> removed and all expansions replaced with calls to `std::pow`. * `PATH_DEV_DSP` -> File-scope QString of identical name and value. * `VST_SNC_SHM_KEY_FILE` -> constexpr char* with identical name and value. * `MM_ALLOC` and `MM_FREE` -> Functions with identical name and implementation. * `INVAL`, `OUTVAL`, etc. for automation nodes -> Functions with identical names and implementations. * BandLimitedWave.h: All integer constant macros replaced with constexpr ints of same name and value. * `FAST_RAND_MAX` -> constexpr int of same name and value. * `QSTR_TO_STDSTR` -> Function with identical name and equivalent implementation. * `CCONST` -> constexpr function template with identical name and implementation. * `F_OPEN_UTF8` -> Function with identical name and equivalent implementation. * `LADSPA_PATH_SEPARATOR` -> constexpr char with identical name and value. * `UI_CTRL_KEY` -> constexpr char* with identical name and value. * `ALIGN_SIZE` -> Renamed to `LMMS_ALIGN_SIZE` and converted from a macro to a constexpr size_t. * `JACK_MIDI_BUFFER_MAX` -> constexpr size_t with identical name and value. * versioninfo.h: `PLATFORM`, `MACHINE` and `COMPILER_VERSION` -> prefixed with `LMMS_BUILDCONF_` and converted from macros to constexpr char* literals. * Header guard _OSCILLOSCOPE -> renamed to OSCILLOSCOPE_H * Header guard _TIME_DISPLAY_WIDGET -> renamed to TIME_DISPLAY_WIDGET_H * C-style typecasts in DrumSynth.cpp have been replaced with `static_cast`. * constexpr numerical constants are initialized with assignment notation instead of curly brace intializers. * In portsmf, `Alg_seq::operator[]` will throw an exception instead of returning null if the operator index is out of range. Additionally, in many places, global constants that were declared as `const T foo = bar;` were changed from const to constexpr, leaving them const and making them potentially evaluable at compile time. Some macros that only appeared in single source files and were unused in those files have been removed entirely.
329 lines
13 KiB
C++
329 lines
13 KiB
C++
/* VectorView.cpp - implementation of VectorView class.
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*
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* Copyright (c) 2019 Martin Pavelek <he29/dot/HS/at/gmail/dot/com>
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*
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* This file is part of LMMS - https://lmms.io
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public
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* License as published by the Free Software Foundation; either
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* version 2 of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* General Public License for more details.
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*
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* You should have received a copy of the GNU General Public
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* License along with this program (see COPYING); if not, write to the
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* Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
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* Boston, MA 02110-1301 USA.
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*
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*/
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#include "VectorView.h"
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#include <algorithm>
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#include <chrono>
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#include <cmath>
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#include <QImage>
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#include <QPainter>
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#include "ColorChooser.h"
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#include "GuiApplication.h"
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#include "MainWindow.h"
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VectorView::VectorView(VecControls *controls, LocklessRingBuffer<sampleFrame> *inputBuffer, unsigned short displaySize, QWidget *parent) :
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QWidget(parent),
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m_controls(controls),
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m_inputBuffer(inputBuffer),
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m_bufferReader(*inputBuffer),
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m_displaySize(displaySize),
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m_zoom(1.f),
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m_persistTimestamp(0),
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m_zoomTimestamp(0),
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m_oldHQ(m_controls->m_highQualityModel.value()),
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m_oldX(m_displaySize / 2),
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m_oldY(m_displaySize / 2)
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{
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setMinimumSize(200, 200);
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setSizePolicy(QSizePolicy::Expanding, QSizePolicy::Expanding);
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connect(getGUI()->mainWindow(), SIGNAL(periodicUpdate()), this, SLOT(periodicUpdate()));
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m_displayBuffer.resize(sizeof qRgb(0,0,0) * m_displaySize * m_displaySize, 0);
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#ifdef VEC_DEBUG
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m_executionAvg = 0;
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#endif
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}
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// Compose and draw all the content; called by Qt.
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void VectorView::paintEvent(QPaintEvent *event)
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{
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#ifdef VEC_DEBUG
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unsigned int drawTime = std::chrono::high_resolution_clock::now().time_since_epoch().count();
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#endif
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// All drawing done in this method, local variables are sufficient for the boundary
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const int displayTop = 2;
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const int displayBottom = height() - 2;
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const int displayLeft = 2;
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const int displayRight = width() - 2;
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const int displayWidth = displayRight - displayLeft;
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const int displayHeight = displayBottom - displayTop;
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const float centerX = displayLeft + (displayWidth / 2.f);
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const float centerY = displayTop + (displayWidth / 2.f);
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const int margin = 4;
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const int gridCorner = 30;
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// Setup QPainter and font sizes
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QPainter painter(this);
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painter.setRenderHint(QPainter::Antialiasing, true);
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QFont normalFont, boldFont;
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boldFont.setPixelSize(26);
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boldFont.setBold(true);
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const int labelWidth = 26;
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const int labelHeight = 26;
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bool hq = m_controls->m_highQualityModel.value();
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// Clear display buffer if quality setting was changed
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if (hq != m_oldHQ)
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{
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m_oldHQ = hq;
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for (std::size_t i = 0; i < m_displayBuffer.size(); i++)
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{
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m_displayBuffer.data()[i] = 0;
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}
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}
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// Dim stored image based on persistence setting and elapsed time.
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// Update period is limited to 50 ms (20 FPS) for non-HQ mode and 10 ms (100 FPS) for HQ mode.
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const unsigned int currentTimestamp = std::chrono::duration_cast<std::chrono::milliseconds>
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(
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std::chrono::high_resolution_clock::now().time_since_epoch()
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).count();
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const unsigned int elapsed = currentTimestamp - m_persistTimestamp;
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const unsigned int threshold = hq ? 10 : 50;
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if (elapsed > threshold)
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{
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m_persistTimestamp = currentTimestamp;
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// Non-HQ mode uses half the resolution → use limited buffer space.
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const std::size_t useableBuffer = hq ? m_displayBuffer.size() : m_displayBuffer.size() / 4;
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// The knob value is interpreted on log. scale, otherwise the effect would ramp up too slowly.
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// Persistence value specifies fraction of light intensity that remains after 10 ms.
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// → Compensate it based on elapsed time (exponential decay).
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const float persist = log10(1 + 9 * m_controls->m_persistenceModel.value());
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const float persistPerFrame = pow(persist, elapsed / 10.f);
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// Note that for simplicity and performance reasons, this implementation only dims all stored
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// values by a given factor. A true simulation would also do the inverse of desaturation that
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// occurs in high-intensity traces in HQ mode.
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for (std::size_t i = 0; i < useableBuffer; i++)
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{
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m_displayBuffer.data()[i] *= persistPerFrame;
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}
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}
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// Get new samples from the lockless input FIFO buffer
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auto inBuffer = m_bufferReader.read_max(m_inputBuffer->capacity());
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std::size_t frameCount = inBuffer.size();
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// Draw new points on top
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float left, right;
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int x, y;
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const bool logScale = m_controls->m_logarithmicModel.value();
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const unsigned short activeSize = hq ? m_displaySize : m_displaySize / 2;
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// Helper lambda functions for better readability
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// Make sure pixel stays within display bounds:
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auto saturate = [=](short pixelPos) {return qBound((short)0, pixelPos, (short)(activeSize - 1));};
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// Take existing pixel and brigthen it. Very bright light should reduce saturation and become
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// white. This effect is easily approximated by capping elementary colors to 255 individually.
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auto updatePixel = [&](unsigned short x, unsigned short y, QColor addedColor)
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{
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QColor currentColor = ((QRgb*)m_displayBuffer.data())[x + y * activeSize];
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currentColor.setRed(std::min(currentColor.red() + addedColor.red(), 255));
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currentColor.setGreen(std::min(currentColor.green() + addedColor.green(), 255));
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currentColor.setBlue(std::min(currentColor.blue() + addedColor.blue(), 255));
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((QRgb*)m_displayBuffer.data())[x + y * activeSize] = currentColor.rgb();
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};
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if (hq)
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{
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// High quality mode: check distance between points and draw a line.
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// The longer the line is, the dimmer, simulating real electron trace on luminescent screen.
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for (std::size_t frame = 0; frame < frameCount; frame++)
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{
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float inLeft = inBuffer[frame][0] * m_zoom;
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float inRight = inBuffer[frame][1] * m_zoom;
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// Scale left and right channel from (-1.0, 1.0) to display range
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if (logScale)
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{
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// To better preserve shapes, the log scale is applied to the distance from origin,
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// not the individual channels.
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const float distance = sqrt(inLeft * inLeft + inRight * inRight);
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const float distanceLog = log10(1 + 9 * std::abs(distance));
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const float angleCos = inLeft / distance;
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const float angleSin = inRight / distance;
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left = distanceLog * angleCos * (activeSize - 1) / 4;
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right = distanceLog * angleSin * (activeSize - 1) / 4;
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}
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else
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{
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left = inLeft * (activeSize - 1) / 4;
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right = inRight * (activeSize - 1) / 4;
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}
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// Rotate display coordinates 45 degrees, flip Y axis and make sure the result stays within bounds
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x = saturate(right - left + activeSize / 2.f);
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y = saturate(activeSize - (right + left + activeSize / 2.f));
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// Estimate number of points needed to fill space between the old and new pixel. Cap at 100.
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unsigned char points = std::min((int)sqrt((m_oldX - x) * (m_oldX - x) + (m_oldY - y) * (m_oldY - y)), 100);
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// Large distance = dim trace. The curve for darker() is choosen so that:
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// - no movement (0 points) actually _increases_ brightness slightly,
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// - one point between samples = returns exactly the specified color,
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// - one to 99 points between samples = follows a sharp "1/x" decaying curve,
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// - 100 points between samples = returns approximately 5 % brightness.
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// Everything else is discarded (by the 100 point cap) because there is not much to see anyway.
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QColor addedColor = m_controls->m_colorFG.darker(75 + 20 * points).rgb();
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// Draw the new pixel: the beam sweeps across area that may have been excited before
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// → add new value to existing pixel state.
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updatePixel(x, y, addedColor);
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// Draw interpolated points between the old pixel and the new one
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int newX = right - left + activeSize / 2.f;
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int newY = activeSize - (right + left + activeSize / 2.f);
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for (unsigned char i = 1; i < points; i++)
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{
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x = saturate(((points - i) * m_oldX + i * newX) / points);
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y = saturate(((points - i) * m_oldY + i * newY) / points);
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updatePixel(x, y, addedColor);
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}
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m_oldX = newX;
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m_oldY = newY;
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}
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}
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else
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{
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// To improve performance, non-HQ mode uses smaller display size and only
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// one full-color pixel per sample.
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for (std::size_t frame = 0; frame < frameCount; frame++)
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{
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float inLeft = inBuffer[frame][0] * m_zoom;
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float inRight = inBuffer[frame][1] * m_zoom;
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if (logScale) {
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const float distance = sqrt(inLeft * inLeft + inRight * inRight);
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const float distanceLog = log10(1 + 9 * std::abs(distance));
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const float angleCos = inLeft / distance;
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const float angleSin = inRight / distance;
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left = distanceLog * angleCos * (activeSize - 1) / 4;
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right = distanceLog * angleSin * (activeSize - 1) / 4;
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} else {
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left = inLeft * (activeSize - 1) / 4;
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right = inRight * (activeSize - 1) / 4;
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}
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x = saturate(right - left + activeSize / 2.f);
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y = saturate(activeSize - (right + left + activeSize / 2.f));
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((QRgb*)m_displayBuffer.data())[x + y * activeSize] = m_controls->m_colorFG.rgb();
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}
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}
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// Draw background
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painter.fillRect(displayLeft, displayTop, displayWidth, displayHeight, QColor(0,0,0));
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// Draw the final image
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QImage temp = QImage(m_displayBuffer.data(),
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activeSize,
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activeSize,
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QImage::Format_RGB32);
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temp.setDevicePixelRatio(devicePixelRatio());
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painter.drawImage(displayLeft, displayTop,
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temp.scaledToWidth(displayWidth * devicePixelRatio(),
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Qt::SmoothTransformation));
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// Draw the grid and labels
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painter.setPen(QPen(m_controls->m_colorGrid, 1.5, Qt::SolidLine, Qt::RoundCap, Qt::BevelJoin));
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painter.drawEllipse(QPointF(centerX, centerY), displayWidth / 2.f, displayWidth / 2.f);
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painter.setPen(QPen(m_controls->m_colorGrid, 1.5, Qt::DotLine, Qt::RoundCap, Qt::BevelJoin));
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painter.drawLine(QPointF(centerX, centerY), QPointF(displayLeft + gridCorner, displayTop + gridCorner));
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painter.drawLine(QPointF(centerX, centerY), QPointF(displayRight - gridCorner, displayTop + gridCorner));
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painter.setPen(QPen(m_controls->m_colorLabels, 1, Qt::SolidLine, Qt::RoundCap, Qt::BevelJoin));
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painter.setFont(boldFont);
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painter.drawText(displayLeft + margin, displayTop,
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labelWidth, labelHeight, Qt::AlignLeft | Qt::AlignTop | Qt::TextDontClip,
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QString("L"));
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painter.drawText(displayRight - margin - labelWidth, displayTop,
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labelWidth, labelHeight, Qt::AlignRight| Qt::AlignTop | Qt::TextDontClip,
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QString("R"));
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// Draw the outline
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painter.setPen(QPen(m_controls->m_colorOutline, 2, Qt::SolidLine, Qt::RoundCap, Qt::BevelJoin));
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painter.drawRoundedRect(1, 1, width() - 2, height() - 2, 2.f, 2.f);
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// Draw zoom info if changed within last second (re-using timestamp acquired for dimming)
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if (currentTimestamp - m_zoomTimestamp < 1000)
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{
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painter.setPen(QPen(m_controls->m_colorLabels, 1, Qt::SolidLine, Qt::RoundCap, Qt::BevelJoin));
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painter.setFont(normalFont);
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painter.drawText(displayWidth / 2 - 50, displayBottom - 20, 100, 16, Qt::AlignCenter,
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QString("Zoom: ").append(std::to_string((int)round(m_zoom * 100)).c_str()).append(" %"));
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}
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// Optionally measure drawing performance
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#ifdef VEC_DEBUG
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drawTime = std::chrono::high_resolution_clock::now().time_since_epoch().count() - drawTime;
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m_executionAvg = 0.95f * m_executionAvg + 0.05f * drawTime / 1000000.f;
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painter.setPen(QPen(m_controls->m_colorLabels, 1, Qt::SolidLine, Qt::RoundCap, Qt::BevelJoin));
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painter.setFont(normalFont);
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painter.drawText(displayWidth / 2 - 50, displayBottom - 16, 100, 16, Qt::AlignLeft,
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QString("Exec avg.: ").append(std::to_string(m_executionAvg).substr(0, 5).c_str()).append(" ms"));
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#endif
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}
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// Periodically trigger repaint and check if the widget is visible
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void VectorView::periodicUpdate()
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{
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m_visible = isVisible();
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if (m_visible) {update();}
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}
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// Allow to change color on double-click.
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// More of an Easter egg, to avoid cluttering the interface with non-essential functionality.
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void VectorView::mouseDoubleClickEvent(QMouseEvent *event)
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{
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ColorChooser *colorDialog = new ColorChooser(m_controls->m_colorFG, this);
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if (colorDialog->exec())
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{
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m_controls->m_colorFG = colorDialog->currentColor();
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}
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}
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// Change zoom level using the mouse wheel
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void VectorView::wheelEvent(QWheelEvent *event)
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{
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// Go through integers to avoid accumulating errors
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const unsigned short old_zoom = round(100 * m_zoom);
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// Min-max bounds are 20 and 1000 %, step for 15°-increment mouse wheel is 20 %
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const unsigned short new_zoom = qBound(20, old_zoom + event->angleDelta().y() / 6, 1000);
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m_zoom = new_zoom / 100.f;
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event->accept();
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m_zoomTimestamp = std::chrono::duration_cast<std::chrono::milliseconds>
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(
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std::chrono::high_resolution_clock::now().time_since_epoch()
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).count();
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}
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