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90ec5b8246
fractorium/Source/Fractorium/FractoriumParams.cpp
Person 90ec5b8246 --User changes: 
-Show common folder locations such as documents, downloads, pictures in the sidebar in all file dialogs.
 -Warning message about exceeding memory in final render dialog now suggests strips as the solution to the problem.
 -Strips now has a tooltip explaining what it does.
 -Allow more digits in the spinners on the color section the flame tab.
 -Add manually adjustable size spinners in the final render dialog. Percentage scale and absolute size are fully synced.
 -Default prefix in final render is now the filename when doing animations (coming from sequence section of the library tab).
 -Changed the elliptic variation back to using a less precise version for float, and a more precise version for double. The last release had it always using double.
 -New applied xaos table that shows a read-only view of actual weights by taking the base xform weights and multiplying them by the xaos values.
 -New table in the xaos tab that gives a graphical representation of the probability that each xform is chosen, with and without xaos.
 -Add button to transpose the xaos rows and columns.
 -Add support for importing .chaos files from Chaotica.
 --Pasting back to Chaotica will work for most, but not all, variations due to incompatible parameter names in some.
 -Curves are now splines instead of Bezier. This adds compatibility with Chaotica, but breaks it for Apophysis. Xmls are still pastable, but the color curves will look different.
 --The curve editor on the palette tab can now add points by clicking on the lines and remove points by clicking on the points themselves, just like Chaotica.
 --Splines are saved in four new xml fields: overall_curve, red_curve, green_curve and blue_curve.
 -Allow for specifying the percentage of a sub batch each thread should iterate through per kernel call when running with OpenCL. This gives a roughly 1% performance increase due to having to make less kernel calls while iterating.
 --This field is present for interactive editing (where it's not very useful) and in the final render dialog.
 --On the command line, this is specified as --sbpctth for EmberRender and EmberAnimate.
 -Allow double clicking to toggle the supersample field in the flame tab between 1 and 2 for easily checking the effect of the field.
 -When showing affine values as polar coordinates, show angles normalized to 360 to match Chaotica.
 -Fuse Count spinner now toggles between 15 and 100 when double clicking for easily checking the effect of the field.
 -Added field for limiting the range in the x and y direction that the initial points are chosen from.
 -Added a field called K2 which is an alternative way to set brightness, ignored when zero.
 --This has no effect for many variations, but hs a noticeable effect for some.
 -Added new variations:
 arcsech
 arcsech2
 arcsinh
 arctanh
 asteria
 block
 bwraps_rand
 circlecrop2
 coth_spiral
 crackle2
 depth_blur
 depth_blur2
 depth_gaussian
 depth_gaussian2
 depth_ngon
 depth_ngon2
 depth_sine
 depth_sine2
 dragonfire
 dspherical
 dust
 excinis
 exp2
 flipx
 flowerdb
 foci_p
 gaussian
 glynnia2
 glynnsim4
 glynnsim5
 henon
 henon
 hex_rand
 hex_truchet
 hypershift
 lazyjess
 lens
 lozi
 lozi
 modulusx
 modulusy
 oscilloscope2
 point_symmetry
 pointsymmetry
 projective
 pulse
 rotate
 scry2
 shift
 smartshape
 spher
 squares
 starblur2
 swirl3
 swirl3r
 tanh_spiral
 target0
 target2
 tile_hlp
 truchet_glyph
 truchet_inv
 truchet_knot
 unicorngaloshen
 vibration
 vibration2
 --hex_truchet, hex_rand should always use double. They are extremely sensitive.

--Bug fixes:
 -Bounds sign was flipped for x coordinate of world space when center was not zero.
 -Right clicking and dragging spinner showed menu on mouse up, even if it was very far away.
 -Text boxes for size in final render dialog were hard to type in. Same bug as xform weight used to be so fix the same way.
 -Fix spelling to be plural in toggle color speed box.
 -Stop using the blank user palette to generate flames. Either put colored palettes in it, or exclude it from randoms.
 -Clicking the random palette button for a palette file with only one palette in it would freeze the program.
 -Clicking none scale in final render did not re-render the preview.
 -Use less precision on random xaos. No need for 12 decimal places.
 -The term sub batch is overloaded in the options dialog. Change the naming and tooltip of those settings for cpu and opencl.
 --Also made clear in the tooltip for the default opencl quality setting that the value is per device.
 -The arrows spinner in palette editor appears like a read-only label. Made it look like a spinner.
 -Fix border colors for various spin boxes and table headers in the style sheet. Requires reload.
 -Fix a bug in the bwraps variation which would produce different results than Chaotica and Apophysis.
 -Synth was allowed to be selected for random flame generation when using an Nvidia card but it shouldn't have been because Nvidia has a hard time compiling synth.
 -A casting bug in the OpenCL kernels for log scaling and density filtering was preventing successful compilations on Intel iGPUs. Fixed even though we don't support anything other than AMD and Nvidia.
 -Palette rotation (click and drag) position was not being reset when loading a new flame.
 -When the xform circles were hidden, opening and closing the options dialog would improperly reshow them.
 -Double click toggle was broken on integer spin boxes.
 -Fixed tab order of some controls.
 -Creating a palette from a jpg in the palette editor only produced a single color.
 --Needed to package imageformats/qjpeg.dll with the Windows installer.
 -The basic memory benchmark test flame was not really testing memory. Make it more spread out.
 -Remove the temporal samples field from the flame tab, it was never used because it's only an animation parameter which is specified in the final render dialog or on the command line with EmberAnimate.

--Code changes:
 -Add IsEmpty() to Palette to determine if a palette is all black.
 -Attempt to avoid selecting a blank palette in PaletteList::GetRandomPalette().
 -Add function ScanForChaosNodes() and some associated helper functions in XmlToEmber.
 -Make variation param name correction be case insensitive in XmlToEmber.
 -Report error when assigning a variation param value in XmlToEmber.
 -Add SubBatchPercentPerThread() method to RendererCL.
 -Override enterEvent() and leaveEvent() in DoubleSpinBox and SpinBox to prevent the context menu from showing up on right mouse up after already leaving the spinner.
 -Filtering the mouse wheel event in TableWidget no longer appears to be needed. It was probably an old Qt bug that has been fixed.
 -Gui/ember syncing code in the final render dialog needed to be reworked to accommodate absolute sizes.
2019-04-13 19:00:46 -07:00

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#include "FractoriumPch.h"
#include "Fractorium.h"
/// <summary>
/// Initialize the parameters UI.
/// </summary>
void Fractorium::InitParamsUI()
{
int row = 0;
int spinHeight = 20;
double dmax = numeric_limits<double>::max();
vector<string> comboVals;
QTableWidget* table = ui.ColorTable;
//Because QTableWidget does not allow for a single title bar/header
//at the top of a multi-column table, the workaround hack is to just
//make another single column table with no rows, and use the single
//column header as the title bar. Then positioning it right above the table
//that holds the data. Disallow selecting and resizing of the title bar.
SetFixedTableHeader(ui.ColorTableHeader->horizontalHeader());
SetFixedTableHeader(ui.GeometryTableHeader->horizontalHeader());
SetFixedTableHeader(ui.FilterTableHeader->horizontalHeader());
SetFixedTableHeader(ui.IterationTableHeader->horizontalHeader());
SetFixedTableHeader(ui.AnimationTableHeader->horizontalHeader());
//Color.
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_BrightnessSpin, spinHeight, 0.05, 1000, 1, SIGNAL(valueChanged(double)), SLOT(OnBrightnessChanged(double)), true, 4.0, 4.0, 4.0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_GammaSpin, spinHeight, 1, 9999, 0.5, SIGNAL(valueChanged(double)), SLOT(OnGammaChanged(double)), true, 4.0, 4.0, 4.0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_GammaThresholdSpin, spinHeight, 0, 10, 0.01, SIGNAL(valueChanged(double)), SLOT(OnGammaThresholdChanged(double)), true, 0.1, 0.1, 0.0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_VibrancySpin, spinHeight, 0, 30, 0.01, SIGNAL(valueChanged(double)), SLOT(OnVibrancyChanged(double)), true, 1.0, 1.0, 0.0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_HighlightSpin, spinHeight, -1.0, 10, 0.1, SIGNAL(valueChanged(double)), SLOT(OnHighlightPowerChanged(double)), true, 1.0, 1.0, -1.0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_K2Spin, spinHeight, 0, 10.0, 0.0001, SIGNAL(valueChanged(double)), SLOT(OnK2Changed(double)), true, 0, 0.0001, 0);
m_HighlightSpin->DoubleClickLowVal(-1.0);
int dec = 6;
m_BrightnessSpin->setDecimals(dec);
m_GammaSpin->setDecimals(dec);
m_GammaThresholdSpin->setDecimals(dec);
m_VibrancySpin->setDecimals(dec);
m_HighlightSpin->setDecimals(dec);
m_K2Spin->setDecimals(dec);
m_BgRow = row;
m_BackgroundColorButton = new QPushButton("...", table);
m_BackgroundColorButton->setMinimumWidth(21);
m_BackgroundColorButton->setMaximumWidth(21);
table->setCellWidget(row, 1, m_BackgroundColorButton);
table->item(row, 1)->setTextAlignment(Qt::AlignRight | Qt::AlignVCenter);
connect(m_BackgroundColorButton, SIGNAL(clicked(bool)), this, SLOT(OnBackgroundColorButtonClicked(bool)), Qt::QueuedConnection);
row++;
comboVals.push_back("Step");
comboVals.push_back("Linear");
SetupCombo(table, this, row, 1, m_PaletteModeCombo, comboVals, SIGNAL(currentIndexChanged(int)), SLOT(OnPaletteModeComboCurrentIndexChanged(int)));
m_PaletteModeCombo->SetCurrentIndexStealth(int(ePaletteMode::PALETTE_LINEAR));
table->horizontalHeader()->setSectionResizeMode(0, QHeaderView::ResizeToContents);
//Geometry.
row = 0;
table = ui.GeometryTable;
SetupSpinner<SpinBox, int> (table, this, row, 1, m_WidthSpin, spinHeight, 10, 2048, 50, SIGNAL(valueChanged(int)), SLOT(OnWidthChanged(int)), true, width(), width(), width());
SetupSpinner<SpinBox, int> (table, this, row, 1, m_HeightSpin, spinHeight, 10, 2048, 50, SIGNAL(valueChanged(int)), SLOT(OnHeightChanged(int)), true, height(), height(), height());
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_CenterXSpin, spinHeight, -dmax, dmax, 0.05, SIGNAL(valueChanged(double)), SLOT(OnCenterXChanged(double)), true, 0, 0, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_CenterYSpin, spinHeight, -dmax, dmax, 0.05, SIGNAL(valueChanged(double)), SLOT(OnCenterYChanged(double)), true, 0, 0, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_ScaleSpin, spinHeight, 10, dmax, 20, SIGNAL(valueChanged(double)), SLOT(OnScaleChanged(double)), true, 240, 240, 240);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_ZoomSpin, spinHeight, 0, 25, 0.2, SIGNAL(valueChanged(double)), SLOT(OnZoomChanged(double)), true, 0, 0, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_RotateSpin, spinHeight, -180, 180, 10, SIGNAL(valueChanged(double)), SLOT(OnRotateChanged(double)), true, 0, 0, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_ZPosSpin, spinHeight, -1000, 1000, 1, SIGNAL(valueChanged(double)), SLOT(OnZPosChanged(double)), true, 0, 1, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_PerspectiveSpin, spinHeight, -500, 500, 0.01, SIGNAL(valueChanged(double)), SLOT(OnPerspectiveChanged(double)), true, 0, 1, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_PitchSpin, spinHeight, -dmax, dmax, 1, SIGNAL(valueChanged(double)), SLOT(OnPitchChanged(double)), true, 0, 45, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_YawSpin, spinHeight, -dmax, dmax, 1, SIGNAL(valueChanged(double)), SLOT(OnYawChanged(double)), true, 0, 45, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_DepthBlurSpin, spinHeight, -dmax, dmax, 0.01, SIGNAL(valueChanged(double)), SLOT(OnDepthBlurChanged(double)), true, 0, 1, 0);
m_WidthSpin->m_DoubleClickNonZeroEvent = [&](SpinBox * sb, int val)
{
m_Controller->ResizeAndScale(val, m_HeightSpin->DoubleClickNonZero(), eScaleType::SCALE_WIDTH);
m_HeightSpin->SetValueStealth(m_HeightSpin->DoubleClickNonZero());
};
m_HeightSpin->m_DoubleClickNonZeroEvent = [&](SpinBox * sb, int val)
{
m_Controller->ResizeAndScale(m_WidthSpin->DoubleClickNonZero(), val, eScaleType::SCALE_HEIGHT);
m_WidthSpin->SetValueStealth(m_WidthSpin->DoubleClickNonZero());
};
dec = 4;
m_CenterXSpin->setDecimals(dec);
m_CenterYSpin->setDecimals(dec);
m_ZPosSpin->setDecimals(dec);
m_PerspectiveSpin->setDecimals(dec);
m_DepthBlurSpin->setDecimals(dec);
table->horizontalHeader()->setSectionResizeMode(0, QHeaderView::ResizeToContents);
//Filter.
row = 0;
table = ui.FilterTable;
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_SpatialFilterWidthSpin, spinHeight, 0, 2, 0.1, SIGNAL(valueChanged(double)), SLOT(OnSpatialFilterWidthChanged(double)), true, 1.0, 1.0, 0);
comboVals = SpatialFilterCreator<float>::FilterTypes();
SetupCombo(table, this, row, 1, m_SpatialFilterTypeCombo, comboVals, SIGNAL(currentIndexChanged(const QString&)), SLOT(OnSpatialFilterTypeComboCurrentIndexChanged(const QString&)));
m_SpatialFilterTypeCombo->SetCurrentIndexStealth(0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_DEFilterMinRadiusSpin, spinHeight, 0, 25, 1, SIGNAL(valueChanged(double)), SLOT(OnDEFilterMinRadiusWidthChanged(double)), true, 0, 0, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_DEFilterMaxRadiusSpin, spinHeight, 0, 25, 1, SIGNAL(valueChanged(double)), SLOT(OnDEFilterMaxRadiusWidthChanged(double)), true, 0.0, 9.0, 0);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_DECurveSpin, spinHeight, 0.15, 5, 0.1, SIGNAL(valueChanged(double)), SLOT(OnDEFilterCurveWidthChanged(double)), true, 0.4, 0.4, 0.4);
table->horizontalHeader()->setSectionResizeMode(0, QHeaderView::ResizeToContents);
//Iteration.
row = 0;
table = ui.IterationTable;
auto quality = m_Settings->OpenCL() ? m_Settings->OpenClQuality() : m_Settings->CpuQuality();
SetupSpinner<SpinBox, int>( table, this, row, 1, m_SbsSpin, spinHeight, 1000, 100000, 100, SIGNAL(valueChanged(int)), SLOT(OnSbsChanged(int)), true, DEFAULT_SBS, DEFAULT_SBS, DEFAULT_SBS);
SetupSpinner<SpinBox, int>( table, this, row, 1, m_FuseSpin, spinHeight, 1, 1000, 5, SIGNAL(valueChanged(int)), SLOT(OnFuseChanged(int)), true, 15, 100, 15);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_RandRangeSpin, spinHeight, 0.01, 1000, 0.1, SIGNAL(valueChanged(double)), SLOT(OnRandRangeChanged(double)), true, 1, 10, 1);
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_QualitySpin, spinHeight, 1, dmax, 50, SIGNAL(valueChanged(double)), SLOT(OnQualityChanged(double)), true, quality, 10, 10);
SetupSpinner<SpinBox, int>( table, this, row, 1, m_SupersampleSpin, spinHeight, 1, 4, 1, SIGNAL(valueChanged(int)), SLOT(OnSupersampleChanged(int)), true, 1, 2, 1);
m_RandRangeSpin->DoubleClickLowVal(1);
m_RandRangeSpin->setDecimals(4);
m_FuseSpin->DoubleClickLowVal(15);
m_SupersampleSpin->DoubleClickLowVal(1);
table->horizontalHeader()->setSectionResizeMode(0, QHeaderView::ResizeToContents);
//Animation.
row = 0;
table = ui.AnimationTable;
comboVals.clear();
comboVals.push_back("Linear");
comboVals.push_back("Smooth");
SetupCombo(table, this, row, 1, m_InterpTypeCombo, comboVals, SIGNAL(currentIndexChanged(int)), SLOT(OnInterpTypeComboCurrentIndexChanged(int)));
m_InterpTypeCombo->SetCurrentIndexStealth(int(eInterp::EMBER_INTERP_SMOOTH));
comboVals.clear();
comboVals.push_back("Linear");
comboVals.push_back("Log");
SetupCombo( table, this, row, 1, m_AffineInterpTypeCombo, comboVals, SIGNAL(currentIndexChanged(int)), SLOT(OnAffineInterpTypeComboCurrentIndexChanged(int)));
m_AffineInterpTypeCombo->SetCurrentIndexStealth(int(eAffineInterp::AFFINE_INTERP_LOG));
SetupSpinner<DoubleSpinBox, double>(table, this, row, 1, m_TemporalFilterWidthSpin, spinHeight, 1, 10, 1, SIGNAL(valueChanged(double)), SLOT(OnTemporalFilterWidthChanged(double)), true, 1);
comboVals = TemporalFilterCreator<float>::FilterTypes();
SetupCombo( table, this, row, 1, m_TemporalFilterTypeCombo, comboVals, SIGNAL(currentIndexChanged(const QString&)), SLOT(OnTemporalFilterTypeComboCurrentIndexChanged(const QString&)));
m_TemporalFilterTypeCombo->SetCurrentIndexStealth(int(eTemporalFilterType::GAUSSIAN_TEMPORAL_FILTER));
table->horizontalHeader()->setSectionResizeMode(0, QHeaderView::ResizeToContents);
}
/// <summary>
/// Return whether the apply all checkbox is checked.
/// </summary>
/// <returns>True if checked, else false.</returns>
bool Fractorium::ApplyAll()
{
return ui.ApplyAllParamsCheckBox->isChecked();
}
/// <summary>
/// Color.
/// </summary>
/// <summary>
/// Set the brightness to be used for calculating K1 and K2 for filtering and final accum.
/// Called when brightness spinner is changed.
/// Resets the rendering process to the filtering stage.
/// </summary>
/// <param name="d">The brightness</param>
template <typename T>
void FractoriumEmberController<T>::BrightnessChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_Brightness = d;
}, true, eProcessAction::FILTER_AND_ACCUM, m_Fractorium->ApplyAll());
}
void Fractorium::OnBrightnessChanged(double d) { m_Controller->BrightnessChanged(d); }
/// <summary>
/// Set the gamma to be used for final accum.
/// Called when gamma spinner is changed.
/// Resets the rendering process if temporal samples is greater than 1,
/// else if early clip is true, filter and accum, else final accum only.
/// </summary>
/// <param name="d">The gamma value</param>
template <typename T> void FractoriumEmberController<T>::GammaChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_Gamma = d;
}, true, m_Renderer->EarlyClip() ? eProcessAction::FILTER_AND_ACCUM : eProcessAction::ACCUM_ONLY, m_Fractorium->ApplyAll());
}
void Fractorium::OnGammaChanged(double d) { m_Controller->GammaChanged(d); }
/// <summary>
/// Set the gamma threshold to be used for final accum.
/// Called when gamma threshold spinner is changed.
/// Resets the rendering process to the final accumulation stage.
/// </summary>
/// <param name="d">The gamma threshold</param>
template <typename T> void FractoriumEmberController<T>::GammaThresholdChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_GammaThresh = d;
}, true, m_Renderer->EarlyClip() ? eProcessAction::FILTER_AND_ACCUM : eProcessAction::ACCUM_ONLY, m_Fractorium->ApplyAll());
}
void Fractorium::OnGammaThresholdChanged(double d) { m_Controller->GammaThresholdChanged(d); }
/// <summary>
/// Set the vibrancy to be used for final accum.
/// Called when vibrancy spinner is changed.
/// Resets the rendering process to the final accumulation stage if temporal samples is 1, else full reset.
/// </summary>
/// <param name="d">The vibrancy</param>
template <typename T> void FractoriumEmberController<T>::VibrancyChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_Vibrancy = d;
}, true, m_Renderer->EarlyClip() ? eProcessAction::FILTER_AND_ACCUM : eProcessAction::ACCUM_ONLY, m_Fractorium->ApplyAll());
}
void Fractorium::OnVibrancyChanged(double d) { m_Controller->VibrancyChanged(d); }
/// <summary>
/// Set the highlight power to be used for final accum.
/// Called when highlight power spinner is changed.
/// Resets the rendering process to the final accumulation stage.
/// </summary>
/// <param name="d">The highlight power</param>
template <typename T> void FractoriumEmberController<T>::HighlightPowerChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_HighlightPower = d;
}, true, m_Renderer->EarlyClip() ? eProcessAction::FILTER_AND_ACCUM : eProcessAction::ACCUM_ONLY, m_Fractorium->ApplyAll());
}
void Fractorium::OnHighlightPowerChanged(double d) { m_Controller->HighlightPowerChanged(d); }
/// <summary>
/// Set the k2 brightness value to be used for final accum.
/// Called when k2 is changed.
/// Resets the rendering process to the final accumulation stage.
/// </summary>
/// <param name="d">The k2 value</param>
template <typename T> void FractoriumEmberController<T>::K2Changed(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_K2 = d;
}, true, m_Renderer->EarlyClip() ? eProcessAction::FILTER_AND_ACCUM : eProcessAction::ACCUM_ONLY, m_Fractorium->ApplyAll());
}
void Fractorium::OnK2Changed(double d) { m_Controller->K2Changed(d); }
/// <summary>
/// Show the color selection dialog.
/// Called when background color button is clicked.
/// </summary>
/// <param name="checked">Ignored</param>
void Fractorium::OnBackgroundColorButtonClicked(bool checked)
{
m_ColorDialog->exec();
}
/// <summary>
/// Set a new ember background color when the user accepts the color dialog.
/// Also change the background and foreground colors of the color cell in the
/// color params table.
/// Resets the rendering process.
/// </summary>
/// <param name="color">The color to set, RGB in the 0-255 range</param>
template <typename T>
void FractoriumEmberController<T>::BackgroundChanged(const QColor& color)
{
auto itemRow = m_Fractorium->m_BgRow;
auto colorTable = m_Fractorium->ui.ColorTable;
colorTable->item(itemRow, 1)->setBackgroundColor(color);
auto r = ToString(color.red());
auto g = ToString(color.green());
auto b = ToString(color.blue());
colorTable->item(itemRow, 1)->setTextColor(VisibleColor(color));
colorTable->item(itemRow, 1)->setText("rgb(" + r + ", " + g + ", " + b + ")");
UpdateAll([&](Ember<T>& ember, bool isMain)
{
//Color is 0-255, normalize to 0-1.
ember.m_Background.r = color.red() / 255.0;
ember.m_Background.g = color.green() / 255.0;
ember.m_Background.b = color.blue() / 255.0;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnColorSelected(const QColor& color) { m_Controller->BackgroundChanged(color); }
/// <summary>
/// Set the palette index interpolation mode.
/// Called when palette mode combo box index is changed.
/// Resets the rendering process.
/// </summary>
/// <param name="index">The index of the palette mode combo box</param>
template <typename T> void FractoriumEmberController<T>::PaletteModeChanged(uint i)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_PaletteMode = i == 0 ? ePaletteMode::PALETTE_STEP : ePaletteMode::PALETTE_LINEAR;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnPaletteModeComboCurrentIndexChanged(int index) { m_Controller->PaletteModeChanged(index); }
/// <summary>
/// Geometry.
/// </summary>
/// <summary>
/// Set the width of the ember in pixels to the passed in value.
/// Called when the width spinner is changed in a manner other than double clicking.
/// Resets the rendering process.
/// </summary>
/// <param name="i">The width value in pixels to set</param>
template <typename T> void FractoriumEmberController<T>::WidthChanged(uint i)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_FinalRasW = i;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnWidthChanged(int i) { m_Controller->WidthChanged(i); }
/// <summary>
/// Set the height of the ember in pixels to the passed in value.
/// Called when the height spinner is changed in a manner other than double clicking.
/// Resets the rendering process.
/// </summary>
/// <param name="i">The height value in pixels to set</param>
template <typename T> void FractoriumEmberController<T>::HeightChanged(uint i)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_FinalRasH = i;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnHeightChanged(int i) { m_Controller->HeightChanged(i); }
/// <summary>
/// Set the width and height of the ember in pixels to the passed in values.
/// Called when either the width or height spinners are double clicked.
/// Because this will change the scale value, the scale spinner gets a stealth update.
/// For this reason, the affine scales are reset, even though they are not when doing a manual
/// height or width adjustment.
/// Resets the rendering process.
/// </summary>
/// <param name="width">The width value in pixels to set</param>
/// <param name="height">The height value in pixels to set</param>
/// <param name="scaleType">The height value in pixels to set</param>
template <typename T>
void FractoriumEmberController<T>::ResizeAndScale(int width, int height, eScaleType scaleType)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
m_Ember.SetSizeAndAdjustScale(width, height, false, scaleType);
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
m_Fractorium->m_ScaleSpin->SetValueStealth(m_Ember.m_PixelsPerUnit);
m_Fractorium->OnActionResetScale(true);
}
/// <summary>
/// Set the x offset applied to the center of the image.
/// Resets the rendering process.
/// </summary>
/// <param name="d">The x offset value</param>
template <typename T> void FractoriumEmberController<T>::CenterXChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_CenterX = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnCenterXChanged(double d) { m_Controller->CenterXChanged(d); }
/// <summary>
/// Set the y offset applied to the center of the image.
/// Resets the rendering process.
/// </summary>
/// <param name="d">The y offset value</param>
template <typename T> void FractoriumEmberController<T>::CenterYChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_CenterY = ember.m_RotCenterY = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnCenterYChanged(double d) { m_Controller->CenterYChanged(d); }
/// <summary>
/// Set the scale (pixels per unit) value of the image.
/// Note this will not increase the number of iters ran, but will degrade quality.
/// To preserve quality, but exponentially increase iters, use zoom.
/// Called when scale spinner is changed.
/// Resets the rendering process.
/// </summary>
/// <param name="d">The scale value</param>
template <typename T> void FractoriumEmberController<T>::ScaleChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_PixelsPerUnit = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnScaleChanged(double d) { m_Controller->ScaleChanged(d); }
/// <summary>
/// Set the zoom value of the image.
/// Note this will increase the number of iters ran exponentially.
/// To zoom in without increasing iters, but sacrifice quality, use scale.
/// Called when zoom spinner is changed.
/// Resets the rendering process.
/// </summary>
/// <param name="d">The zoom value</param>
template <typename T> void FractoriumEmberController<T>::ZoomChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_Zoom = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnZoomChanged(double d) { m_Controller->ZoomChanged(d); }
/// <summary>
/// Set the angular rotation of the image.
/// Called when rotate spinner is changed.
/// Resets the rendering process.
/// </summary>
/// <param name="d">The rotation in angles</param>
template <typename T> void FractoriumEmberController<T>::RotateChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_Rotate = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnRotateChanged(double d) { m_Controller->RotateChanged(d); }
template <typename T> void FractoriumEmberController<T>::ZPosChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_CamZPos = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnZPosChanged(double d) { m_Controller->ZPosChanged(d); }
template <typename T> void FractoriumEmberController<T>::PerspectiveChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_CamPerspective = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnPerspectiveChanged(double d) { m_Controller->PerspectiveChanged(d); }
template <typename T> void FractoriumEmberController<T>::PitchChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_CamPitch = d * DEG_2_RAD;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnPitchChanged(double d) { m_Controller->PitchChanged(d); }
template <typename T> void FractoriumEmberController<T>::YawChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_CamYaw = d * DEG_2_RAD;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnYawChanged(double d) { m_Controller->YawChanged(d); }
template <typename T> void FractoriumEmberController<T>::DepthBlurChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_CamDepthBlur = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnDepthBlurChanged(double d) { m_Controller->DepthBlurChanged(d); }
/// <summary>
/// Filter.
/// </summary>
/// <summary>
/// Set the spatial filter width.
/// Called when the spatial filter width spinner is changed.
/// Resets the rendering process to density filtering if early clip is used, else to final accumulation.
/// </summary>
/// <param name="d">The spatial filter width</param>
template <typename T> void FractoriumEmberController<T>::SpatialFilterWidthChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_SpatialFilterRadius = d;
}, true, m_Renderer->EarlyClip() ? eProcessAction::FILTER_AND_ACCUM : eProcessAction::ACCUM_ONLY, m_Fractorium->ApplyAll());
}
void Fractorium::OnSpatialFilterWidthChanged(double d) { m_Controller->SpatialFilterWidthChanged(d); }
/// <summary>
/// Set the spatial filter type.
/// Called when the spatial filter type combo box index is changed.
/// Resets the rendering process to density filtering if early clip is used, else to final accumulation.
/// </summary>
/// <param name="text">The spatial filter type</param>
template <typename T> void FractoriumEmberController<T>::SpatialFilterTypeChanged(const QString& text)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_SpatialFilterType = SpatialFilterCreator<T>::FromString(text.toStdString());
}, true, m_Renderer->EarlyClip() ? eProcessAction::FILTER_AND_ACCUM : eProcessAction::ACCUM_ONLY, m_Fractorium->ApplyAll());
}
void Fractorium::OnSpatialFilterTypeComboCurrentIndexChanged(const QString& text) { m_Controller->SpatialFilterTypeChanged(text); }
/// <summary>
/// Set the density estimation filter min radius value.
/// Resets the rendering process to density filtering.
/// </summary>
/// <param name="d">The min radius value</param>
template <typename T>
void FractoriumEmberController<T>::DEFilterMinRadiusWidthChanged(double d)
{
if (m_Ember.m_MinRadDE != d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_MinRadDE = d;
}, true, eProcessAction::FILTER_AND_ACCUM, m_Fractorium->ApplyAll());
}
}
void Fractorium::OnDEFilterMinRadiusWidthChanged(double d)
{
ConstrainLow(m_DEFilterMinRadiusSpin, m_DEFilterMaxRadiusSpin);
m_Controller->DEFilterMinRadiusWidthChanged(m_DEFilterMinRadiusSpin->value());
}
/// <summary>
/// Set the density estimation filter max radius value.
/// Resets the rendering process to density filtering.
/// </summary>
/// <param name="d">The max radius value</param>
template <typename T>
void FractoriumEmberController<T>::DEFilterMaxRadiusWidthChanged(double d)
{
if (m_Ember.m_MaxRadDE != d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_MaxRadDE = d;
}, true, eProcessAction::FILTER_AND_ACCUM, m_Fractorium->ApplyAll());
}
}
void Fractorium::OnDEFilterMaxRadiusWidthChanged(double d)
{
ConstrainHigh(m_DEFilterMinRadiusSpin, m_DEFilterMaxRadiusSpin);
m_Controller->DEFilterMaxRadiusWidthChanged(m_DEFilterMaxRadiusSpin->value());
}
/// <summary>
/// Set the density estimation filter curve value.
/// Resets the rendering process to density filtering.
/// </summary>
/// <param name="d">The curve value</param>
template <typename T> void FractoriumEmberController<T>::DEFilterCurveWidthChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_CurveDE = d;
}, true, eProcessAction::FILTER_AND_ACCUM, m_Fractorium->ApplyAll());
}
void Fractorium::OnDEFilterCurveWidthChanged(double d) { m_Controller->DEFilterCurveWidthChanged(d); }
/// <summary>
/// Iteration.
/// </summary>
/// <summary>
/// Set the iteration depth.
/// Called when the sub batch size spinner is changed.
/// Resets the rendering process.
/// </summary>
/// <param name="d">The sub batch size value to set</param>
template <typename T> void FractoriumEmberController<T>::SbsChanged(int d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_SubBatchSize = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnSbsChanged(int d) { m_Controller->SbsChanged(d); }
/// <summary>
/// Set the range from which to chose the starting random points, as well as point resets due to bad points.
/// Called when the rand range spinner is changed.
/// Resets the rendering process.
/// </summary>
/// <param name="d">The sub batch size value to set</param>
template <typename T> void FractoriumEmberController<T>::RandRangeChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_RandPointRange = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnRandRangeChanged(double d) { m_Controller->RandRangeChanged(d); }
/// <summary>
/// Set the number of samples to disregard for each sub batch.
/// Called when the fuse count spinner is changed.
/// Resets the rendering process.
/// </summary>
/// <param name="d">The fuse count value to set</param>
template <typename T> void FractoriumEmberController<T>::FuseChanged(int d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_FuseCount = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnFuseChanged(int d) { m_Controller->FuseChanged(d); }
/// <summary>
/// Set the quality.
/// 10 is good for interactive rendering on the CPU.
/// 20-50 is good for OpenCL.
/// Above 500 seems to offer little additional value for final renders.
/// Called when the quality spinner is changed.
/// If rendering is done, and the value is greater than the last value,
/// the rendering process is continued, else it's reset.
/// </summary>
/// <param name="d">The quality in terms of iterations per pixel</param>
template <typename T> void FractoriumEmberController<T>::QualityChanged(double d) { }
void Fractorium::OnQualityChanged(double d) { m_Controller->QualityChanged(d); }
/// <summary>
/// Set the supersample.
/// Note this will dramatically degrade performance, especially in
/// OpenCL, while only giving a minor improvement in visual quality.
/// Values above 2 add no noticeable difference.
/// The user should only use this for a final render, or a quick preview, and then
/// reset it back to 1 when done.
/// Called when the supersample spinner is changed.
/// Resets the rendering process.
/// </summary>
/// <param name="d">The supersample value to set</param>
template <typename T> void FractoriumEmberController<T>::SupersampleChanged(int d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_Supersample = d;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
}
void Fractorium::OnSupersampleChanged(int d) { m_Controller->SupersampleChanged(d); }
/// <summary>
/// Set the affine interpolation type.
/// Does not reset anything because this is only used for animation.
/// In the future, when animation is implemented, this will have an effect.
/// Called when the affine interp type combo box index is changed.
/// </summary>
/// <param name="index">The index</param>
template <typename T>
void FractoriumEmberController<T>::AffineInterpTypeChanged(int i)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
eAffineInterp interp;
if (i == 0)
interp = eAffineInterp::AFFINE_INTERP_LINEAR;
else if (i == 1)
interp = eAffineInterp::AFFINE_INTERP_LOG;
else
interp = eAffineInterp::AFFINE_INTERP_LINEAR;
ember.m_AffineInterp = interp;
if (!m_Fractorium->ApplyAll())
if (m_EmberFilePointer)
m_EmberFilePointer->m_AffineInterp = interp;
}, false, eProcessAction::NOTHING, m_Fractorium->ApplyAll());
}
void Fractorium::OnAffineInterpTypeComboCurrentIndexChanged(int index) { m_Controller->AffineInterpTypeChanged(index); }
/// <summary>
/// Set the interpolation type.
/// Does not reset anything because this is only used for animation.
/// Called when the interp type combo box index is changed.
/// </summary>
/// <param name="i">The index</param>
template <typename T>
void FractoriumEmberController<T>::InterpTypeChanged(int i)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
eInterp interp;
if (i == 0)
interp = eInterp::EMBER_INTERP_LINEAR;
else if (i == 1)
interp = eInterp::EMBER_INTERP_SMOOTH;
else
interp = eInterp::EMBER_INTERP_LINEAR;
ember.m_Interp = interp;
if (!m_Fractorium->ApplyAll())
if (m_EmberFilePointer)
m_EmberFilePointer->m_Interp = interp;
}, false, eProcessAction::NOTHING, m_Fractorium->ApplyAll());
}
void Fractorium::OnInterpTypeComboCurrentIndexChanged(int index) { m_Controller->InterpTypeChanged(index); }
/// <summary>
/// Set the temporal filter width to be used with animation.
/// Called when the temporal filter width spinner is changed.
/// Does not reset anything because this is only used for animation.
/// </summary>
/// <param name="d">The temporal filter width</param>
template <typename T>
void FractoriumEmberController<T>::TemporalFilterWidthChanged(double d)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_TemporalFilterWidth = d;
if (!m_Fractorium->ApplyAll())
if (m_EmberFilePointer)
m_EmberFilePointer->m_TemporalFilterWidth = d;
}, false, eProcessAction::NOTHING, m_Fractorium->ApplyAll());//Don't do anything until animation is implemented.
}
void Fractorium::OnTemporalFilterWidthChanged(double d) { m_Controller->TemporalFilterWidthChanged(d); }
/// <summary>
/// Set the temporal filter type to be used with animation.
/// Called when the temporal filter combo box index is changed.
/// Does not reset anything because this is only used for animation.
/// </summary>
/// <param name="text">The name of the temporal filter</param>
template <typename T>
void FractoriumEmberController<T>::TemporalFilterTypeChanged(const QString& text)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
auto filter = TemporalFilterCreator<T>::FromString(text.toStdString());
ember.m_TemporalFilterType = filter;
if (!m_Fractorium->ApplyAll())
if (m_EmberFilePointer)
m_EmberFilePointer->m_TemporalFilterType = filter;
}, false, eProcessAction::NOTHING, m_Fractorium->ApplyAll());//Don't do anything until animation is implemented.
}
void Fractorium::OnTemporalFilterTypeComboCurrentIndexChanged(const QString& text) { m_Controller->TemporalFilterTypeChanged(text); }
/// <summary>
/// Set the center.
/// This updates the spinners as well as the current ember center.
/// Resets the renering process.
/// </summary>
/// <param name="x">The x offset</param>
/// <param name="y">The y offset</param>
template <typename T>
void FractoriumEmberController<T>::SetCenter(double x, double y)
{
UpdateAll([&](Ember<T>& ember, bool isMain)
{
ember.m_CenterX = x;
ember.m_CenterY = ember.m_RotCenterY = y;
}, true, eProcessAction::FULL_RENDER, m_Fractorium->ApplyAll());
m_Fractorium->m_CenterXSpin->SetValueStealth(x);//Don't trigger a redraw twice.
m_Fractorium->m_CenterYSpin->SetValueStealth(y);
}
/// <summary>
/// Fill the parameter tables and palette widgets with values from the current ember.
/// This takes ~1-2ms.
/// </summary>
template <typename T>
void FractoriumEmberController<T>::FillParamTablesAndPalette()
{
m_Fractorium->m_BrightnessSpin->SetValueStealth(m_Ember.m_Brightness);//Color.
m_Fractorium->m_GammaSpin->SetValueStealth(m_Ember.m_Gamma);
m_Fractorium->m_GammaThresholdSpin->SetValueStealth(m_Ember.m_GammaThresh);
m_Fractorium->m_VibrancySpin->SetValueStealth(m_Ember.m_Vibrancy);
m_Fractorium->m_HighlightSpin->SetValueStealth(m_Ember.m_HighlightPower);
m_Fractorium->m_K2Spin->SetValueStealth(m_Ember.m_K2);
m_Fractorium->m_ColorDialog->setCurrentColor(QColor(m_Ember.m_Background.r * 255, m_Ember.m_Background.g * 255, m_Ember.m_Background.b * 255));
m_Fractorium->ui.ColorTable->item(m_Fractorium->m_BgRow, 1)->setBackgroundColor(m_Fractorium->m_ColorDialog->currentColor());
BackgroundChanged(m_Fractorium->m_ColorDialog->currentColor());
m_Fractorium->m_PaletteModeCombo->SetCurrentIndexStealth(int(m_Ember.m_PaletteMode));
m_Fractorium->m_WidthSpin->SetValueStealth(m_Ember.m_FinalRasW);//Geometry.
m_Fractorium->m_HeightSpin->SetValueStealth(m_Ember.m_FinalRasH);
m_Fractorium->m_CenterXSpin->SetValueStealth(m_Ember.m_CenterX);
m_Fractorium->m_CenterYSpin->SetValueStealth(m_Ember.m_CenterY);
m_Fractorium->m_ScaleSpin->SetValueStealth(m_Ember.m_PixelsPerUnit);
m_Fractorium->m_ZoomSpin->SetValueStealth(m_Ember.m_Zoom);
m_Fractorium->m_RotateSpin->SetValueStealth(m_Ember.m_Rotate);
m_Fractorium->m_ZPosSpin->SetValueStealth(m_Ember.m_CamZPos);
m_Fractorium->m_PerspectiveSpin->SetValueStealth(m_Ember.m_CamPerspective);
m_Fractorium->m_PitchSpin->SetValueStealth(m_Ember.m_CamPitch * RAD_2_DEG_T);
m_Fractorium->m_YawSpin->SetValueStealth(m_Ember.m_CamYaw * RAD_2_DEG_T);
m_Fractorium->m_DepthBlurSpin->SetValueStealth(m_Ember.m_CamDepthBlur);
m_Fractorium->m_SpatialFilterWidthSpin->SetValueStealth(m_Ember.m_SpatialFilterRadius);//Filter.
m_Fractorium->m_SpatialFilterTypeCombo->SetCurrentIndexStealth(int(m_Ember.m_SpatialFilterType));
m_Fractorium->m_TemporalFilterWidthSpin->SetValueStealth(m_Ember.m_TemporalFilterWidth);
m_Fractorium->m_TemporalFilterTypeCombo->SetCurrentIndexStealth(int(m_Ember.m_TemporalFilterType));
m_Fractorium->m_DEFilterMinRadiusSpin->SetValueStealth(m_Ember.m_MinRadDE);
m_Fractorium->m_DEFilterMaxRadiusSpin->SetValueStealth(m_Ember.m_MaxRadDE);
m_Fractorium->m_DECurveSpin->SetValueStealth(m_Ember.m_CurveDE);
m_Fractorium->m_SbsSpin->SetValueStealth(m_Ember.m_SubBatchSize);//Iteration.
m_Fractorium->m_FuseSpin->SetValueStealth(m_Ember.m_FuseCount);
m_Fractorium->m_RandRangeSpin->SetValueStealth(m_Ember.m_RandPointRange);
m_Fractorium->m_QualitySpin->SetValueStealth(m_Ember.m_Quality);
m_Fractorium->m_SupersampleSpin->SetValueStealth(m_Ember.m_Supersample);
m_Fractorium->m_AffineInterpTypeCombo->SetCurrentIndexStealth(int(m_Ember.m_AffineInterp));
m_Fractorium->m_InterpTypeCombo->SetCurrentIndexStealth(int(m_Ember.m_Interp));
auto temp = m_Ember.m_Palette.m_Filename;
if (temp.get())
m_Fractorium->SetPaletteFileComboIndex(*temp.get());
//Update the palette preview widget.
m_Fractorium->ResetPaletteControls();
//Since the controls were cleared above, the adjusted palette will be identical to the base palette.
//Callers can set, apply and display palette adjustments after this function exits if needed.
SetBasePaletteAndAdjust(m_Ember.m_Palette);//Updating the palette GUI will trigger a full render.
InitLockedScale();
}
/// <summary>
/// Copy all GUI widget values on the parameters tab to the passed in ember.
/// </summary>
/// <param name="ember">The ember to copy values to.</param>
template <typename T>
void FractoriumEmberController<T>::ParamsToEmber(Ember<T>& ember)
{
auto color = m_Fractorium->ui.ColorTable->item(5, 1)->backgroundColor();
ember.m_Brightness = m_Fractorium->m_BrightnessSpin->value();//Color.
ember.m_Gamma = m_Fractorium->m_GammaSpin->value();
ember.m_GammaThresh = m_Fractorium->m_GammaThresholdSpin->value();
ember.m_Vibrancy = m_Fractorium->m_VibrancySpin->value();
ember.m_HighlightPower = m_Fractorium->m_HighlightSpin->value();
ember.m_K2 = m_Fractorium->m_K2Spin->value();
ember.m_Background.r = color.red() / 255.0;
ember.m_Background.g = color.green() / 255.0;
ember.m_Background.b = color.blue() / 255.0;
ember.m_PaletteMode = ePaletteMode(m_Fractorium->m_PaletteModeCombo->currentIndex());
ember.m_FinalRasW = m_Fractorium->m_WidthSpin->value();//Geometry.
ember.m_FinalRasH = m_Fractorium->m_HeightSpin->value();
ember.m_CenterX = m_Fractorium->m_CenterXSpin->value();
ember.m_CenterY = ember.m_RotCenterY = m_Fractorium->m_CenterYSpin->value();
ember.m_PixelsPerUnit = m_Fractorium->m_ScaleSpin->value();
ember.m_Zoom = m_Fractorium->m_ZoomSpin->value();
ember.m_Rotate = m_Fractorium->m_RotateSpin->value();
ember.m_CamZPos = m_Fractorium->m_ZPosSpin->value();
ember.m_CamPerspective = m_Fractorium->m_PerspectiveSpin->value();
ember.m_CamPitch = m_Fractorium->m_PitchSpin->value() * DEG_2_RAD_T;
ember.m_CamYaw = m_Fractorium->m_YawSpin->value() * DEG_2_RAD_T;
ember.m_CamDepthBlur = m_Fractorium->m_DepthBlurSpin->value();
ember.m_SpatialFilterRadius = m_Fractorium->m_SpatialFilterWidthSpin->value();//Filter.
ember.m_SpatialFilterType = eSpatialFilterType(m_Fractorium->m_SpatialFilterTypeCombo->currentIndex());
ember.m_TemporalFilterWidth = m_Fractorium->m_TemporalFilterWidthSpin->value();
ember.m_TemporalFilterType = eTemporalFilterType(m_Fractorium->m_TemporalFilterTypeCombo->currentIndex());
ember.m_MinRadDE = m_Fractorium->m_DEFilterMinRadiusSpin->value();
ember.m_MaxRadDE = m_Fractorium->m_DEFilterMaxRadiusSpin->value();
ember.m_CurveDE = m_Fractorium->m_DECurveSpin->value();
ember.m_SubBatchSize = m_Fractorium->m_SbsSpin->value();
ember.m_FuseCount = m_Fractorium->m_FuseSpin->value();
ember.m_RandPointRange = m_Fractorium->m_RandRangeSpin->value();
ember.m_Quality = m_Fractorium->m_QualitySpin->value();
ember.m_Supersample = m_Fractorium->m_SupersampleSpin->value();
ember.m_AffineInterp = eAffineInterp(m_Fractorium->m_AffineInterpTypeCombo->currentIndex());
ember.m_Interp = eInterp(m_Fractorium->m_InterpTypeCombo->currentIndex());
ember.SyncSize();
}
/// <summary>
/// Set the rotation.
/// This updates the spinner, optionally stealth.
/// </summary>
/// <param name="rot">The rotation value in angles to set</param>
/// <param name="stealth">True if stealth to skip re-rendering, else false to trigger a new render</param>
void Fractorium::SetRotation(double rot, bool stealth)
{
if (stealth)
m_RotateSpin->SetValueStealth(rot);
else
m_RotateSpin->setValue(rot);
}
/// <summary>
/// Set the scale.
/// This is the number of raster pixels that correspond to the distance
/// between 0-1 in the cartesian plane. The higher the number, the more
/// zoomed in the image is.
/// Resets the rendering process.
/// </summary>
/// <param name="scale">The scale value</param>
void Fractorium::SetScale(double scale)
{
m_ScaleSpin->setValue(scale);
}
template class FractoriumEmberController<float>;
#ifdef DO_DOUBLE
template class FractoriumEmberController<double>;
#endif
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