1.1.4

6 years ago · ffc8b3d117
--- a/.astylerc
+++ b/.astylerc
@@ -0,0 +1,31 @@
 # astyle settings file
 # Requires Artistic Style 3.1
 # http://astyle.sourceforge.net/
 # Usage:
 # astyle --suffix=none --options=.astylerc filename.cpp
 # or recursively
 # astyle --suffix=none --options=.astylerc -r 'include/*' 'src/*'
 # or using find
 # find src include -type f | xargs astyle --suffix=none --options=.astylerc
 style=java
 indent=tab=2
 attach-closing-while
 indent-switches
 indent-preproc-block
 indent-preproc-define
 indent-col1-comments
 pad-oper
 pad-comma
 pad-header
 unpad-paren
 align-pointer=type
 align-reference=type
 break-closing-braces
 break-one-line-headers
 attach-return-type
 attach-return-type-decl
 keep-one-line-statements
 close-templates
--- a/.github/CONTRIBUTING.md
+++ b/.github/CONTRIBUTING.md
@@ -1,26 +1,28 @@
 ### Pre-implementation
 Before authoring a code contribution, open an issue explaining your proposal in detail.
 Remember that code is easy to write, but inventing a valid design is usually the crux.
 Expect the proposal to be rejected if you do not consider 100% of use-cases and corner cases.
 ### Code style and quality
 Be courteous and try to match the code style.
 I won't define the exact style here, so just follow the existing code.
 Use C++11 style, not >=C++14 or C.
 This means using the `std::` namespace for stdlib symbols, `std::string` instead of `char*`, `//` comments and `/** */` docstrings, etc.
 Avoid over-engineered things like `iostream`, `std::array`, `std::unique_ptr`, etc when simpler alternatives exist.
 Write maintainable code that will last >4 years.
 No feature/bug is urgent enough to write dirty/temporary implementations.
 I have no need to withdraw technical debt.
 ### Legal
 Because a proprietary fork of VCV Rack is planned by VCV (*Rack for DAWs*), in order for your patch to be accepted, you must make a declaration stating that:
 - you are the sole author of your patch.
 - your patch is released under the [CC0](https://creativecommons.org/publicdomain/zero/1.0/) license.
 - or ask for a copyright reassignment form if you prefer this instead.
 VCV Rack is [open-source](https://opensource.org/osd) but not [open-contribution](https://opensource.guide/how-to-contribute/).
 I am unable to accept free code contributions to Rack for the following reasons.
 - **Quality.**
 Most contributions to open-source projects typically only contain code, but writing code is just a small percentage of the effort required to maintain a large software project.
 Additional tasks for fully supporting a feature include
 	- debating the best design before any code is written
 	- considering all use cases and corner cases of the implementation
 	- generalizability to allow other features to be built on top if needed
 	- testing across all supported operating systems and hardware
 	- dedication to support the feature for >4 years
 - **Time.**
 In the past, free code contributions have cost far more time to review, iterate, fix, and test than writing the implementation from scratch.
 There have been exceptions to this, but they are rare.
 - **Legal.**
 A proprietary fork of VCV Rack is planned (see [*Rack for DAWs*](https://vcvrack.com/manual/FAQ.html#is-vcv-rack-available-as-a-vst-au-aax-plugin-for-daws)), so VCV must own all GPLv3 code.
 To accept a contribution, all authors of the contribution need to either
 	- declare the patch under the [CC0](https://creativecommons.org/publicdomain/zero/1.0/) license.
 	- complete a copyright reassignment form.
 	- perform the work under a paid agreement.
 Except in exceptional circumstances, contributions are only accepted as paid work under detailed guidelines.
 However there are several areas you may contribute Rack project.
 - [creating high-quality issues](https://vcvrack.com/manual/FAQ.html#i-found-a-bug)
 - responding to [issues](https://github.com/VCVRack/Rack/issues) and answering questions in the [VCV communities](https://vcvrack.com/manual/Communities.html)
 - [developing and maintaining your own plugins](https://vcvrack.com/manual/PluginDevelopmentTutorial.html)
 - contributing to Rack's open-source dependencies, like [GLFW](https://www.glfw.org/), [nanovg](https://github.com/memononen/nanovg), [RtAudio](https://www.music.mcgill.ca/~gary/rtaudio/), and [RtMidi](https://www.music.mcgill.ca/~gary/rtmidi/).
--- a/.github/ISSUE_TEMPLATE/bug_report.md
+++ b/.github/ISSUE_TEMPLATE/bug_report.md
@@ -5,10 +5,11 @@ about: Bugs, build errors, compatibility/stability issues
 ---
 <!--
 Search existing issues before posting a new one to avoid duplicates.
 To file a bug report, fill out the form below.
 Use a descriptive title that best explains the bug in one sentence.
 Attach screenshots if the bug is visual.
 Attach your `<Rack user folder>/log.txt` file if Rack is crashing.
 If Rack crashed, attach/upload (don't copy/paste) your `<Rack user folder>/log.txt` file.
 Surround terminal output with three tildes
 ```
 like this.
--- a/.github/ISSUE_TEMPLATE/feature_request.md
+++ b/.github/ISSUE_TEMPLATE/feature_request.md
@@ -5,6 +5,7 @@ about: Feature ideas, design proposals
 ---
 <!--
 Search existing issues before posting a new one to avoid duplicates.
 To request a feature, fill out the form below.
 Use a descriptive title that best explains the feature request in one sentence.
 -->
--- a/CHANGELOG.md
+++ b/CHANGELOG.md
@@ -2,6 +2,18 @@
 In this document, Mod is Ctrl on Windows/Linux and Cmd on Mac.
 ### 1.1.4 (2019-08-22)
 - Fix parameter smoothing of MIDI-Map.
 - Sort modules within plugin in the Module Browser according to plugin rather than alphabetically.
 - Fix bug where knobs sometimes jump while dragging.
 - Reimplement CPU meter to measure thread runtime, not real time.
 - Fix crashes when deleting/duplicating modules while dragging modules/cables in certain cases.
 - API
 	- Add `dsp::BiquadFilter`.
 	- Add `dsp/approx.hpp` with approximate math functions.
 	- Add `simd::tan()`, `atan()`, and `atan2()`.
 	- Add `string::toBase64()` and `fromBase64()`.
 ### 1.1.3 (2019-07-23)
 - Include root certificate bundle for libcurl on all OS's.
 - Revert to OpenSSL from Schannel on Windows.
--- a/Core.json
+++ b/Core.json
@@ -1,7 +1,7 @@
 {
  "slug": "Core",
  "name": "Core",
  "version": "1.1.3",
  "version": "1.1.4",
  "license": "GPL-3.0-only",
  "author": "VCV",
  "brand": "VCV",
--- a/Makefile
+++ b/Makefile
@@ -1,6 +1,6 @@
 RACK_DIR ?= .
 # VERSION := 1.dev.$(shell git rev-parse --short HEAD)
 VERSION := 1.1.3
 VERSION := 1.1.4
 FLAGS += -DVERSION=$(VERSION)
 FLAGS += -Iinclude -Idep/include
--- a/helper.py
+++ b/helper.py
@@ -200,7 +200,7 @@ def create_module(slug, panel_filename=None, source_filename=None):
 		module_manifest['slug'] = slug
 		module_manifest['name'] = input_default("Module name", slug)
 		module_manifest['description'] = input_default("One-line description (optional)")
 		tags = input_default("Tags (comma-separated, case-insensitive, see https://github.com/VCVRack/Rack/blob/v1/src/plugin.cpp#L511-L571 for list)")
 		tags = input_default("Tags (comma-separated, case-insensitive, see https://github.com/VCVRack/Rack/blob/v1/src/tag.cpp for list)")
 		tags = tags.split(",")
 		tags = [tag.strip() for tag in tags]
 		if len(tags) == 1 and tags[0] == "":
--- a/include/Quantity.hpp
+++ b/include/Quantity.hpp
@@ -19,24 +19,36 @@ struct Quantity {
 	/** Returns the value
 	Override this to return the state of your subclass.
 	*/
 	virtual float getValue() {return 0.f;}
 	virtual float getValue() {
 		return 0.f;
 	}
 	/** Returns the minimum allowed value */
 	virtual float getMinValue() {return 0.f;}
 	virtual float getMinValue() {
 		return 0.f;
 	}
 	/** Returns the maximum allowed value */
 	virtual float getMaxValue() {return 1.f;}
 	virtual float getMaxValue() {
 		return 1.f;
 	}
 	/** Returns the default value, for resetting */
 	virtual float getDefaultValue() {return 0.f;}
 	virtual float getDefaultValue() {
 		return 0.f;
 	}
 	/** Returns the value, possibly transformed for displaying
 	Useful for logarithmic scaling, multiplying by 100 for percentages, etc.
 	*/
 	virtual float getDisplayValue() {return getValue();}
 	virtual float getDisplayValue() {
 		return getValue();
 	}
 	/** Inversely transforms the display value and sets the value */
 	virtual void setDisplayValue(float displayValue) {setValue(displayValue);}
 	virtual void setDisplayValue(float displayValue) {
 		setValue(displayValue);
 	}
 	/** The number of total decimal places for generating the display value string
 	*/
@@ -48,12 +60,16 @@ struct Quantity {
 	virtual void setDisplayValueString(std::string s);
 	/** The name of the quantity */
 	virtual std::string getLabel() {return "";}
 	virtual std::string getLabel() {
 		return "";
 	}
 	/** The unit abbreviation of the quantity
 	Include an initial space character if you want a space after the number, e.g. "440 Hz". This allows space-less units, like "100%".
 	*/
 	virtual std::string getUnit() {return "";}
 	virtual std::string getUnit() {
 		return "";
 	}
 	/** Returns a string representation of the quantity */
 	virtual std::string getString();
--- a/include/app.hpp
+++ b/include/app.hpp
@@ -6,12 +6,12 @@ namespace rack {
 namespace history {
 	struct State;
 struct State;
 } // namespace history
 namespace engine {
 	struct Engine;
 struct Engine;
 } // namespace engine
@@ -20,23 +20,23 @@ struct PatchManager;
 namespace event {
 	struct State;
 struct State;
 } // namespace event
 namespace app {
 	struct Scene;
 struct Scene;
 } // namespace app
 /** Contains the application state  */
 struct App {
 	event::State *event = NULL;
 	app::Scene *scene = NULL;
 	engine::Engine *engine = NULL;
 	Window *window = NULL;
 	history::State *history = NULL;
 	PatchManager *patch = NULL;
 	event::State* event = NULL;
 	app::Scene* scene = NULL;
 	engine::Engine* engine = NULL;
 	Window* window = NULL;
 	history::State* history = NULL;
 	PatchManager* patch = NULL;
 	void init();
 	~App();
@@ -46,7 +46,7 @@ struct App {
 void appInit();
 void appDestroy();
 /** Returns the global App pointer */
 App *appGet();
 App* appGet();
 /** Accesses the global App pointer */
 #define APP appGet()
--- a/include/app/AudioWidget.hpp
+++ b/include/app/AudioWidget.hpp
@@ -9,14 +9,14 @@ namespace app {
 struct AudioWidget : LedDisplay {
 	LedDisplayChoice *driverChoice;
 	LedDisplaySeparator *driverSeparator;
 	LedDisplayChoice *deviceChoice;
 	LedDisplaySeparator *deviceSeparator;
 	LedDisplayChoice *sampleRateChoice;
 	LedDisplaySeparator *sampleRateSeparator;
 	LedDisplayChoice *bufferSizeChoice;
 	void setAudioPort(audio::Port *port);
 	LedDisplayChoice* driverChoice;
 	LedDisplaySeparator* driverSeparator;
 	LedDisplayChoice* deviceChoice;
 	LedDisplaySeparator* deviceSeparator;
 	LedDisplayChoice* sampleRateChoice;
 	LedDisplaySeparator* sampleRateSeparator;
 	LedDisplayChoice* bufferSizeChoice;
 	void setAudioPort(audio::Port* port);
 };
--- a/include/app/CableWidget.hpp
+++ b/include/app/CableWidget.hpp
@@ -12,25 +12,25 @@ namespace app {
 struct CableWidget : widget::OpaqueWidget {
 	PortWidget *outputPort = NULL;
 	PortWidget *inputPort = NULL;
 	PortWidget *hoveredOutputPort = NULL;
 	PortWidget *hoveredInputPort = NULL;
 	PortWidget* outputPort = NULL;
 	PortWidget* inputPort = NULL;
 	PortWidget* hoveredOutputPort = NULL;
 	PortWidget* hoveredInputPort = NULL;
 	/** Owned. */
 	engine::Cable *cable;
 	engine::Cable* cable;
 	NVGcolor color;
 	CableWidget();
 	~CableWidget();
 	bool isComplete();
 	void setOutput(PortWidget *outputPort);
 	void setInput(PortWidget *inputPort);
 	void setOutput(PortWidget* outputPort);
 	void setInput(PortWidget* inputPort);
 	math::Vec getOutputPos();
 	math::Vec getInputPos();
 	json_t *toJson();
 	void fromJson(json_t *rootJ);
 	void draw(const DrawArgs &args) override;
 	void drawPlugs(const DrawArgs &args);
 	json_t* toJson();
 	void fromJson(json_t* rootJ);
 	void draw(const DrawArgs& args) override;
 	void drawPlugs(const DrawArgs& args);
 };
--- a/include/app/CircularShadow.hpp
+++ b/include/app/CircularShadow.hpp
@@ -12,7 +12,7 @@ struct CircularShadow : widget::TransparentWidget {
 	float opacity;
 	CircularShadow();
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
--- a/include/app/Knob.hpp
+++ b/include/app/Knob.hpp
@@ -20,11 +20,11 @@ struct Knob : ParamWidget {
 	/** Drag horizontally instead of vertically */
 	bool horizontal = false;
 	void onHover(const event::Hover &e) override;
 	void onButton(const event::Button &e) override;
 	void onDragStart(const event::DragStart &e) override;
 	void onDragEnd(const event::DragEnd &e) override;
 	void onDragMove(const event::DragMove &e) override;
 	void onHover(const event::Hover& e) override;
 	void onButton(const event::Button& e) override;
 	void onDragStart(const event::DragStart& e) override;
 	void onDragEnd(const event::DragEnd& e) override;
 	void onDragMove(const event::DragMove& e) override;
 	void reset() override;
 	void randomize() override;
 };
--- a/include/app/LedDisplay.hpp
+++ b/include/app/LedDisplay.hpp
@@ -10,12 +10,12 @@ namespace app {
 struct LedDisplay : widget::OpaqueWidget {
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
 struct LedDisplaySeparator : widget::Widget {
 	LedDisplaySeparator();
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
 struct LedDisplayChoice : widget::OpaqueWidget {
@@ -25,8 +25,8 @@ struct LedDisplayChoice : widget::OpaqueWidget {
 	NVGcolor color;
 	NVGcolor bgColor;
 	LedDisplayChoice();
 	void draw(const DrawArgs &args) override;
 	void onButton(const event::Button &e) override;
 	void draw(const DrawArgs& args) override;
 	void onButton(const event::Button& e) override;
 };
 struct LedDisplayTextField : ui::TextField {
@@ -34,7 +34,7 @@ struct LedDisplayTextField : ui::TextField {
 	math::Vec textOffset;
 	NVGcolor color;
 	LedDisplayTextField();
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 	int getTextPosition(math::Vec mousePos) override;
 };
--- a/include/app/LightWidget.hpp
+++ b/include/app/LightWidget.hpp
@@ -12,9 +12,9 @@ struct LightWidget : widget::TransparentWidget {
 	NVGcolor color = nvgRGBA(0, 0, 0, 0);
 	NVGcolor borderColor = nvgRGBA(0, 0, 0, 0);
 	void draw(const DrawArgs &args) override;
 	virtual void drawLight(const DrawArgs &args);
 	virtual void drawHalo(const DrawArgs &args);
 	void draw(const DrawArgs& args) override;
 	virtual void drawLight(const DrawArgs& args);
 	virtual void drawHalo(const DrawArgs& args);
 };
--- a/include/app/MenuBar.hpp
+++ b/include/app/MenuBar.hpp
@@ -8,11 +8,11 @@ namespace app {
 struct MenuBar : widget::OpaqueWidget {
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
 MenuBar *createMenuBar();
 MenuBar* createMenuBar();
 } // namespace app
--- a/include/app/MidiWidget.hpp
+++ b/include/app/MidiWidget.hpp
@@ -9,12 +9,12 @@ namespace app {
 struct MidiWidget : LedDisplay {
 	LedDisplayChoice *driverChoice;
 	LedDisplaySeparator *driverSeparator;
 	LedDisplayChoice *deviceChoice;
 	LedDisplaySeparator *deviceSeparator;
 	LedDisplayChoice *channelChoice;
 	void setMidiPort(midi::Port *port);
 	LedDisplayChoice* driverChoice;
 	LedDisplaySeparator* driverSeparator;
 	LedDisplayChoice* deviceChoice;
 	LedDisplaySeparator* deviceSeparator;
 	LedDisplayChoice* channelChoice;
 	void setMidiPort(midi::Port* port);
 };
--- a/include/app/ModuleBrowser.hpp
+++ b/include/app/ModuleBrowser.hpp
@@ -7,7 +7,7 @@ namespace rack {
 namespace app {
 widget::Widget *moduleBrowserCreate();
 widget::Widget* moduleBrowserCreate();
 } // namespace app
--- a/include/app/ModuleLightWidget.hpp
+++ b/include/app/ModuleLightWidget.hpp
@@ -12,7 +12,7 @@ namespace app {
 Will access firstLightId, firstLightId + 1, etc. for each added color
 */
 struct ModuleLightWidget : MultiLightWidget {
 	engine::Module *module = NULL;
 	engine::Module* module = NULL;
 	int firstLightId;
 	void step() override;
--- a/include/app/ModuleWidget.hpp
+++ b/include/app/ModuleWidget.hpp
@@ -14,11 +14,11 @@ namespace app {
 /** Manages an engine::Module in the rack. */
 struct ModuleWidget : widget::OpaqueWidget {
 	plugin::Model *model = NULL;
 	plugin::Model* model = NULL;
 	/** Owned. */
 	engine::Module *module = NULL;
 	engine::Module* module = NULL;
 	widget::Widget *panel = NULL;
 	widget::Widget* panel = NULL;
 	/** Note that the indexes of these vectors do not necessarily correspond with the indexes of `Module::params` etc.
 	*/
 	std::vector<ParamWidget*> params;
@@ -29,39 +29,39 @@ struct ModuleWidget : widget::OpaqueWidget {
 	math::Vec oldPos;
 	ModuleWidget();
 	DEPRECATED ModuleWidget(engine::Module *module) : ModuleWidget() {
 	DEPRECATED ModuleWidget(engine::Module* module) : ModuleWidget() {
 		setModule(module);
 	}
 	~ModuleWidget();
 	void draw(const DrawArgs &args) override;
 	void drawShadow(const DrawArgs &args);
 	void draw(const DrawArgs& args) override;
 	void drawShadow(const DrawArgs& args);
 	void onButton(const event::Button &e) override;
 	void onHoverKey(const event::HoverKey &e) override;
 	void onDragStart(const event::DragStart &e) override;
 	void onDragEnd(const event::DragEnd &e) override;
 	void onDragMove(const event::DragMove &e) override;
 	void onButton(const event::Button& e) override;
 	void onHoverKey(const event::HoverKey& e) override;
 	void onDragStart(const event::DragStart& e) override;
 	void onDragEnd(const event::DragEnd& e) override;
 	void onDragMove(const event::DragMove& e) override;
 	/** Associates this ModuleWidget with the Module
 	Transfers ownership
 	*/
 	void setModule(engine::Module *module);
 	void setModule(engine::Module* module);
 	void setPanel(std::shared_ptr<Svg> svg);
 	/** Convenience functions for adding special widgets (calls addChild()) */
 	void addParam(ParamWidget *param);
 	void addOutput(PortWidget *output);
 	void addInput(PortWidget *input);
 	ParamWidget *getParam(int paramId);
 	PortWidget *getOutput(int outputId);
 	PortWidget *getInput(int inputId);
 	void addParam(ParamWidget* param);
 	void addOutput(PortWidget* output);
 	void addInput(PortWidget* input);
 	ParamWidget* getParam(int paramId);
 	PortWidget* getOutput(int outputId);
 	PortWidget* getInput(int inputId);
 	/** Overriding these is deprecated.
 	Use Module::dataToJson() and dataFromJson() instead
 	*/
 	virtual json_t *toJson();
 	virtual void fromJson(json_t *rootJ);
 	virtual json_t* toJson();
 	virtual void fromJson(json_t* rootJ);
 	/** Serializes/unserializes the module state */
 	void copyClipboard();
@@ -93,7 +93,7 @@ struct ModuleWidget : widget::OpaqueWidget {
 	/** Override to add context menu entries to your subclass.
 	It is recommended to add a blank ui::MenuEntry first for spacing.
 	*/
 	virtual void appendContextMenu(ui::Menu *menu) {}
 	virtual void appendContextMenu(ui::Menu* menu) {}
 };
--- a/include/app/MultiLightWidget.hpp
+++ b/include/app/MultiLightWidget.hpp
@@ -14,7 +14,7 @@ struct MultiLightWidget : LightWidget {
 	void addBaseColor(NVGcolor baseColor);
 	/** Sets the color to a linear combination of the baseColors with the given weights */
 	void setBrightnesses(const std::vector<float> &brightnesses);
 	void setBrightnesses(const std::vector<float>& brightnesses);
 };
--- a/include/app/ParamWidget.hpp
+++ b/include/app/ParamWidget.hpp
@@ -12,20 +12,20 @@ namespace app {
 /** Manages an engine::Param on a ModuleWidget. */
 struct ParamWidget : widget::OpaqueWidget {
 	engine::ParamQuantity *paramQuantity = NULL;
 	engine::ParamQuantity* paramQuantity = NULL;
 	float dirtyValue = NAN;
 	ui::Tooltip *tooltip = NULL;
 	ui::Tooltip* tooltip = NULL;
 	void step() override;
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 	void onButton(const event::Button &e) override;
 	void onDoubleClick(const event::DoubleClick &e) override;
 	void onEnter(const event::Enter &e) override;
 	void onLeave(const event::Leave &e) override;
 	void onButton(const event::Button& e) override;
 	void onDoubleClick(const event::DoubleClick& e) override;
 	void onEnter(const event::Enter& e) override;
 	void onLeave(const event::Leave& e) override;
 	/** For legacy patch loading */
 	void fromJson(json_t *rootJ);
 	void fromJson(json_t* rootJ);
 	void createContextMenu();
 	void resetAction();
 	virtual void reset() {}
--- a/include/app/PortWidget.hpp
+++ b/include/app/PortWidget.hpp
@@ -11,7 +11,7 @@ namespace app {
 /** Manages an engine::Port on a ModuleWidget. */
 struct PortWidget : widget::OpaqueWidget {
 	engine::Module *module = NULL;
 	engine::Module* module = NULL;
 	int portId;
 	bool hovered = false;
@@ -20,22 +20,22 @@ struct PortWidget : widget::OpaqueWidget {
 		INPUT
 	};
 	Type type;
 	MultiLightWidget *plugLight;
 	MultiLightWidget* plugLight;
 	PortWidget();
 	~PortWidget();
 	void step() override;
 	void draw(const DrawArgs &args) override;
 	void onButton(const event::Button &e) override;
 	void onEnter(const event::Enter &e) override;
 	void onLeave(const event::Leave &e) override;
 	void onDragStart(const event::DragStart &e) override;
 	void onDragEnd(const event::DragEnd &e) override;
 	void onDragDrop(const event::DragDrop &e) override;
 	void onDragEnter(const event::DragEnter &e) override;
 	void onDragLeave(const event::DragLeave &e) override;
 	void draw(const DrawArgs& args) override;
 	void onButton(const event::Button& e) override;
 	void onEnter(const event::Enter& e) override;
 	void onLeave(const event::Leave& e) override;
 	void onDragStart(const event::DragStart& e) override;
 	void onDragEnd(const event::DragEnd& e) override;
 	void onDragDrop(const event::DragDrop& e) override;
 	void onDragEnter(const event::DragEnter& e) override;
 	void onDragLeave(const event::DragLeave& e) override;
 };
--- a/include/app/RackRail.hpp
+++ b/include/app/RackRail.hpp
@@ -11,7 +11,7 @@ struct RackRail : widget::TransparentWidget {
 	std::shared_ptr<Svg> busBoardSvg;
 	RackRail();
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
--- a/include/app/RackScrollWidget.hpp
+++ b/include/app/RackScrollWidget.hpp
@@ -10,17 +10,17 @@ namespace app {
 struct RackScrollWidget : ui::ScrollWidget {
 	widget::ZoomWidget *zoomWidget;
 	RackWidget *rackWidget;
 	widget::ZoomWidget* zoomWidget;
 	RackWidget* rackWidget;
 	/** The pivot point for zooming */
 	math::Vec zoomPos;
 	math::Vec oldOffset;
 	RackScrollWidget();
 	void step() override;
 	void draw(const DrawArgs &args) override;
 	void onHoverKey(const event::HoverKey &e) override;
 	void onHoverScroll(const event::HoverScroll &e) override;
 	void draw(const DrawArgs& args) override;
 	void onHoverKey(const event::HoverKey& e) override;
 	void onHoverScroll(const event::HoverScroll& e) override;
 	void reset();
 };
--- a/include/app/RackWidget.hpp
+++ b/include/app/RackWidget.hpp
@@ -16,13 +16,13 @@ namespace app {
 /** Container for ModuleWidget and CableWidget. */
 struct RackWidget : widget::OpaqueWidget {
 	widget::Widget *moduleContainer;
 	widget::Widget *cableContainer;
 	CableWidget *incompleteCable = NULL;
 	widget::FramebufferWidget *railFb;
 	widget::Widget* moduleContainer;
 	widget::Widget* cableContainer;
 	CableWidget* incompleteCable = NULL;
 	widget::FramebufferWidget* railFb;
 	/** The last mouse position in the RackWidget */
 	math::Vec mousePos;
 	ParamWidget *touchedParam = NULL;
 	ParamWidget* touchedParam = NULL;
 	std::map<int, math::Vec> moduleDragPositions;
 	int nextCableColorId = 0;
@@ -30,17 +30,17 @@ struct RackWidget : widget::OpaqueWidget {
 	~RackWidget();
 	void step() override;
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 	void onHover(const event::Hover &e) override;
 	void onHoverKey(const event::HoverKey &e) override;
 	void onDragHover(const event::DragHover &e) override;
 	void onButton(const event::Button &e) override;
 	void onHover(const event::Hover& e) override;
 	void onHoverKey(const event::HoverKey& e) override;
 	void onDragHover(const event::DragHover& e) override;
 	void onButton(const event::Button& e) override;
 	/** Completely clear the rack's modules and cables */
 	void clear();
 	json_t *toJson();
 	void fromJson(json_t *rootJ);
 	json_t* toJson();
 	void fromJson(json_t* rootJ);
 	void pastePresetClipboardAction();
 	// Module methods
@@ -48,39 +48,39 @@ struct RackWidget : widget::OpaqueWidget {
 	/** Adds a module and adds it to the Engine
 	Ownership rules work like add/removeChild()
 	*/
 	void addModule(ModuleWidget *mw);
 	void addModuleAtMouse(ModuleWidget *mw);
 	void addModule(ModuleWidget* mw);
 	void addModuleAtMouse(ModuleWidget* mw);
 	/** Removes the module and transfers ownership to the caller */
 	void removeModule(ModuleWidget *mw);
 	void removeModule(ModuleWidget* mw);
 	/** Sets a module's box if non-colliding. Returns true if set */
 	bool requestModulePos(ModuleWidget *mw, math::Vec pos);
 	bool requestModulePos(ModuleWidget* mw, math::Vec pos);
 	/** Moves a module to the closest non-colliding position */
 	void setModulePosNearest(ModuleWidget *mw, math::Vec pos);
 	void setModulePosForce(ModuleWidget *mw, math::Vec pos);
 	ModuleWidget *getModule(int moduleId);
 	void setModulePosNearest(ModuleWidget* mw, math::Vec pos);
 	void setModulePosForce(ModuleWidget* mw, math::Vec pos);
 	ModuleWidget* getModule(int moduleId);
 	bool isEmpty();
 	void updateModuleDragPositions();
 	history::ComplexAction *getModuleDragAction();
 	history::ComplexAction* getModuleDragAction();
 	// Cable methods
 	void clearCables();
 	void clearCablesAction();
 	/** Removes all complete cables connected to the port */
 	void clearCablesOnPort(PortWidget *port);
 	void clearCablesOnPort(PortWidget* port);
 	/** Adds a complete cable and adds it to the Engine.
 	Ownership rules work like add/removeChild()
 	*/
 	void addCable(CableWidget *w);
 	void removeCable(CableWidget *w);
 	void addCable(CableWidget* w);
 	void removeCable(CableWidget* w);
 	/** Takes ownership of `w` and adds it as a child if it isn't already */
 	void setIncompleteCable(CableWidget *w);
 	CableWidget *releaseIncompleteCable();
 	void setIncompleteCable(CableWidget* w);
 	CableWidget* releaseIncompleteCable();
 	/** Returns the most recently added complete cable connected to the given Port, i.e. the top of the stack */
 	CableWidget *getTopCable(PortWidget *port);
 	CableWidget *getCable(int cableId);
 	CableWidget* getTopCable(PortWidget* port);
 	CableWidget* getCable(int cableId);
 	/** Returns all cables attached to port, complete or not */
 	std::list<CableWidget*> getCablesOnPort(PortWidget *port);
 	std::list<CableWidget*> getCablesOnPort(PortWidget* port);
 };
--- a/include/app/Scene.hpp
+++ b/include/app/Scene.hpp
@@ -12,10 +12,10 @@ namespace app {
 struct Scene : widget::OpaqueWidget {
 	// Convenience variables for accessing important widgets
 	RackScrollWidget *rackScroll;
 	RackWidget *rack;
 	MenuBar *menuBar;
 	widget::Widget *moduleBrowser;
 	RackScrollWidget* rackScroll;
 	RackWidget* rack;
 	MenuBar* menuBar;
 	widget::Widget* moduleBrowser;
 	double lastAutosaveTime = 0.0;
@@ -27,9 +27,9 @@ struct Scene : widget::OpaqueWidget {
 	Scene();
 	~Scene();
 	void step() override;
 	void draw(const DrawArgs &args) override;
 	void onHoverKey(const event::HoverKey &e) override;
 	void onPathDrop(const event::PathDrop &e) override;
 	void draw(const DrawArgs& args) override;
 	void onHoverKey(const event::HoverKey& e) override;
 	void onPathDrop(const event::PathDrop& e) override;
 	void runCheckVersion();
 };
--- a/include/app/SliderKnob.hpp
+++ b/include/app/SliderKnob.hpp
@@ -9,10 +9,10 @@ namespace app {
 struct SliderKnob : Knob {
 	// Bypass Knob's circular hitbox detection
 	void onHover(const event::Hover &e) override {
 	void onHover(const event::Hover& e) override {
 		ParamWidget::onHover(e);
 	}
 	void onButton(const event::Button &e) override {
 	void onButton(const event::Button& e) override {
 		ParamWidget::onButton(e);
 	}
 };
--- a/include/app/SvgButton.hpp
+++ b/include/app/SvgButton.hpp
@@ -11,16 +11,16 @@ namespace app {
 struct SvgButton : widget::OpaqueWidget {
 	widget::FramebufferWidget *fb;
 	CircularShadow *shadow;
 	widget::SvgWidget *sw;
 	widget::FramebufferWidget* fb;
 	CircularShadow* shadow;
 	widget::SvgWidget* sw;
 	std::vector<std::shared_ptr<Svg>> frames;
 	SvgButton();
 	void addFrame(std::shared_ptr<Svg> svg);
 	void onDragStart(const event::DragStart &e) override;
 	void onDragEnd(const event::DragEnd &e) override;
 	void onDragDrop(const event::DragDrop &e) override;
 	void onDragStart(const event::DragStart& e) override;
 	void onDragEnd(const event::DragEnd& e) override;
 	void onDragDrop(const event::DragDrop& e) override;
 };
--- a/include/app/SvgKnob.hpp
+++ b/include/app/SvgKnob.hpp
@@ -13,18 +13,20 @@ namespace app {
 /** A knob which rotates an SVG and caches it in a framebuffer */
 struct SvgKnob : Knob {
 	widget::FramebufferWidget *fb;
 	CircularShadow *shadow;
 	widget::TransformWidget *tw;
 	widget::SvgWidget *sw;
 	widget::FramebufferWidget* fb;
 	CircularShadow* shadow;
 	widget::TransformWidget* tw;
 	widget::SvgWidget* sw;
 	/** Angles in radians */
 	float minAngle = 0.f;
 	float maxAngle = M_PI;
 	SvgKnob();
 	void setSvg(std::shared_ptr<Svg> svg);
 	DEPRECATED void setSVG(std::shared_ptr<Svg> svg) {setSvg(svg);}
 	void onChange(const event::Change &e) override;
 	DEPRECATED void setSVG(std::shared_ptr<Svg> svg) {
 		setSvg(svg);
 	}
 	void onChange(const event::Change& e) override;
 };
--- a/include/app/SvgPanel.hpp
+++ b/include/app/SvgPanel.hpp
@@ -11,7 +11,7 @@ namespace app {
 struct PanelBorder : widget::TransparentWidget {
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
--- a/include/app/SvgPort.hpp
+++ b/include/app/SvgPort.hpp
@@ -11,13 +11,15 @@ namespace app {
 struct SvgPort : PortWidget {
 	widget::FramebufferWidget *fb;
 	CircularShadow *shadow;
 	widget::SvgWidget *sw;
 	widget::FramebufferWidget* fb;
 	CircularShadow* shadow;
 	widget::SvgWidget* sw;
 	SvgPort();
 	void setSvg(std::shared_ptr<Svg> svg);
 	DEPRECATED void setSVG(std::shared_ptr<Svg> svg) {setSvg(svg);}
 	DEPRECATED void setSVG(std::shared_ptr<Svg> svg) {
 		setSvg(svg);
 	}
 };
--- a/include/app/SvgScrew.hpp
+++ b/include/app/SvgScrew.hpp
@@ -11,8 +11,8 @@ namespace app {
 /** If you don't add these to your ModuleWidget, they will fall out of the rack... */
 struct SvgScrew : widget::Widget {
 	widget::FramebufferWidget *fb;
 	widget::SvgWidget *sw;
 	widget::FramebufferWidget* fb;
 	widget::SvgWidget* sw;
 	SvgScrew();
 	void setSvg(std::shared_ptr<Svg> svg);
--- a/include/app/SvgSlider.hpp
+++ b/include/app/SvgSlider.hpp
@@ -13,19 +13,23 @@ namespace app {
 Can be used for horizontal or vertical linear faders.
 */
 struct SvgSlider : app::SliderKnob {
 	widget::FramebufferWidget *fb;
 	widget::SvgWidget *background;
 	widget::SvgWidget *handle;
 	widget::FramebufferWidget* fb;
 	widget::SvgWidget* background;
 	widget::SvgWidget* handle;
 	/** Intermediate positions will be interpolated between these positions */
 	math::Vec minHandlePos, maxHandlePos;
 	SvgSlider();
 	void setBackgroundSvg(std::shared_ptr<Svg> svg);
 	void setHandleSvg(std::shared_ptr<Svg> svg);
 	void onChange(const event::Change &e) override;
 	void onChange(const event::Change& e) override;
 	DEPRECATED void setBackgroundSVG(std::shared_ptr<Svg> svg) {setBackgroundSvg(svg);}
 	DEPRECATED void setHandleSVG(std::shared_ptr<Svg> svg) {setBackgroundSvg(svg);}
 	DEPRECATED void setBackgroundSVG(std::shared_ptr<Svg> svg) {
 		setBackgroundSvg(svg);
 	}
 	DEPRECATED void setHandleSVG(std::shared_ptr<Svg> svg) {
 		setBackgroundSvg(svg);
 	}
 	DEPRECATED void setSVGs(std::shared_ptr<Svg> backgroundSvg, std::shared_ptr<Svg> handleSvg) {
 		setBackgroundSvg(backgroundSvg);
 		setHandleSvg(handleSvg);
--- a/include/app/SvgSwitch.hpp
+++ b/include/app/SvgSwitch.hpp
@@ -12,15 +12,15 @@ namespace app {
 /** A ParamWidget with multiple frames corresponding to its value */
 struct SvgSwitch : Switch {
 	widget::FramebufferWidget *fb;
 	CircularShadow *shadow;
 	widget::SvgWidget *sw;
 	widget::FramebufferWidget* fb;
 	CircularShadow* shadow;
 	widget::SvgWidget* sw;
 	std::vector<std::shared_ptr<Svg>> frames;
 	SvgSwitch();
 	/** Adds an SVG file to represent the next switch position */
 	void addFrame(std::shared_ptr<Svg> svg);
 	void onChange(const event::Change &e) override;
 	void onChange(const event::Change& e) override;
 };
--- a/include/app/Switch.hpp
+++ b/include/app/Switch.hpp
@@ -20,9 +20,9 @@ struct Switch : ParamWidget {
 	bool momentaryReleased = false;
 	void step() override;
 	void onDoubleClick(const event::DoubleClick &e) override;
 	void onDragStart(const event::DragStart &e) override;
 	void onDragEnd(const event::DragEnd &e) override;
 	void onDoubleClick(const event::DoubleClick& e) override;
 	void onDragStart(const event::DragStart& e) override;
 	void onDragEnd(const event::DragEnd& e) override;
 	void reset() override;
 	void randomize() override;
 };
--- a/include/asset.hpp
+++ b/include/asset.hpp
@@ -6,7 +6,7 @@ namespace rack {
 namespace plugin {
 	struct Plugin;
 struct Plugin;
 } // namespace plugin
@@ -19,7 +19,7 @@ std::string system(std::string filename);
 /** Returns the path of a user resource. Can read and write files to this location. */
 std::string user(std::string filename);
 /** Returns the path of a resource in the plugin's folder. Should only read files from this location. */
 std::string plugin(plugin::Plugin *plugin, std::string filename);
 std::string plugin(plugin::Plugin* plugin, std::string filename);
 // Set these before calling init() to override the default paths
--- a/include/audio.hpp
+++ b/include/audio.hpp
@@ -4,7 +4,7 @@
 #pragma GCC diagnostic push
 #ifndef __clang__
 #pragma GCC diagnostic ignored "-Wsuggest-override"
 	#pragma GCC diagnostic ignored "-Wsuggest-override"
 #endif
 #include <RtAudio.h>
 #pragma GCC diagnostic pop
@@ -28,7 +28,7 @@ struct Port {
 	int blockSize = 256;
 	int numOutputs = 0;
 	int numInputs = 0;
 	RtAudio *rtAudio = NULL;
 	RtAudio* rtAudio = NULL;
 	/** Cached */
 	RtAudio::DeviceInfo deviceInfo;
@@ -40,7 +40,7 @@ struct Port {
 	void setDriverId(int driverId);
 	int getDeviceCount();
 	bool getDeviceInfo(int deviceId, RtAudio::DeviceInfo *deviceInfo);
 	bool getDeviceInfo(int deviceId, RtAudio::DeviceInfo* deviceInfo);
 	/** Returns the number of inputs or outputs, whichever is greater */
 	int getDeviceChannels(int deviceId);
 	std::string getDeviceName(int deviceId);
@@ -58,12 +58,12 @@ struct Port {
 	void openStream();
 	void closeStream();
 	virtual void processStream(const float *input, float *output, int frames) {}
 	virtual void processStream(const float* input, float* output, int frames) {}
 	virtual void onCloseStream() {}
 	virtual void onOpenStream() {}
 	virtual void onChannelsChange() {}
 	json_t *toJson();
 	void fromJson(json_t *rootJ);
 	json_t* toJson();
 	void fromJson(json_t* rootJ);
 };
--- a/include/bridge.hpp
+++ b/include/bridge.hpp
@@ -8,8 +8,8 @@ namespace rack {
 void bridgeInit();
 void bridgeDestroy();
 void bridgeAudioSubscribe(int channel, audio::Port *port);
 void bridgeAudioUnsubscribe(int channel, audio::Port *port);
 void bridgeAudioSubscribe(int channel, audio::Port* port);
 void bridgeAudioUnsubscribe(int channel, audio::Port* port);
 } // namespace rack
--- a/include/common.hpp
+++ b/include/common.hpp
@@ -120,13 +120,13 @@ Example:
 	Foo *foo = construct<Foo>(&Foo::greeting, "Hello world", &Foo::legs, 2);
 */
 template <typename T>
 T *construct() {
 T* construct() {
 	return new T;
 }
 template <typename T, typename F, typename V, typename... Args>
 T *construct(F f, V v, Args... args) {
 	T *o = construct<T>(args...);
 T* construct(F f, V v, Args... args) {
 	T* o = construct<T>(args...);
 	o->*f = v;
 	return o;
 }
@@ -144,7 +144,9 @@ template <typename F>
 struct DeferWrapper {
 	F f;
 	DeferWrapper(F f) : f(f) {}
 	~DeferWrapper() { f(); }
 	~DeferWrapper() {
 		f();
 	}
 };
 template <typename F>
@@ -157,7 +159,7 @@ DeferWrapper<F> deferWrapper(F f) {
 /** An exception meant to be shown to the user */
 struct UserException : std::runtime_error {
 	UserException(const std::string &msg) : std::runtime_error(msg) {}
 	UserException(const std::string& msg) : std::runtime_error(msg) {}
 };
--- a/include/componentlibrary.hpp
+++ b/include/componentlibrary.hpp
@@ -45,8 +45,8 @@ static const NVGcolor SCHEME_DARK_GRAY = nvgRGB(0x17, 0x17, 0x17);
 struct RoundKnob : app::SvgKnob {
 	RoundKnob() {
 		minAngle = -0.83*M_PI;
 		maxAngle = 0.83*M_PI;
 		minAngle = -0.83 * M_PI;
 		maxAngle = 0.83 * M_PI;
 	}
 };
@@ -83,8 +83,8 @@ struct RoundBlackSnapKnob : RoundBlackKnob {
 struct Davies1900hKnob : app::SvgKnob {
 	Davies1900hKnob() {
 		minAngle = -0.83*M_PI;
 		maxAngle = 0.83*M_PI;
 		minAngle = -0.83 * M_PI;
 		maxAngle = 0.83 * M_PI;
 	}
 };
@@ -127,8 +127,8 @@ struct Davies1900hLargeRedKnob : Davies1900hKnob {
 struct Rogan : app::SvgKnob {
 	Rogan() {
 		minAngle = -0.83*M_PI;
 		maxAngle = 0.83*M_PI;
 		minAngle = -0.83 * M_PI;
 		maxAngle = 0.83 * M_PI;
 	}
 };
@@ -297,12 +297,12 @@ struct Rogan1PWhite : Rogan {
 struct SynthTechAlco : app::SvgKnob {
 	SynthTechAlco() {
 		minAngle = -0.82*M_PI;
 		maxAngle = 0.82*M_PI;
 		minAngle = -0.82 * M_PI;
 		maxAngle = 0.82 * M_PI;
 		setSvg(APP->window->loadSvg(asset::system("res/ComponentLibrary/SynthTechAlco.svg")));
 		// Add cap
 		widget::FramebufferWidget *capFb = new widget::FramebufferWidget;
 		widget::SvgWidget *cap = new widget::SvgWidget;
 		widget::FramebufferWidget* capFb = new widget::FramebufferWidget;
 		widget::SvgWidget* cap = new widget::SvgWidget;
 		cap->setSvg(APP->window->loadSvg(asset::system("res/ComponentLibrary/SynthTechAlco_cap.svg")));
 		capFb->addChild(cap);
 		addChild(capFb);
@@ -311,16 +311,16 @@ struct SynthTechAlco : app::SvgKnob {
 struct Trimpot : app::SvgKnob {
 	Trimpot() {
 		minAngle = -0.75*M_PI;
 		maxAngle = 0.75*M_PI;
 		minAngle = -0.75 * M_PI;
 		maxAngle = 0.75 * M_PI;
 		setSvg(APP->window->loadSvg(asset::system("res/ComponentLibrary/Trimpot.svg")));
 	}
 };
 struct BefacoBigKnob : app::SvgKnob {
 	BefacoBigKnob() {
 		minAngle = -0.75*M_PI;
 		maxAngle = 0.75*M_PI;
 		minAngle = -0.75 * M_PI;
 		maxAngle = 0.75 * M_PI;
 		setSvg(APP->window->loadSvg(asset::system("res/ComponentLibrary/BefacoBigKnob.svg")));
 	}
 };
@@ -333,8 +333,8 @@ struct BefacoBigSnapKnob : BefacoBigKnob {
 struct BefacoTinyKnob : app::SvgKnob {
 	BefacoTinyKnob() {
 		minAngle = -0.75*M_PI;
 		maxAngle = 0.75*M_PI;
 		minAngle = -0.75 * M_PI;
 		maxAngle = 0.75 * M_PI;
 		setSvg(APP->window->loadSvg(asset::system("res/ComponentLibrary/BefacoTinyKnob.svg")));
 	}
 };
--- a/include/dsp/approx.hpp
+++ b/include/dsp/approx.hpp
@@ -0,0 +1,70 @@
 #pragma once
 #include <dsp/common.hpp>
 namespace rack {
 namespace dsp {
 /*
 In this header, function names are divided into two or more parts, separated by "_".
 The functionality is the first part, and the approximation methods are the following parts.
 Glossary:
 https://en.wikipedia.org/wiki/Taylor_series
 https://en.wikipedia.org/wiki/Chebyshev_polynomials
 https://en.wikipedia.org/wiki/Pad%C3%A9_approximant
 https://en.wikipedia.org/wiki/Horner%27s_method
 https://en.wikipedia.org/wiki/Estrin%27s_scheme
 https://en.wikipedia.org/wiki/CORDIC
 */
 /** Returns 2^floor(x), assuming that x >= 0.
 If `xf` is non-NULL, it is set to the fractional part of x.
 */
 template <typename T>
 T approxExp2Floor(T x, T* xf);
 template <>
 inline simd::float_4 approxExp2Floor(simd::float_4 x, simd::float_4* xf) {
 	simd::int32_4 xi = x;
 	if (xf)
 		*xf = x - simd::float_4(xi);
 	// Set float exponent directly
 	// https://stackoverflow.com/a/57454528/272642
 	simd::int32_4 y = (xi + 127) << 23;
 	return simd::float_4::cast(y);
 }
 template <>
 inline float approxExp2Floor(float x, float* xf) {
 	int xi = x;
 	if (xf)
 		*xf = x - xi;
 	return 1 << xi;
 }
 /** Returns 2^x, assuming that x >= 0.
 Maximum 0.00024% error.
 For float, roughly 3x faster than `std::pow(2.f, x)`.
 For float_4, roughly 2x faster than `simd::pow(2.f, x)`.
 If negative powers are needed, you may use a lower bound and rescale.
 	approxExp2(x + 20) / 1048576
 */
 template <typename T>
 T approxExp2_taylor5(T x) {
 	// Use bit-shifting for integer part of x.
 	T y = approxExp2Floor(x, &x);
 	// 5th order expansion of 2^x around 0.4752 in Horner form.
 	// The center is chosen so that the endpoints of [0, 1] have equal error, creating no discontinuity at integers.
 	y *= T(0.9999976457798443) + x * (T(0.6931766804601935) + x * (T(0.2400729486415728) + x * (T(0.05592817518644387) + x * (T(0.008966320633544) + x * T(0.001853512473884202)))));
 	return y;
 }
 } // namespace dsp
 } // namespace rack
--- a/include/dsp/common.hpp
+++ b/include/dsp/common.hpp
@@ -53,23 +53,23 @@ T dbToAmplitude(T db) {
 template <typename T>
 T quadraticBipolar(T x) {
 	return simd::sgn(x) * (x*x);
 	return simd::sgn(x) * (x * x);
 }
 template <typename T>
 T cubic(T x) {
 	return x*x*x;
 	return x * x * x;
 }
 template <typename T>
 T quarticBipolar(T x) {
 	return simd::sgn(x) * (x*x*x*x);
 	return simd::sgn(x) * (x * x * x * x);
 }
 template <typename T>
 T quintic(T x) {
 	// optimal with -fassociative-math
 	return x*x*x*x*x;
 	return x * x * x * x * x;
 }
 template <typename T>
--- a/include/dsp/digital.hpp
+++ b/include/dsp/digital.hpp
@@ -23,7 +23,27 @@ struct BooleanTrigger {
 /** Turns HIGH when value reaches 1.f, turns LOW when value reaches 0.f. */
 struct SchmittTrigger {
 template <typename T = float>
 struct TSchmittTrigger {
 	T state;
 	TSchmittTrigger() {
 		reset();
 	}
 	void reset() {
 		state = T::mask();
 	}
 	T process(T in) {
 		T on = (in >= 1.f);
 		T off = (in <= 0.f);
 		T triggered = ~state & on;
 		state = on | (state & ~off);
 		return triggered;
 	}
 };
 template <>
 struct TSchmittTrigger<float> {
 	bool state = true;
 	void reset() {
@@ -60,24 +80,7 @@ struct SchmittTrigger {
 	}
 };
 template <typename T>
 struct TSchmittTrigger {
 	T state;
 	TSchmittTrigger() {
 		reset();
 	}
 	void reset() {
 		state = T::mask();
 	}
 	T process(T in) {
 		T on = (in >= 1.f);
 		T off = (in <= 0.f);
 		T triggered = ~state & on;
 		state = on | (state & ~off);
 		return triggered;
 	}
 };
 typedef TSchmittTrigger<> SchmittTrigger;
 /** When triggered, holds a high value for a specified time before going low again */
--- a/include/dsp/fft.hpp
+++ b/include/dsp/fft.hpp
@@ -13,7 +13,7 @@ Wrapper for [PFFFT](https://bitbucket.org/jpommier/pffft/)
 Buffers must be aligned to 16-byte boundaries. new[] and malloc() do this for you.
 */
 struct RealFFT {
 	PFFFT_Setup *setup;
 	PFFFT_Setup* setup;
 	int length;
 	RealFFT(size_t length) {
@@ -31,7 +31,7 @@ struct RealFFT {
 	Output is arbitrarily ordered for performance reasons.
 	However, this ordering is consistent, so element-wise multiplication with line up with other results, and the inverse FFT will return a correctly ordered result.
 	*/
 	void rfftUnordered(const float *input, float *output) {
 	void rfftUnordered(const float* input, float* output) {
 		pffft_transform(setup, input, output, NULL, PFFFT_FORWARD);
 	}
@@ -39,7 +39,7 @@ struct RealFFT {
 	Input is `2*length` elements. Output is `length` elements.
 	Scaling is such that IRFFT(RFFT(x)) = N*x.
 	*/
 	void irfftUnordered(const float *input, float *output) {
 	void irfftUnordered(const float* input, float* output) {
 		pffft_transform(setup, input, output, NULL, PFFFT_BACKWARD);
 	}
@@ -54,17 +54,17 @@ struct RealFFT {
 		output[length - 2] = real(F(n/2 - 1))
 		output[length - 1] = imag(F(n/2 - 1))
 	*/
 	void rfft(const float *input, float *output) {
 	void rfft(const float* input, float* output) {
 		pffft_transform_ordered(setup, input, output, NULL, PFFFT_FORWARD);
 	}
 	void irfft(const float *input, float *output) {
 	void irfft(const float* input, float* output) {
 		pffft_transform_ordered(setup, input, output, NULL, PFFFT_BACKWARD);
 	}
 	/** Scales the RFFT so that `scale(IFFT(FFT(x))) = x`.
 	*/
 	void scale(float *x) {
 	void scale(float* x) {
 		float a = 1.f / length;
 		for (int i = 0; i < length; i++) {
 			x[i] *= a;
@@ -77,7 +77,7 @@ struct RealFFT {
 `length` must be a multiple of 16.
 */
 struct ComplexFFT {
 	PFFFT_Setup *setup;
 	PFFFT_Setup* setup;
 	int length;
 	ComplexFFT(size_t length) {
@@ -93,7 +93,7 @@ struct ComplexFFT {
 	Input and output must be aligned using the above align*() functions.
 	Input is `2*length` elements. Output is `2*length` elements.
 	*/
 	void fftUnordered(const float *input, float *output) {
 	void fftUnordered(const float* input, float* output) {
 		pffft_transform(setup, input, output, NULL, PFFFT_FORWARD);
 	}
@@ -101,23 +101,23 @@ struct ComplexFFT {
 	Input is `2*length` elements. Output is `2*length` elements.
 	Scaling is such that FFT(IFFT(x)) = N*x.
 	*/
 	void ifftUnordered(const float *input, float *output) {
 	void ifftUnordered(const float* input, float* output) {
 		pffft_transform(setup, input, output, NULL, PFFFT_BACKWARD);
 	}
 	void fft(const float *input, float *output) {
 	void fft(const float* input, float* output) {
 		pffft_transform_ordered(setup, input, output, NULL, PFFFT_FORWARD);
 	}
 	void ifft(const float *input, float *output) {
 	void ifft(const float* input, float* output) {
 		pffft_transform_ordered(setup, input, output, NULL, PFFFT_BACKWARD);
 	}
 	void scale(float *x) {
 	void scale(float* x) {
 		float a = 1.f / length;
 		for (int i = 0; i < length; i++) {
 			x[2*i+0] *= a;
 			x[2*i+1] *= a;
 			x[2 * i + 0] *= a;
 			x[2 * i + 1] *= a;
 		}
 	}
 };
--- a/include/dsp/filter.hpp
+++ b/include/dsp/filter.hpp
@@ -68,6 +68,10 @@ struct TExponentialFilter {
 		this->lambda = lambda;
 	}
 	void setTau(T tau) {
 		this->lambda = 1 / tau;
 	}
 	T process(T deltaTime, T in) {
 		T y = out + (in - out) * lambda * deltaTime;
 		// If no change was made between the old and new output, assume T granularity is too small and snap output to input
@@ -98,6 +102,10 @@ struct TPeakFilter {
 		this->lambda = lambda;
 	}
 	void setTau(T tau) {
 		this->lambda = 1 / tau;
 	}
 	T process(T deltaTime, T in) {
 		T y = out + (in - out) * lambda * deltaTime;
 		out = simd::fmax(y, in);
@@ -174,5 +182,207 @@ struct TExponentialSlewLimiter {
 typedef TExponentialSlewLimiter<> ExponentialSlewLimiter;
 template <typename T = float>
 struct TBiquadFilter {
 	/** input state */
 	T x[2];
 	/** output state */
 	T y[2];
 	/** transfer function numerator coefficients: b_0, b_1, b_2 */
 	float b[3];
 	/** transfer function denominator coefficients: a_1, a_2
 	a_0 is fixed to 1.
 	*/
 	float a[2];
 	enum Type {
 		LOWPASS_1POLE,
 		HIGHPASS_1POLE,
 		LOWPASS,
 		HIGHPASS,
 		LOWSHELF,
 		HIGHSHELF,
 		BANDPASS,
 		PEAK,
 		NOTCH,
 		NUM_TYPES
 	};
 	TBiquadFilter() {
 		reset();
 		setParameters(LOWPASS, 0.f, 0.f, 1.f);
 	}
 	void reset() {
 		std::memset(x, 0, sizeof(x));
 		std::memset(y, 0, sizeof(y));
 	}
 	T process(T in) {
 		// Advance IIR
 		T out = b[0] * in + b[1] * x[0] + b[2] * x[1]
 		        - a[0] * y[0] - a[1] * y[1];
 		// Push input
 		x[1] = x[0];
 		x[0] = in;
 		// Push output
 		y[1] = y[0];
 		y[0] = out;
 		return out;
 	}
 	/** Calculates and sets the biquad transfer function coefficients.
 	f: normalized frequency (cutoff frequency / sample rate), must be less than 0.5
 	Q: quality factor
 	V: gain
 	*/
 	void setParameters(Type type, float f, float Q, float V) {
 		float K = std::tan(M_PI * f);
 		switch (type) {
 			case LOWPASS_1POLE: {
 				a[0] = -std::exp(-2.f * M_PI * f);
 				a[1] = 0.f;
 				b[0] = 1.f + a[0];
 				b[1] = 0.f;
 				b[2] = 0.f;
 			} break;
 			case HIGHPASS_1POLE: {
 				a[0] = std::exp(-2.f * M_PI * (0.5f - f));
 				a[1] = 0.f;
 				b[0] = 1.f - a[0];
 				b[1] = 0.f;
 				b[2] = 0.f;
 			} break;
 			case LOWPASS: {
 				float norm = 1.f / (1.f + K / Q + K * K);
 				b[0] = K * K * norm;
 				b[1] = 2.f * b[0];
 				b[2] = b[0];
 				a[0] = 2.f * (K * K - 1.f) * norm;
 				a[1] = (1.f - K / Q + K * K) * norm;
 			} break;
 			case HIGHPASS: {
 				float norm = 1.f / (1.f + K / Q + K * K);
 				b[0] = norm;
 				b[1] = -2.f * b[0];
 				b[2] = b[0];
 				a[0] = 2.f * (K * K - 1.f) * norm;
 				a[1] = (1.f - K / Q + K * K) * norm;
 			} break;
 			case LOWSHELF: {
 				float sqrtV = std::sqrt(V);
 				if (V >= 1.f) {
 					float norm = 1.f / (1.f + M_SQRT2 * K + K * K);
 					b[0] = (1.f + M_SQRT2 * sqrtV * K + V * K * K) * norm;
 					b[1] = 2.f * (V * K * K - 1.f) * norm;
 					b[2] = (1.f - M_SQRT2 * sqrtV * K + V * K * K) * norm;
 					a[0] = 2.f * (K * K - 1.f) * norm;
 					a[1] = (1.f - M_SQRT2 * K + K * K) * norm;
 				}
 				else {
 					float norm = 1.f / (1.f + M_SQRT2 / sqrtV * K + K * K / V);
 					b[0] = (1.f + M_SQRT2 * K + K * K) * norm;
 					b[1] = 2.f * (K * K - 1) * norm;
 					b[2] = (1.f - M_SQRT2 * K + K * K) * norm;
 					a[0] = 2.f * (K * K / V - 1.f) * norm;
 					a[1] = (1.f - M_SQRT2 / sqrtV * K + K * K / V) * norm;
 				}
 			} break;
 			case HIGHSHELF: {
 				float sqrtV = std::sqrt(V);
 				if (V >= 1.f) {
 					float norm = 1.f / (1.f + M_SQRT2 * K + K * K);
 					b[0] = (V + M_SQRT2 * sqrtV * K + K * K) * norm;
 					b[1] = 2.f * (K * K - V) * norm;
 					b[2] = (V - M_SQRT2 * sqrtV * K + K * K) * norm;
 					a[0] = 2.f * (K * K - 1.f) * norm;
 					a[1] = (1.f - M_SQRT2 * K + K * K) * norm;
 				}
 				else {
 					float norm = 1.f / (1.f / V + M_SQRT2 / sqrtV * K + K * K);
 					b[0] = (1.f + M_SQRT2 * K + K * K) * norm;
 					b[1] = 2.f * (K * K - 1.f) * norm;
 					b[2] = (1.f - M_SQRT2 * K + K * K) * norm;
 					a[0] = 2.f * (K * K - 1.f / V) * norm;
 					a[1] = (1.f / V - M_SQRT2 / sqrtV * K + K * K) * norm;
 				}
 			} break;
 			case BANDPASS: {
 				float norm = 1.f / (1.f + K / Q + K * K);
 				b[0] = K / Q * norm;
 				b[1] = 0.f;
 				b[2] = -b[0];
 				a[0] = 2.f * (K * K - 1.f) * norm;
 				a[1] = (1.f - K / Q + K * K) * norm;
 			} break;
 			case PEAK: {
 				if (V >= 1.f) {
 					float norm = 1.f / (1.f + K / Q + K * K);
 					b[0] = (1.f + K / Q * V + K * K) * norm;
 					b[1] = 2.f * (K * K - 1.f) * norm;
 					b[2] = (1.f - K / Q * V + K * K) * norm;
 					a[0] = b[1];
 					a[1] = (1.f - K / Q + K * K) * norm;
 				}
 				else {
 					float norm = 1.f / (1.f + K / Q / V + K * K);
 					b[0] = (1.f + K / Q + K * K) * norm;
 					b[1] = 2.f * (K * K - 1.f) * norm;
 					b[2] = (1.f - K / Q + K * K) * norm;
 					a[0] = b[1];
 					a[1] = (1.f - K / Q / V + K * K) * norm;
 				}
 			} break;
 			case NOTCH: {
 				float norm = 1.f / (1.f + K / Q + K * K);
 				b[0] = (1.f + K * K) * norm;
 				b[1] = 2.f * (K * K - 1.f) * norm;
 				b[2] = b[0];
 				a[0] = b[1];
 				a[1] = (1.f - K / Q + K * K) * norm;
 			} break;
 			default: break;
 		}
 	}
 	void copyParameters(const TBiquadFilter<T>& from) {
 		b[0] = from.b[0];
 		b[1] = from.b[1];
 		b[2] = from.b[2];
 		a[0] = from.a[0];
 		a[1] = from.a[1];
 	}
 	/** Computes the gain of a particular frequency
 	f: normalized frequency
 	*/
 	float getFrequencyResponse(float f) {
 		// Compute sum(a_k e^(-i k f))
 		std::complex<float> bsum = b[0];
 		std::complex<float> asum = 1.f;
 		for (int i = 1; i < 3; i++) {
 			float p = 2 * M_PI * -i * f;
 			std::complex<float> e(std::cos(p), std::sin(p));
 			bsum += b[i] * e;
 			asum += a[i - 1] * e;
 		}
 		return std::abs(bsum / asum);
 	}
 };
 typedef TBiquadFilter<> BiquadFilter;
 } // namespace dsp
 } // namespace rack
--- a/include/dsp/fir.hpp
+++ b/include/dsp/fir.hpp
@@ -8,7 +8,7 @@ namespace dsp {
 /** Performs a direct sum convolution */
 inline float convolveNaive(const float *in, const float *kernel, int len) {
 inline float convolveNaive(const float* in, const float* kernel, int len) {
 	float y = 0.f;
 	for (int i = 0; i < len; i++) {
 		y += in[len - 1 - i] * kernel[i];
@@ -17,7 +17,7 @@ inline float convolveNaive(const float *in, const float *kernel, int len) {
 }
 /** Computes the impulse response of a boxcar lowpass filter */
 inline void boxcarLowpassIR(float *out, int len, float cutoff = 0.5f) {
 inline void boxcarLowpassIR(float* out, int len, float cutoff = 0.5f) {
 	for (int i = 0; i < len; i++) {
 		float t = i - (len - 1) / 2.f;
 		out[i] = 2 * cutoff * sinc(2 * cutoff * t);
@@ -28,23 +28,23 @@ inline void boxcarLowpassIR(float *out, int len, float cutoff = 0.5f) {
 struct RealTimeConvolver {
 	// `kernelBlocks` number of contiguous FFT blocks of size `blockSize`
 	// indexed by [i * blockSize*2 + j]
 	float *kernelFfts = NULL;
 	float *inputFfts = NULL;
 	float *outputTail = NULL;
 	float *tmpBlock = NULL;
 	float* kernelFfts = NULL;
 	float* inputFfts = NULL;
 	float* outputTail = NULL;
 	float* tmpBlock = NULL;
 	size_t blockSize;
 	size_t kernelBlocks = 0;
 	size_t inputPos = 0;
 	PFFFT_Setup *pffft;
 	PFFFT_Setup* pffft;
 	/** `blockSize` is the size of each FFT block. It should be >=32 and a power of 2. */
 	RealTimeConvolver(size_t blockSize) {
 		this->blockSize = blockSize;
 		pffft = pffft_new_setup(blockSize*2, PFFFT_REAL);
 		pffft = pffft_new_setup(blockSize * 2, PFFFT_REAL);
 		outputTail = new float[blockSize];
 		std::memset(outputTail, 0, blockSize * sizeof(float));
 		tmpBlock = new float[blockSize*2];
 		std::memset(tmpBlock, 0, blockSize*2 * sizeof(float));
 		tmpBlock = new float[blockSize * 2];
 		std::memset(tmpBlock, 0, blockSize * 2 * sizeof(float));
 	}
 	~RealTimeConvolver() {
@@ -54,7 +54,7 @@ struct RealTimeConvolver {
 		pffft_destroy_setup(pffft);
 	}
 	void setKernel(const float *kernel, size_t length) {
 	void setKernel(const float* kernel, size_t length) {
 		// Clear existing kernel
 		if (kernelFfts) {
 			pffft_aligned_free(kernelFfts);
@@ -72,17 +72,17 @@ struct RealTimeConvolver {
 			kernelBlocks = (length - 1) / blockSize + 1;
 			// Allocate blocks
 			kernelFfts = (float*) pffft_aligned_malloc(sizeof(float) * blockSize*2 * kernelBlocks);
 			inputFfts = (float*) pffft_aligned_malloc(sizeof(float) * blockSize*2 * kernelBlocks);
 			std::memset(inputFfts, 0, sizeof(float) * blockSize*2 * kernelBlocks);
 			kernelFfts = (float*) pffft_aligned_malloc(sizeof(float) * blockSize * 2 * kernelBlocks);
 			inputFfts = (float*) pffft_aligned_malloc(sizeof(float) * blockSize * 2 * kernelBlocks);
 			std::memset(inputFfts, 0, sizeof(float) * blockSize * 2 * kernelBlocks);
 			for (size_t i = 0; i < kernelBlocks; i++) {
 				// Pad each block with zeros
 				std::memset(tmpBlock, 0, sizeof(float) * blockSize*2);
 				size_t len = std::min((int) blockSize, (int) (length - i*blockSize));
 				std::memcpy(tmpBlock, &kernel[i*blockSize], sizeof(float)*len);
 				std::memset(tmpBlock, 0, sizeof(float) * blockSize * 2);
 				size_t len = std::min((int) blockSize, (int)(length - i * blockSize));
 				std::memcpy(tmpBlock, &kernel[i * blockSize], sizeof(float)*len);
 				// Compute fft
 				pffft_transform(pffft, tmpBlock, &kernelFfts[blockSize*2 * i], NULL, PFFFT_FORWARD);
 				pffft_transform(pffft, tmpBlock, &kernelFfts[blockSize * 2 * i], NULL, PFFFT_FORWARD);
 			}
 		}
 	}
@@ -90,7 +90,7 @@ struct RealTimeConvolver {
 	/** Applies reverb to input
 	input and output must be of size `blockSize`
 	*/
 	void processBlock(const float *input, float *output) {
 	void processBlock(const float* input, float* output) {
 		if (kernelBlocks == 0) {
 			std::memset(output, 0, sizeof(float) * blockSize);
 			return;
@@ -99,17 +99,17 @@ struct RealTimeConvolver {
 		// Step input position
 		inputPos = (inputPos + 1) % kernelBlocks;
 		// Pad block with zeros
 		std::memset(tmpBlock, 0, sizeof(float) * blockSize*2);
 		std::memset(tmpBlock, 0, sizeof(float) * blockSize * 2);
 		std::memcpy(tmpBlock, input, sizeof(float) * blockSize);
 		// Compute input fft
 		pffft_transform(pffft, tmpBlock, &inputFfts[blockSize*2 * inputPos], NULL, PFFFT_FORWARD);
 		pffft_transform(pffft, tmpBlock, &inputFfts[blockSize * 2 * inputPos], NULL, PFFFT_FORWARD);
 		// Create output fft
 		std::memset(tmpBlock, 0, sizeof(float) * blockSize*2);
 		std::memset(tmpBlock, 0, sizeof(float) * blockSize * 2);
 		// convolve input fft by kernel fft
 		// Note: This is the CPU bottleneck loop
 		for (size_t i = 0; i < kernelBlocks; i++) {
 			size_t pos = (inputPos - i + kernelBlocks) % kernelBlocks;
 			pffft_zconvolve_accumulate(pffft, &kernelFfts[blockSize*2 * i], &inputFfts[blockSize*2 * pos], tmpBlock, 1.f);
 			pffft_zconvolve_accumulate(pffft, &kernelFfts[blockSize * 2 * i], &inputFfts[blockSize * 2 * pos], tmpBlock, 1.f);
 		}
 		// Compute output
 		pffft_transform(pffft, tmpBlock, tmpBlock, NULL, PFFFT_BACKWARD);
@@ -118,7 +118,7 @@ struct RealTimeConvolver {
 			tmpBlock[i] += outputTail[i];
 		}
 		// Copy output block to output
 		float scale = 1.f / (blockSize*2);
 		float scale = 1.f / (blockSize * 2);
 		for (size_t i = 0; i < blockSize; i++) {
 			// Scale based on FFT
 			output[i] = tmpBlock[i] * scale;
--- a/include/dsp/minblep.hpp
+++ b/include/dsp/minblep.hpp
@@ -12,7 +12,7 @@ o: oversample factor
 output: must be length `2 * z * o`.
 https://www.cs.cmu.edu/~eli/papers/icmc01-hardsync.pdf
 */
 void minBlepImpulse(int z, int o, float *output);
 void minBlepImpulse(int z, int o, float* output);
 template <int Z, int O, typename T = float>
--- a/include/dsp/resampler.hpp
+++ b/include/dsp/resampler.hpp
@@ -15,7 +15,7 @@ namespace dsp {
 /** Resamples by a fixed rational factor. */
 template <int MAX_CHANNELS>
 struct SampleRateConverter {
 	SpeexResamplerState *st = NULL;
 	SpeexResamplerState* st = NULL;
 	int channels = MAX_CHANNELS;
 	int quality = SPEEX_RESAMPLER_QUALITY_DEFAULT;
 	int inRate = 44100;
@@ -73,7 +73,7 @@ struct SampleRateConverter {
 	}
 	/** `in` and `out` are interlaced with the number of channels */
 	void process(const Frame<MAX_CHANNELS> *in, int *inFrames, Frame<MAX_CHANNELS> *out, int *outFrames) {
 	void process(const Frame<MAX_CHANNELS>* in, int* inFrames, Frame<MAX_CHANNELS>* out, int* outFrames) {
 		assert(in);
 		assert(inFrames);
 		assert(out);
@@ -105,13 +105,13 @@ struct SampleRateConverter {
 /** Downsamples by an integer factor. */
 template <int OVERSAMPLE, int QUALITY, typename T = float>
 struct Decimator {
 	T inBuffer[OVERSAMPLE*QUALITY];
 	float kernel[OVERSAMPLE*QUALITY];
 	T inBuffer[OVERSAMPLE * QUALITY];
 	float kernel[OVERSAMPLE * QUALITY];
 	int inIndex;
 	Decimator(float cutoff = 0.9f) {
 		boxcarLowpassIR(kernel, OVERSAMPLE*QUALITY, cutoff * 0.5f / OVERSAMPLE);
 		blackmanHarrisWindow(kernel, OVERSAMPLE*QUALITY);
 		boxcarLowpassIR(kernel, OVERSAMPLE * QUALITY, cutoff * 0.5f / OVERSAMPLE);
 		blackmanHarrisWindow(kernel, OVERSAMPLE * QUALITY);
 		reset();
 	}
 	void reset() {
@@ -119,17 +119,17 @@ struct Decimator {
 		std::memset(inBuffer, 0, sizeof(inBuffer));
 	}
 	/** `in` must be length OVERSAMPLE */
 	T process(T *in) {
 	T process(T* in) {
 		// Copy input to buffer
 		std::memcpy(&inBuffer[inIndex], in, OVERSAMPLE*sizeof(T));
 		std::memcpy(&inBuffer[inIndex], in, OVERSAMPLE * sizeof(T));
 		// Advance index
 		inIndex += OVERSAMPLE;
 		inIndex %= OVERSAMPLE*QUALITY;
 		inIndex %= OVERSAMPLE * QUALITY;
 		// Perform naive convolution
 		T out = 0.f;
 		for (int i = 0; i < OVERSAMPLE*QUALITY; i++) {
 		for (int i = 0; i < OVERSAMPLE * QUALITY; i++) {
 			int index = inIndex - 1 - i;
 			index = (index + OVERSAMPLE*QUALITY) % (OVERSAMPLE*QUALITY);
 			index = (index + OVERSAMPLE * QUALITY) % (OVERSAMPLE * QUALITY);
 			out += kernel[i] * inBuffer[index];
 		}
 		return out;
@@ -141,12 +141,12 @@ struct Decimator {
 template <int OVERSAMPLE, int QUALITY>
 struct Upsampler {
 	float inBuffer[QUALITY];
 	float kernel[OVERSAMPLE*QUALITY];
 	float kernel[OVERSAMPLE * QUALITY];
 	int inIndex;
 	Upsampler(float cutoff = 0.9f) {
 		boxcarLowpassIR(kernel, OVERSAMPLE*QUALITY, cutoff * 0.5f / OVERSAMPLE);
 		blackmanHarrisWindow(kernel, OVERSAMPLE*QUALITY);
 		boxcarLowpassIR(kernel, OVERSAMPLE * QUALITY, cutoff * 0.5f / OVERSAMPLE);
 		blackmanHarrisWindow(kernel, OVERSAMPLE * QUALITY);
 		reset();
 	}
 	void reset() {
@@ -154,7 +154,7 @@ struct Upsampler {
 		std::memset(inBuffer, 0, sizeof(inBuffer));
 	}
 	/** `out` must be length OVERSAMPLE */
 	void process(float in, float *out) {
 	void process(float in, float* out) {
 		// Zero-stuff input buffer
 		inBuffer[inIndex] = OVERSAMPLE * in;
 		// Advance index
--- a/include/dsp/ringbuffer.hpp
+++ b/include/dsp/ringbuffer.hpp
@@ -18,13 +18,13 @@ struct RingBuffer {
 	size_t end = 0;
 	size_t mask(size_t i) const {
 			return i & (S - 1);
 		return i & (S - 1);
 	}
 	void push(T t) {
 		size_t i = mask(end++);
 		data[i] = t;
 	}
 	void pushBuffer(const T *t, int n) {
 	void pushBuffer(const T* t, int n) {
 		size_t i = mask(end);
 		size_t e1 = i + n;
 		size_t e2 = (e1 < S) ? e1 : S;
@@ -37,7 +37,7 @@ struct RingBuffer {
 	T shift() {
 		return data[mask(start++)];
 	}
 	void shiftBuffer(T *t, size_t n) {
 	void shiftBuffer(T* t, size_t n) {
 		size_t i = mask(start);
 		size_t s1 = i + n;
 		size_t s2 = (s1 < S) ? s1 : S;
@@ -70,7 +70,7 @@ Thread-safe for single producers and consumers?
 */
 template <typename T, size_t S>
 struct DoubleRingBuffer {
 	T data[S*2];
 	T data[S * 2];
 	size_t start = 0;
 	size_t end = 0;
@@ -104,7 +104,7 @@ struct DoubleRingBuffer {
 	If any data is appended, you must call endIncr afterwards.
 	Pointer is invalidated when any other method is called.
 	*/
 	T *endData() {
 	T* endData() {
 		return &data[mask(end)];
 	}
 	void endIncr(size_t n) {
@@ -123,7 +123,7 @@ struct DoubleRingBuffer {
 	/** Returns a pointer to S consecutive elements for consumption
 	If any data is consumed, call startIncr afterwards.
 	*/
 	const T *startData() const {
 	const T* startData() const {
 		return &data[mask(start)];
 	}
 	void startIncr(size_t n) {
@@ -174,7 +174,7 @@ struct AppleRingBuffer {
 	}
 	/** Returns a pointer to S consecutive elements for appending, requesting to append n elements.
 	*/
 	T *endData(size_t n) {
 	T* endData(size_t n) {
 		if (end + n > N) {
 			returnBuffer();
 		}
@@ -189,7 +189,7 @@ struct AppleRingBuffer {
 	/** Returns a pointer to S consecutive elements for consumption
 	If any data is consumed, call startIncr afterwards.
 	*/
 	const T *startData() const {
 	const T* startData() const {
 		return &data[start];
 	}
 	void startIncr(size_t n) {
--- a/include/dsp/window.hpp
+++ b/include/dsp/window.hpp
@@ -16,7 +16,7 @@ inline T hann(T p) {
 }
 /** Multiplies the Hann window by a signal `x` of length `len` in-place. */
 inline void hannWindow(float *x, int len) {
 inline void hannWindow(float* x, int len) {
 	for (int i = 0; i < len; i++) {
 		x[i] *= hann(float(i) / (len - 1));
 	}
@@ -29,12 +29,12 @@ A typical alpha value is 0.16.
 template <typename T>
 inline T blackman(T alpha, T p) {
 	return
 		+ (1 - alpha) / 2
 		- T(1) / 2 * simd::cos(2 * T(M_PI) * p)
 		+ alpha / 2 * simd::cos(4 * T(M_PI) * p);
 	  + (1 - alpha) / 2
 	  - T(1) / 2 * simd::cos(2 * T(M_PI) * p)
 	  + alpha / 2 * simd::cos(4 * T(M_PI) * p);
 }
 inline void blackmanWindow(float alpha, float *x, int len) {
 inline void blackmanWindow(float alpha, float* x, int len) {
 	for (int i = 0; i < len; i++) {
 		x[i] *= blackman(alpha, float(i) / (len - 1));
 	}
@@ -47,13 +47,13 @@ https://en.wikipedia.org/wiki/Window_function#Blackman%E2%80%93Nuttall_window
 template <typename T>
 inline T blackmanNuttall(T p) {
 	return
 		+ T(0.3635819)
 		- T(0.4891775) * simd::cos(2 * T(M_PI) * p)
 		+ T(0.1365995) * simd::cos(4 * T(M_PI) * p)
 		- T(0.0106411) * simd::cos(6 * T(M_PI) * p);
 	  + T(0.3635819)
 	  - T(0.4891775) * simd::cos(2 * T(M_PI) * p)
 	  + T(0.1365995) * simd::cos(4 * T(M_PI) * p)
 	  - T(0.0106411) * simd::cos(6 * T(M_PI) * p);
 }
 inline void blackmanNuttallWindow(float *x, int len) {
 inline void blackmanNuttallWindow(float* x, int len) {
 	for (int i = 0; i < len; i++) {
 		x[i] *= blackmanNuttall(float(i) / (len - 1));
 	}
@@ -65,13 +65,13 @@ https://en.wikipedia.org/wiki/Window_function#Blackman%E2%80%93Harris_window
 template <typename T>
 inline T blackmanHarris(T p) {
 	return
 		+ T(0.35875)
 		- T(0.48829) * simd::cos(2 * T(M_PI) * p)
 		+ T(0.14128) * simd::cos(4 * T(M_PI) * p)
 		- T(0.01168) * simd::cos(6 * T(M_PI) * p);
 	  + T(0.35875)
 	  - T(0.48829) * simd::cos(2 * T(M_PI) * p)
 	  + T(0.14128) * simd::cos(4 * T(M_PI) * p)
 	  - T(0.01168) * simd::cos(6 * T(M_PI) * p);
 }
 inline void blackmanHarrisWindow(float *x, int len) {
 inline void blackmanHarrisWindow(float* x, int len) {
 	for (int i = 0; i < len; i++) {
 		x[i] *= blackmanHarris(float(i) / (len - 1));
 	}
--- a/include/engine/Cable.hpp
+++ b/include/engine/Cable.hpp
@@ -9,9 +9,9 @@ namespace engine {
 struct Cable {
 	int id = -1;
 	Module *outputModule = NULL;
 	Module* outputModule = NULL;
 	int outputId;
 	Module *inputModule = NULL;
 	Module* inputModule = NULL;
 	int inputId;
 };
--- a/include/engine/Engine.hpp
+++ b/include/engine/Engine.hpp
@@ -12,7 +12,7 @@ namespace engine {
 struct Engine {
 	struct Internal;
 	Internal *internal;
 	Internal* internal;
 	Engine();
 	~Engine();
@@ -37,12 +37,12 @@ struct Engine {
 	If the module ID is -1, an ID is automatically assigned.
 	Does not transfer pointer ownership.
 	*/
 	void addModule(Module *module);
 	void removeModule(Module *module);
 	Module *getModule(int moduleId);
 	void resetModule(Module *module);
 	void randomizeModule(Module *module);
 	void bypassModule(Module *module, bool bypass);
 	void addModule(Module* module);
 	void removeModule(Module* module);
 	Module* getModule(int moduleId);
 	void resetModule(Module* module);
 	void randomizeModule(Module* module);
 	void bypassModule(Module* module, bool bypass);
 	// Cables
 	/** Adds a cable to the rack engine.
@@ -50,26 +50,26 @@ struct Engine {
 	If the cable ID is -1, an ID is automatically assigned.
 	Does not transfer pointer ownership.
 	*/
 	void addCable(Cable *cable);
 	void removeCable(Cable *cable);
 	void addCable(Cable* cable);
 	void removeCable(Cable* cable);
 	// Params
 	void setParam(Module *module, int paramId, float value);
 	float getParam(Module *module, int paramId);
 	void setSmoothParam(Module *module, int paramId, float value);
 	float getSmoothParam(Module *module, int paramId);
 	void setParam(Module* module, int paramId, float value);
 	float getParam(Module* module, int paramId);
 	void setSmoothParam(Module* module, int paramId, float value);
 	float getSmoothParam(Module* module, int paramId);
 	// ParamHandles
 	void addParamHandle(ParamHandle *paramHandle);
 	void removeParamHandle(ParamHandle *paramHandle);
 	void addParamHandle(ParamHandle* paramHandle);
 	void removeParamHandle(ParamHandle* paramHandle);
 	/** Returns the unique ParamHandle for the given paramId */
 	ParamHandle *getParamHandle(int moduleId, int paramId);
 	ParamHandle* getParamHandle(int moduleId, int paramId);
 	/** Use getParamHandle(int, int) instead. */
 	DEPRECATED ParamHandle *getParamHandle(Module *module, int paramId);
 	DEPRECATED ParamHandle* getParamHandle(Module* module, int paramId);
 	/** Sets the ParamHandle IDs and module pointer.
 	If `overwrite` is true and another ParamHandle points to the same param, unsets that one and replaces it with the given handle.
 	*/
 	void updateParamHandle(ParamHandle *paramHandle, int moduleId, int paramId, bool overwrite = true);
 	void updateParamHandle(ParamHandle* paramHandle, int moduleId, int paramId, bool overwrite = true);
 };
--- a/include/engine/Module.hpp
+++ b/include/engine/Module.hpp
@@ -14,7 +14,7 @@ namespace rack {
 namespace plugin {
 	struct Model;
 struct Model;
 }
@@ -23,7 +23,7 @@ namespace engine {
 /** DSP processor instance for your module. */
 struct Module {
 	plugin::Model *model = NULL;	/** Unique ID for referring to the module in the engine.
 	plugin::Model* model = NULL;	/** Unique ID for referring to the module in the engine.
 	Assigned when added to the engine.
 	*/
 	int id = -1;
@@ -42,7 +42,7 @@ struct Module {
 		/** ID of the expander module, or -1 if nonexistent. */
 		int moduleId = -1;
 		/** Pointer to the expander Module, or NULL if nonexistent. */
 		Module *module = NULL;
 		Module* module = NULL;
 		/** Double buffer for receiving messages from the expander module.
 		If you intend to receive messages from an expander, allocate both message buffers with identical blocks of memory (arrays, structs, etc).
 		Remember to free the buffer in the Module destructor.
@@ -63,8 +63,8 @@ struct Module {
 		You may choose for your Module to instead write to its own message buffer for consumption by other modules, i.e. the expander "pulls" rather than this module "pushing".
 		As long as this convention is followed by the other module, this is fine.
 		*/
 		void *producerMessage = NULL;
 		void *consumerMessage = NULL;
 		void* producerMessage = NULL;
 		void* consumerMessage = NULL;
 		bool messageFlipRequested = false;
 	};
@@ -97,10 +97,10 @@ struct Module {
 		if (paramQuantities[paramId])
 			delete paramQuantities[paramId];
 		Param *p = &params[paramId];
 		Param* p = &params[paramId];
 		p->value = defaultValue;
 		ParamQuantity *q = new TParamQuantity;
 		ParamQuantity* q = new TParamQuantity;
 		q->module = this;
 		q->paramId = paramId;
 		q->minValue = minValue;
@@ -125,7 +125,7 @@ struct Module {
 	/** Advances the module by one audio sample.
 	Override this method to read Inputs and Params and to write Outputs and Lights.
 	*/
 	virtual void process(const ProcessArgs &args) {
 	virtual void process(const ProcessArgs& args) {
 #pragma GCC diagnostic push
 #pragma GCC diagnostic ignored "-Wdeprecated-declarations"
 		step();
@@ -145,12 +145,14 @@ struct Module {
 	/** Called when the Module is removed from the Engine */
 	virtual void onRemove() {}
 	json_t *toJson();
 	void fromJson(json_t *rootJ);
 	json_t* toJson();
 	void fromJson(json_t* rootJ);
 	/** Override to store extra internal data in the "data" property of the module's JSON object. */
 	virtual json_t *dataToJson() { return NULL; }
 	virtual void dataFromJson(json_t *root) {}
 	virtual json_t* dataToJson() {
 		return NULL;
 	}
 	virtual void dataFromJson(json_t* root) {}
 };
--- a/include/engine/ParamHandle.hpp
+++ b/include/engine/ParamHandle.hpp
@@ -16,7 +16,7 @@ struct ParamHandle {
 	*/
 	int moduleId = -1;
 	int paramId = 0;
 	Module *module = NULL;
 	Module* module = NULL;
 	std::string text;
 	NVGcolor color;
--- a/include/engine/ParamQuantity.hpp
+++ b/include/engine/ParamQuantity.hpp
@@ -12,7 +12,7 @@ struct Module;
 /** A Quantity that wraps an engine::Param. */
 struct ParamQuantity : Quantity {
 	Module *module = NULL;
 	Module* module = NULL;
 	int paramId = 0;
 	/** The minimum allowed value. */
@@ -38,7 +38,7 @@ struct ParamQuantity : Quantity {
 	/** An optional one-sentence description of the parameter. */
 	std::string description;
 	Param *getParam();
 	Param* getParam();
 	/** Request to the engine to smoothly set the value */
 	void setSmoothValue(float smoothValue);
 	float getSmoothValue();
--- a/include/engine/Port.hpp
+++ b/include/engine/Port.hpp
@@ -62,12 +62,12 @@ struct alignas(32) Port {
 	/** Returns a pointer to the array of voltages beginning with firstChannel.
 	The pointer can be used for reading and writing.
 	*/
 	float *getVoltages(int firstChannel = 0) {
 	float* getVoltages(int firstChannel = 0) {
 		return &voltages[firstChannel];
 	}
 	/** Copies the port's voltages to an array of size at least `channels`. */
 	void readVoltages(float *v) {
 	void readVoltages(float* v) {
 		for (int c = 0; c < channels; c++) {
 			v[c] = voltages[c];
 		}
@@ -76,7 +76,7 @@ struct alignas(32) Port {
 	/** Copies an array of size at least `channels` to the port's voltages.
 	Remember to set the number of channels *before* calling this method.
 	*/
 	void writeVoltages(const float *v) {
 	void writeVoltages(const float* v) {
 		for (int c = 0; c < channels; c++) {
 			voltages[c] = v[c];
 		}
@@ -105,7 +105,7 @@ struct alignas(32) Port {
 	template <typename T>
 	T getPolyVoltageSimd(int firstChannel) {
 			return isMonophonic() ? getVoltage(0) : getVoltageSimd<T>(firstChannel);
 		return isMonophonic() ? getVoltage(0) : getVoltageSimd<T>(firstChannel);
 	}
 	template <typename T>
--- a/include/event.hpp
+++ b/include/event.hpp
@@ -31,7 +31,7 @@ namespace rack {
 namespace widget {
 	struct Widget;
 struct Widget;
 }
@@ -47,46 +47,52 @@ struct Context {
 	/** Whether the event has been consumed by an event handler and no more handlers should consume the event. */
 	bool consumed = false;
 	/** The widget that responded to the event. */
 	widget::Widget *target = NULL;
 	widget::Widget* target = NULL;
 };
 /** Base class for all events. */
 struct Base {
 	Context *context = NULL;
 	Context* context = NULL;
 	/** Prevents the event from being handled by more Widgets.
 	*/
 	void stopPropagating() const {
 		if (!context) return;
 		if (!context)
 			return;
 		context->propagating = false;
 	}
 	bool isPropagating() const {
 		if (!context) return true;
 		if (!context)
 			return true;
 		return context->propagating;
 	}
 	/** Tells the event handler that a particular Widget consumed the event.
 	You usually want to stop propagation as well, so call consume() instead.
 	*/
 	void setTarget(widget::Widget *w) const {
 		if (!context) return;
 	void setTarget(widget::Widget* w) const {
 		if (!context)
 			return;
 		context->target = w;
 	}
 	widget::Widget *getTarget() const {
 		if (!context) return NULL;
 	widget::Widget* getTarget() const {
 		if (!context)
 			return NULL;
 		return context->target;
 	}
 	/** Sets the target Widget and stops propagating.
 	A NULL Widget may be passed to consume but not set a target.
 	*/
 	void consume(widget::Widget *w) const {
 		if (!context) return;
 	void consume(widget::Widget* w) const {
 		if (!context)
 			return;
 		context->propagating = false;
 		context->consumed = true;
 		context->target = w;
 	}
 	bool isConsumed() const {
 		if (!context) return false;
 		if (!context)
 			return false;
 		return context->consumed;
 	}
 };
@@ -256,7 +262,7 @@ Consume this event to allow DragEnter and DragLeave to occur.
 */
 struct DragHover : DragBase, PositionBase {
 	/** The dragged widget */
 	widget::Widget *origin = NULL;
 	widget::Widget* origin = NULL;
 	/** Change in mouse position since the last frame. Can be zero. */
 	math::Vec mouseDelta;
 };
@@ -268,7 +274,7 @@ The target sets `draggedWidget`, which allows DragLeave to occur.
 */
 struct DragEnter : DragBase {
 	/** The dragged widget */
 	widget::Widget *origin = NULL;
 	widget::Widget* origin = NULL;
 };
@@ -277,7 +283,7 @@ Must consume the DragHover event (when the Widget is entered) to receive this ev
 */
 struct DragLeave : DragBase {
 	/** The dragged widget */
 	widget::Widget *origin = NULL;
 	widget::Widget* origin = NULL;
 };
@@ -286,7 +292,7 @@ Must consume the Button event (on release) to receive this event.
 */
 struct DragDrop : DragBase {
 	/** The dragged widget */
 	widget::Widget *origin = NULL;
 	widget::Widget* origin = NULL;
 };
@@ -294,10 +300,10 @@ struct DragDrop : DragBase {
 Recurses.
 */
 struct PathDrop : Base, PositionBase {
 	PathDrop(const std::vector<std::string> &paths) : paths(paths) {}
 	PathDrop(const std::vector<std::string>& paths) : paths(paths) {}
 	/** List of file paths in the dropped selection */
 	const std::vector<std::string> &paths;
 	const std::vector<std::string>& paths;
 };
@@ -361,32 +367,42 @@ struct Hide : Base {
 struct State {
 	widget::Widget *rootWidget = NULL;
 	widget::Widget* rootWidget = NULL;
 	/** State widgets
 	Don't set these directly unless you know what you're doing. Use the set*() methods instead.
 	*/
 	widget::Widget *hoveredWidget = NULL;
 	widget::Widget *draggedWidget = NULL;
 	widget::Widget* hoveredWidget = NULL;
 	widget::Widget* draggedWidget = NULL;
 	int dragButton = 0;
 	widget::Widget *dragHoveredWidget = NULL;
 	widget::Widget *selectedWidget = NULL;
 	widget::Widget* dragHoveredWidget = NULL;
 	widget::Widget* selectedWidget = NULL;
 	/** For double-clicking */
 	double lastClickTime = -INFINITY;
 	widget::Widget *lastClickedWidget = NULL;
 	widget::Widget* lastClickedWidget = NULL;
 	std::set<int> heldKeys;
 	widget::Widget *getRootWidget() {return rootWidget;}
 	widget::Widget *getHoveredWidget() {return hoveredWidget;}
 	widget::Widget *getDraggedWidget() {return draggedWidget;}
 	widget::Widget *getDragHoveredWidget() {return dragHoveredWidget;}
 	widget::Widget *getSelectedWidget() {return selectedWidget;}
 	widget::Widget* getRootWidget() {
 		return rootWidget;
 	}
 	widget::Widget* getHoveredWidget() {
 		return hoveredWidget;
 	}
 	widget::Widget* getDraggedWidget() {
 		return draggedWidget;
 	}
 	widget::Widget* getDragHoveredWidget() {
 		return dragHoveredWidget;
 	}
 	widget::Widget* getSelectedWidget() {
 		return selectedWidget;
 	}
 	void setHovered(widget::Widget *w);
 	void setDragged(widget::Widget *w, int button);
 	void setDragHovered(widget::Widget *w);
 	void setSelected(widget::Widget *w);
 	void setHovered(widget::Widget* w);
 	void setDragged(widget::Widget* w, int button);
 	void setDragHovered(widget::Widget* w);
 	void setSelected(widget::Widget* w);
 	/** Prepares a widget for deletion */
 	void finalizeWidget(widget::Widget *w);
 	void finalizeWidget(widget::Widget* w);
 	bool handleButton(math::Vec pos, int button, int action, int mods);
 	bool handleHover(math::Vec pos, math::Vec mouseDelta);
@@ -394,7 +410,7 @@ struct State {
 	bool handleScroll(math::Vec pos, math::Vec scrollDelta);
 	bool handleText(math::Vec pos, int codepoint);
 	bool handleKey(math::Vec pos, int key, int scancode, int action, int mods);
 	bool handleDrop(math::Vec pos, const std::vector<std::string> &paths);
 	bool handleDrop(math::Vec pos, const std::vector<std::string>& paths);
 	bool handleZoom();
 };
--- a/include/force_link_glibc_2.23.h
+++ b/include/force_link_glibc_2.23.h
@@ -501,11 +501,11 @@ __asm__(".symver __progname_full,__progname_full@GLIBC_2.2.5");
 __asm__(".symver __pthread_cleanup_routine,__pthread_cleanup_routine@GLIBC_2.3.3");
 __asm__(".symver __pthread_getspecific,__pthread_getspecific@GLIBC_2.2.5");
 #ifndef _GLIBCXX_SHARED
 #ifndef IN_LIBGCC2
 #ifdef _REENTRANT
 __asm__(".symver __pthread_key_create,__pthread_key_create@GLIBC_2.2.5");
 #endif
 #endif
 	#ifndef IN_LIBGCC2
 		#ifdef _REENTRANT
 			__asm__(".symver __pthread_key_create,__pthread_key_create@GLIBC_2.2.5");
 		#endif
 	#endif
 #endif
 __asm__(".symver __pthread_mutex_destroy,__pthread_mutex_destroy@GLIBC_2.2.5");
 __asm__(".symver __pthread_mutex_init,__pthread_mutex_init@GLIBC_2.2.5");
@@ -544,7 +544,7 @@ __asm__(".symver __realpath_chk,__realpath_chk@GLIBC_2.4");
 __asm__(".symver __recv_chk,__recv_chk@GLIBC_2.4");
 __asm__(".symver __recvfrom_chk,__recvfrom_chk@GLIBC_2.4");
 #ifdef _REENTRANT
 __asm__(".symver __register_atfork,__register_atfork@GLIBC_2.3.2");
 	__asm__(".symver __register_atfork,__register_atfork@GLIBC_2.3.2");
 #endif
 __asm__(".symver __remainder_finite,__remainder_finite@GLIBC_2.15");
 __asm__(".symver __remainderf_finite,__remainderf_finite@GLIBC_2.15");
@@ -2009,47 +2009,47 @@ __asm__(".symver pselect,pselect@GLIBC_2.2.5");
 __asm__(".symver psiginfo,psiginfo@GLIBC_2.10");
 __asm__(".symver psignal,psignal@GLIBC_2.2.5");
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_destroy,pthread_attr_destroy@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_destroy,pthread_attr_destroy@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_attr_getaffinity_np,pthread_attr_getaffinity_np@GLIBC_2.3.4");
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_getdetachstate,pthread_attr_getdetachstate@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_getdetachstate,pthread_attr_getdetachstate@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_attr_getguardsize,pthread_attr_getguardsize@GLIBC_2.2.5");
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_getinheritsched,pthread_attr_getinheritsched@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_getinheritsched,pthread_attr_getinheritsched@GLIBC_2.2.5");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_getschedparam,pthread_attr_getschedparam@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_getschedparam,pthread_attr_getschedparam@GLIBC_2.2.5");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_getschedpolicy,pthread_attr_getschedpolicy@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_getschedpolicy,pthread_attr_getschedpolicy@GLIBC_2.2.5");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_getscope,pthread_attr_getscope@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_getscope,pthread_attr_getscope@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_attr_getstack,pthread_attr_getstack@GLIBC_2.2.5");
 __asm__(".symver pthread_attr_getstackaddr,pthread_attr_getstackaddr@GLIBC_2.2.5");
 __asm__(".symver pthread_attr_getstacksize,pthread_attr_getstacksize@GLIBC_2.2.5");
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_init,pthread_attr_init@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_init,pthread_attr_init@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_attr_setaffinity_np,pthread_attr_setaffinity_np@GLIBC_2.3.4");
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_setdetachstate,pthread_attr_setdetachstate@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_setdetachstate,pthread_attr_setdetachstate@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_attr_setguardsize,pthread_attr_setguardsize@GLIBC_2.2.5");
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_setinheritsched,pthread_attr_setinheritsched@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_setinheritsched,pthread_attr_setinheritsched@GLIBC_2.2.5");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_setschedparam,pthread_attr_setschedparam@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_setschedparam,pthread_attr_setschedparam@GLIBC_2.2.5");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_setschedpolicy,pthread_attr_setschedpolicy@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_setschedpolicy,pthread_attr_setschedpolicy@GLIBC_2.2.5");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_attr_setscope,pthread_attr_setscope@GLIBC_2.2.5");
 	__asm__(".symver pthread_attr_setscope,pthread_attr_setscope@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_attr_setstack,pthread_attr_setstack@GLIBC_2.2.5");
 __asm__(".symver pthread_attr_setstackaddr,pthread_attr_setstackaddr@GLIBC_2.2.5");
@@ -2063,44 +2063,44 @@ __asm__(".symver pthread_barrierattr_init,pthread_barrierattr_init@GLIBC_2.2.5")
 __asm__(".symver pthread_barrierattr_setpshared,pthread_barrierattr_setpshared@GLIBC_2.2.5");
 __asm__(".symver pthread_cancel,pthread_cancel@GLIBC_2.2.5");
 #ifdef _REENTRANT
 __asm__(".symver pthread_cond_broadcast,pthread_cond_broadcast@GLIBC_2.3.2");
 	__asm__(".symver pthread_cond_broadcast,pthread_cond_broadcast@GLIBC_2.3.2");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_cond_destroy,pthread_cond_destroy@GLIBC_2.3.2");
 	__asm__(".symver pthread_cond_destroy,pthread_cond_destroy@GLIBC_2.3.2");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_cond_init,pthread_cond_init@GLIBC_2.3.2");
 	__asm__(".symver pthread_cond_init,pthread_cond_init@GLIBC_2.3.2");
 #endif
 __asm__(".symver pthread_cond_signal,pthread_cond_signal@GLIBC_2.3.2");
 #ifdef _REENTRANT
 __asm__(".symver pthread_cond_timedwait,pthread_cond_timedwait@GLIBC_2.3.2");
 	__asm__(".symver pthread_cond_timedwait,pthread_cond_timedwait@GLIBC_2.3.2");
 #endif
 __asm__(".symver pthread_cond_wait,pthread_cond_wait@GLIBC_2.3.2");
 #ifdef _REENTRANT
 __asm__(".symver pthread_condattr_destroy,pthread_condattr_destroy@GLIBC_2.2.5");
 	__asm__(".symver pthread_condattr_destroy,pthread_condattr_destroy@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_condattr_getclock,pthread_condattr_getclock@GLIBC_2.3.3");
 __asm__(".symver pthread_condattr_getpshared,pthread_condattr_getpshared@GLIBC_2.2.5");
 #ifdef _REENTRANT
 __asm__(".symver pthread_condattr_init,pthread_condattr_init@GLIBC_2.2.5");
 	__asm__(".symver pthread_condattr_init,pthread_condattr_init@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_condattr_setclock,pthread_condattr_setclock@GLIBC_2.3.3");
 __asm__(".symver pthread_condattr_setpshared,pthread_condattr_setpshared@GLIBC_2.2.5");
 #ifndef _GLIBCXX_SHARED
 #ifdef _REENTRANT
 __asm__(".symver pthread_create,pthread_create@GLIBC_2.2.5");
 #endif
 	#ifdef _REENTRANT
 		__asm__(".symver pthread_create,pthread_create@GLIBC_2.2.5");
 	#endif
 #endif
 #ifndef _GLIBCXX_SHARED
 #ifdef _REENTRANT
 __asm__(".symver pthread_detach,pthread_detach@GLIBC_2.2.5");
 #endif
 	#ifdef _REENTRANT
 		__asm__(".symver pthread_detach,pthread_detach@GLIBC_2.2.5");
 	#endif
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_equal,pthread_equal@GLIBC_2.2.5");
 	__asm__(".symver pthread_equal,pthread_equal@GLIBC_2.2.5");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_exit,pthread_exit@GLIBC_2.2.5");
 	__asm__(".symver pthread_exit,pthread_exit@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_getaffinity_np,pthread_getaffinity_np@GLIBC_2.3.4");
 __asm__(".symver pthread_getattr_default_np,pthread_getattr_default_np@GLIBC_2.18");
@@ -2109,50 +2109,50 @@ __asm__(".symver pthread_getconcurrency,pthread_getconcurrency@GLIBC_2.2.5");
 __asm__(".symver pthread_getcpuclockid,pthread_getcpuclockid@GLIBC_2.2.5");
 __asm__(".symver pthread_getname_np,pthread_getname_np@GLIBC_2.12");
 #ifdef _REENTRANT
 __asm__(".symver pthread_getschedparam,pthread_getschedparam@GLIBC_2.2.5");
 	__asm__(".symver pthread_getschedparam,pthread_getschedparam@GLIBC_2.2.5");
 #endif
 #ifndef _GLIBCXX_SHARED
 #ifndef IN_LIBGCC2
 #ifdef _REENTRANT
 __asm__(".symver pthread_getspecific,pthread_getspecific@GLIBC_2.2.5");
 #endif
 #endif
 	#ifndef IN_LIBGCC2
 		#ifdef _REENTRANT
 			__asm__(".symver pthread_getspecific,pthread_getspecific@GLIBC_2.2.5");
 		#endif
 	#endif
 #endif
 #ifndef _GLIBCXX_SHARED
 #ifdef _REENTRANT
 __asm__(".symver pthread_join,pthread_join@GLIBC_2.2.5");
 #endif
 	#ifdef _REENTRANT
 		__asm__(".symver pthread_join,pthread_join@GLIBC_2.2.5");
 	#endif
 #endif
 #ifndef _GLIBCXX_SHARED
 #ifndef IN_LIBGCC2
 #ifdef _REENTRANT
 __asm__(".symver pthread_key_create,pthread_key_create@GLIBC_2.2.5");
 #endif
 #endif
 	#ifndef IN_LIBGCC2
 		#ifdef _REENTRANT
 			__asm__(".symver pthread_key_create,pthread_key_create@GLIBC_2.2.5");
 		#endif
 	#endif
 #endif
 #ifndef _GLIBCXX_SHARED
 #ifdef _REENTRANT
 __asm__(".symver pthread_key_delete,pthread_key_delete@GLIBC_2.2.5");
 #endif
 	#ifdef _REENTRANT
 		__asm__(".symver pthread_key_delete,pthread_key_delete@GLIBC_2.2.5");
 	#endif
 #endif
 __asm__(".symver pthread_kill,pthread_kill@GLIBC_2.2.5");
 __asm__(".symver pthread_mutex_consistent,pthread_mutex_consistent@GLIBC_2.12");
 __asm__(".symver pthread_mutex_consistent_np,pthread_mutex_consistent_np@GLIBC_2.4");
 #ifdef _REENTRANT
 __asm__(".symver pthread_mutex_destroy,pthread_mutex_destroy@GLIBC_2.2.5");
 	__asm__(".symver pthread_mutex_destroy,pthread_mutex_destroy@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_mutex_getprioceiling,pthread_mutex_getprioceiling@GLIBC_2.4");
 #ifdef _REENTRANT
 __asm__(".symver pthread_mutex_init,pthread_mutex_init@GLIBC_2.2.5");
 	__asm__(".symver pthread_mutex_init,pthread_mutex_init@GLIBC_2.2.5");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_mutex_lock,pthread_mutex_lock@GLIBC_2.2.5");
 	__asm__(".symver pthread_mutex_lock,pthread_mutex_lock@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_mutex_setprioceiling,pthread_mutex_setprioceiling@GLIBC_2.4");
 __asm__(".symver pthread_mutex_timedlock,pthread_mutex_timedlock@GLIBC_2.2.5");
 __asm__(".symver pthread_mutex_trylock,pthread_mutex_trylock@GLIBC_2.2.5");
 #ifdef _REENTRANT
 __asm__(".symver pthread_mutex_unlock,pthread_mutex_unlock@GLIBC_2.2.5");
 	__asm__(".symver pthread_mutex_unlock,pthread_mutex_unlock@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_mutexattr_destroy,pthread_mutexattr_destroy@GLIBC_2.2.5");
 __asm__(".symver pthread_mutexattr_getkind_np,pthread_mutexattr_getkind_np@GLIBC_2.2.5");
@@ -2171,11 +2171,11 @@ __asm__(".symver pthread_mutexattr_setrobust,pthread_mutexattr_setrobust@GLIBC_2
 __asm__(".symver pthread_mutexattr_setrobust_np,pthread_mutexattr_setrobust_np@GLIBC_2.4");
 __asm__(".symver pthread_mutexattr_settype,pthread_mutexattr_settype@GLIBC_2.2.5");
 #ifndef _GLIBCXX_SHARED
 #ifndef IN_LIBGCC2
 #ifdef _REENTRANT
 __asm__(".symver pthread_once,pthread_once@GLIBC_2.2.5");
 #endif
 #endif
 	#ifndef IN_LIBGCC2
 		#ifdef _REENTRANT
 			__asm__(".symver pthread_once,pthread_once@GLIBC_2.2.5");
 		#endif
 	#endif
 #endif
 __asm__(".symver pthread_rwlock_destroy,pthread_rwlock_destroy@GLIBC_2.2.5");
 __asm__(".symver pthread_rwlock_init,pthread_rwlock_init@GLIBC_2.2.5");
@@ -2193,28 +2193,28 @@ __asm__(".symver pthread_rwlockattr_init,pthread_rwlockattr_init@GLIBC_2.2.5");
 __asm__(".symver pthread_rwlockattr_setkind_np,pthread_rwlockattr_setkind_np@GLIBC_2.2.5");
 __asm__(".symver pthread_rwlockattr_setpshared,pthread_rwlockattr_setpshared@GLIBC_2.2.5");
 #ifdef _REENTRANT
 __asm__(".symver pthread_self,pthread_self@GLIBC_2.2.5");
 	__asm__(".symver pthread_self,pthread_self@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_setaffinity_np,pthread_setaffinity_np@GLIBC_2.3.4");
 __asm__(".symver pthread_setattr_default_np,pthread_setattr_default_np@GLIBC_2.18");
 #ifdef _REENTRANT
 __asm__(".symver pthread_setcancelstate,pthread_setcancelstate@GLIBC_2.2.5");
 	__asm__(".symver pthread_setcancelstate,pthread_setcancelstate@GLIBC_2.2.5");
 #endif
 #ifdef _REENTRANT
 __asm__(".symver pthread_setcanceltype,pthread_setcanceltype@GLIBC_2.2.5");
 	__asm__(".symver pthread_setcanceltype,pthread_setcanceltype@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_setconcurrency,pthread_setconcurrency@GLIBC_2.2.5");
 __asm__(".symver pthread_setname_np,pthread_setname_np@GLIBC_2.12");
 #ifdef _REENTRANT
 __asm__(".symver pthread_setschedparam,pthread_setschedparam@GLIBC_2.2.5");
 	__asm__(".symver pthread_setschedparam,pthread_setschedparam@GLIBC_2.2.5");
 #endif
 __asm__(".symver pthread_setschedprio,pthread_setschedprio@GLIBC_2.3.4");
 #ifndef _GLIBCXX_SHARED
 #ifndef IN_LIBGCC2
 #ifdef _REENTRANT
 __asm__(".symver pthread_setspecific,pthread_setspecific@GLIBC_2.2.5");
 #endif
 #endif
 	#ifndef IN_LIBGCC2
 		#ifdef _REENTRANT
 			__asm__(".symver pthread_setspecific,pthread_setspecific@GLIBC_2.2.5");
 		#endif
 	#endif
 #endif
 __asm__(".symver pthread_sigmask,pthread_sigmask@GLIBC_2.2.5");
 __asm__(".symver pthread_sigqueue,pthread_sigqueue@GLIBC_2.11");
--- a/include/helpers.hpp
+++ b/include/helpers.hpp
@@ -16,50 +16,50 @@
 namespace rack {
 template <class TModule, class TModuleWidget, typename... Tags>
 plugin::Model *createModel(const std::string &slug) {
 template <class TModule, class TModuleWidget>
 plugin::Model* createModel(const std::string& slug) {
 	struct TModel : plugin::Model {
 		engine::Module *createModule() override {
 			engine::Module *m = new TModule;
 		engine::Module* createModule() override {
 			engine::Module* m = new TModule;
 			m->model = this;
 			return m;
 		}
 		app::ModuleWidget *createModuleWidget() override {
 			TModule *m = new TModule;
 		app::ModuleWidget* createModuleWidget() override {
 			TModule* m = new TModule;
 			m->engine::Module::model = this;
 			app::ModuleWidget *mw = new TModuleWidget(m);
 			app::ModuleWidget* mw = new TModuleWidget(m);
 			mw->model = this;
 			return mw;
 		}
 		app::ModuleWidget *createModuleWidgetNull() override {
 			app::ModuleWidget *mw = new TModuleWidget(NULL);
 		app::ModuleWidget* createModuleWidgetNull() override {
 			app::ModuleWidget* mw = new TModuleWidget(NULL);
 			mw->model = this;
 			return mw;
 		}
 	};
 	plugin::Model *o = new TModel;
 	plugin::Model* o = new TModel;
 	o->slug = slug;
 	return o;
 }
 template <class TWidget>
 TWidget *createWidget(math::Vec pos) {
 	TWidget *o = new TWidget;
 TWidget* createWidget(math::Vec pos) {
 	TWidget* o = new TWidget;
 	o->box.pos = pos;
 	return o;
 }
 template <class TWidget>
 TWidget *createWidgetCentered(math::Vec pos) {
 	TWidget *o = createWidget<TWidget>(pos);
 TWidget* createWidgetCentered(math::Vec pos) {
 	TWidget* o = createWidget<TWidget>(pos);
 	o->box.pos = o->box.pos.minus(o->box.size.div(2));
 	return o;
 }
 template <class TParamWidget>
 TParamWidget *createParam(math::Vec pos, engine::Module *module, int paramId) {
 	TParamWidget *o = new TParamWidget;
 TParamWidget* createParam(math::Vec pos, engine::Module* module, int paramId) {
 	TParamWidget* o = new TParamWidget;
 	o->box.pos = pos;
 	if (module) {
 		o->paramQuantity = module->paramQuantities[paramId];
@@ -68,15 +68,15 @@ TParamWidget *createParam(math::Vec pos, engine::Module *module, int paramId) {
 }
 template <class TParamWidget>
 TParamWidget *createParamCentered(math::Vec pos, engine::Module *module, int paramId) {
 	TParamWidget *o = createParam<TParamWidget>(pos, module, paramId);
 TParamWidget* createParamCentered(math::Vec pos, engine::Module* module, int paramId) {
 	TParamWidget* o = createParam<TParamWidget>(pos, module, paramId);
 	o->box.pos = o->box.pos.minus(o->box.size.div(2));
 	return o;
 }
 template <class TPortWidget>
 TPortWidget *createInput(math::Vec pos, engine::Module *module, int inputId) {
 	TPortWidget *o = new TPortWidget;
 TPortWidget* createInput(math::Vec pos, engine::Module* module, int inputId) {
 	TPortWidget* o = new TPortWidget;
 	o->box.pos = pos;
 	o->module = module;
 	o->type = app::PortWidget::INPUT;
@@ -85,15 +85,15 @@ TPortWidget *createInput(math::Vec pos, engine::Module *module, int inputId) {
 }
 template <class TPortWidget>
 TPortWidget *createInputCentered(math::Vec pos, engine::Module *module, int inputId) {
 	TPortWidget *o = createInput<TPortWidget>(pos, module, inputId);
 TPortWidget* createInputCentered(math::Vec pos, engine::Module* module, int inputId) {
 	TPortWidget* o = createInput<TPortWidget>(pos, module, inputId);
 	o->box.pos = o->box.pos.minus(o->box.size.div(2));
 	return o;
 }
 template <class TPortWidget>
 TPortWidget *createOutput(math::Vec pos, engine::Module *module, int outputId) {
 	TPortWidget *o = new TPortWidget;
 TPortWidget* createOutput(math::Vec pos, engine::Module* module, int outputId) {
 	TPortWidget* o = new TPortWidget;
 	o->box.pos = pos;
 	o->module = module;
 	o->type = app::PortWidget::OUTPUT;
@@ -102,15 +102,15 @@ TPortWidget *createOutput(math::Vec pos, engine::Module *module, int outputId) {
 }
 template <class TPortWidget>
 TPortWidget *createOutputCentered(math::Vec pos, engine::Module *module, int outputId) {
 	TPortWidget *o = createOutput<TPortWidget>(pos, module, outputId);
 TPortWidget* createOutputCentered(math::Vec pos, engine::Module* module, int outputId) {
 	TPortWidget* o = createOutput<TPortWidget>(pos, module, outputId);
 	o->box.pos = o->box.pos.minus(o->box.size.div(2));
 	return o;
 }
 template <class TModuleLightWidget>
 TModuleLightWidget *createLight(math::Vec pos, engine::Module *module, int firstLightId) {
 	TModuleLightWidget *o = new TModuleLightWidget;
 TModuleLightWidget* createLight(math::Vec pos, engine::Module* module, int firstLightId) {
 	TModuleLightWidget* o = new TModuleLightWidget;
 	o->box.pos = pos;
 	o->module = module;
 	o->firstLightId = firstLightId;
@@ -118,33 +118,33 @@ TModuleLightWidget *createLight(math::Vec pos, engine::Module *module, int first
 }
 template <class TModuleLightWidget>
 TModuleLightWidget *createLightCentered(math::Vec pos, engine::Module *module, int firstLightId) {
 	TModuleLightWidget *o = createLight<TModuleLightWidget>(pos, module, firstLightId);
 TModuleLightWidget* createLightCentered(math::Vec pos, engine::Module* module, int firstLightId) {
 	TModuleLightWidget* o = createLight<TModuleLightWidget>(pos, module, firstLightId);
 	o->box.pos = o->box.pos.minus(o->box.size.div(2));
 	return o;
 }
 template <class TMenuLabel = ui::MenuLabel>
 TMenuLabel *createMenuLabel(std::string text) {
 	TMenuLabel *o = new TMenuLabel;
 TMenuLabel * createMenuLabel(std::string text) {
 	TMenuLabel* o = new TMenuLabel;
 	o->text = text;
 	return o;
 }
 template <class TMenuItem = ui::MenuItem>
 TMenuItem *createMenuItem(std::string text, std::string rightText = "") {
 	TMenuItem *o = new TMenuItem;
 TMenuItem * createMenuItem(std::string text, std::string rightText = "") {
 	TMenuItem* o = new TMenuItem;
 	o->text = text;
 	o->rightText = rightText;
 	return o;
 }
 template <class TMenu = ui::Menu>
 TMenu *createMenu() {
 	TMenu *o = new TMenu;
 TMenu * createMenu() {
 	TMenu* o = new TMenu;
 	o->box.pos = APP->window->mousePos;
 	ui::MenuOverlay *menuOverlay = new ui::MenuOverlay;
 	ui::MenuOverlay* menuOverlay = new ui::MenuOverlay;
 	menuOverlay->addChild(o);
 	APP->scene->addChild(menuOverlay);
--- a/include/history.hpp
+++ b/include/history.hpp
@@ -11,8 +11,8 @@ namespace rack {
 namespace app {
 	struct ModuleWidget;
 	struct CableWidget;
 struct ModuleWidget;
 struct CableWidget;
 } // namespace app
@@ -52,7 +52,7 @@ struct ComplexAction : Action {
 	~ComplexAction();
 	void undo() override;
 	void redo() override;
 	void push(Action *action);
 	void push(Action* action);
 	bool isEmpty();
 };
@@ -66,14 +66,14 @@ struct ModuleAction : Action {
 struct ModuleAdd : ModuleAction {
 	plugin::Model *model;
 	plugin::Model* model;
 	math::Vec pos;
 	json_t *moduleJ;
 	json_t* moduleJ;
 	ModuleAdd() {
 		name = "add module";
 	}
 	~ModuleAdd();
 	void setModule(app::ModuleWidget *mw);
 	void setModule(app::ModuleWidget* mw);
 	void undo() override;
 	void redo() override;
 };
@@ -108,8 +108,8 @@ struct ModuleBypass : ModuleAction {
 struct ModuleChange : ModuleAction {
 	json_t *oldModuleJ;
 	json_t *newModuleJ;
 	json_t* oldModuleJ;
 	json_t* newModuleJ;
 	ModuleChange() {
 		name = "change module";
 	}
@@ -138,7 +138,7 @@ struct CableAdd : Action {
 	int inputModuleId;
 	int inputId;
 	NVGcolor color;
 	void setCable(app::CableWidget *cw);
 	void setCable(app::CableWidget* cw);
 	void undo() override;
 	void redo() override;
 	CableAdd() {
@@ -163,7 +163,7 @@ struct State {
 	State();
 	~State();
 	void clear();
 	void push(Action *action);
 	void push(Action* action);
 	void undo();
 	void redo();
 	bool canUndo();
--- a/include/logger.hpp
+++ b/include/logger.hpp
@@ -35,7 +35,7 @@ void destroy();
 /** Do not use this function directly. Use the macros above.
 Thread-safe, meaning messages cannot overlap each other in the log.
 */
 void log(Level level, const char *filename, int line, const char *format, ...);
 void log(Level level, const char* filename, int line, const char* format, ...);
 } // namespace logger
--- a/include/math.hpp
+++ b/include/math.hpp
@@ -1,5 +1,6 @@
 #pragma once
 #include <common.hpp>
 #include <complex>
 #include <algorithm> // for std::min, max
@@ -63,7 +64,7 @@ inline int eucDiv(int a, int b) {
 	return div;
 }
 inline void eucDivMod(int a, int b, int *div, int *mod) {
 inline void eucDivMod(int a, int b, int* div, int* mod) {
 	*div = a / b;
 	*mod = a % b;
 	if (*mod < 0) {
@@ -148,10 +149,10 @@ inline float crossfade(float a, float b, float p) {
 /** Linearly interpolates an array `p` with index `x`.
 Assumes that the array at `p` is of length at least `floor(x) + 1`.
 */
 inline float interpolateLinear(const float *p, float x) {
 inline float interpolateLinear(const float* p, float x) {
 	int xi = x;
 	float xf = x - xi;
 	return crossfade(p[xi], p[xi+1], xf);
 	return crossfade(p[xi], p[xi + 1], xf);
 }
 /** Complex multiplication `c = a * b`.
@@ -160,7 +161,7 @@ Example:
 	cmultf(ar, ai, br, bi, &ar, &ai);
 */
 inline void complexMult(float ar, float ai, float br, float bi, float *cr, float *ci) {
 inline void complexMult(float ar, float ai, float br, float bi, float* cr, float* ci) {
 	*cr = ar * br - ai * bi;
 	*ci = ar * bi + ai * br;
 }
@@ -279,17 +280,17 @@ struct Rect {
 	/** Returns whether this Rect contains an entire point, inclusive on the top/left, non-inclusive on the bottom/right. */
 	bool isContaining(Vec v) const {
 		return pos.x <= v.x && v.x < pos.x + size.x
 			&& pos.y <= v.y && v.y < pos.y + size.y;
 		       && pos.y <= v.y && v.y < pos.y + size.y;
 	}
 	/** Returns whether this Rect contains an entire Rect. */
 	bool isContaining(Rect r) const {
 		return pos.x <= r.pos.x && r.pos.x + r.size.x <= pos.x + size.x
 			&& pos.y <= r.pos.y && r.pos.y + r.size.y <= pos.y + size.y;
 		       && pos.y <= r.pos.y && r.pos.y + r.size.y <= pos.y + size.y;
 	}
 	/** Returns whether this Rect overlaps with another Rect. */
 	bool isIntersecting(Rect r) const {
 		return (pos.x + size.x > r.pos.x && r.pos.x + r.size.x > pos.x)
 			&& (pos.y + size.y > r.pos.y && r.pos.y + r.size.y > pos.y);
 		       && (pos.y + size.y > r.pos.y && r.pos.y + r.size.y > pos.y);
 	}
 	bool isEqual(Rect r) const {
 		return pos.isEqual(r.pos) && size.isEqual(r.size);
@@ -364,22 +365,28 @@ struct Rect {
 		return r;
 	}
 	DEPRECATED bool contains(Vec v) const {return isContaining(v);}
 	DEPRECATED bool contains(Rect r) const {return isContaining(r);}
 	DEPRECATED bool intersects(Rect r) const {return isIntersecting(r);}
 	DEPRECATED bool contains(Vec v) const {
 		return isContaining(v);
 	}
 	DEPRECATED bool contains(Rect r) const {
 		return isContaining(r);
 	}
 	DEPRECATED bool intersects(Rect r) const {
 		return isIntersecting(r);
 	}
 };
 inline Vec Vec::clamp(Rect bound) const {
 	return Vec(
 		math::clamp(x, bound.pos.x, bound.pos.x + bound.size.x),
 		math::clamp(y, bound.pos.y, bound.pos.y + bound.size.y));
 	         math::clamp(x, bound.pos.x, bound.pos.x + bound.size.x),
 	         math::clamp(y, bound.pos.y, bound.pos.y + bound.size.y));
 }
 inline Vec Vec::clampSafe(Rect bound) const {
 	return Vec(
 		math::clampSafe(x, bound.pos.x, bound.pos.x + bound.size.x),
 		math::clampSafe(y, bound.pos.y, bound.pos.y + bound.size.y));
 	         math::clampSafe(x, bound.pos.x, bound.pos.x + bound.size.x),
 	         math::clampSafe(y, bound.pos.y, bound.pos.y + bound.size.y));
 }
--- a/include/midi.hpp
+++ b/include/midi.hpp
@@ -59,17 +59,31 @@ struct Output;
 struct Driver {
 	virtual ~Driver() {}
 	virtual std::string getName() {return "";}
 	virtual std::string getName() {
 		return "";
 	}
 	virtual std::vector<int> getInputDeviceIds() {return {};}
 	virtual std::string getInputDeviceName(int deviceId) {return "";}
 	virtual InputDevice *subscribeInput(int deviceId, Input *input) {return NULL;}
 	virtual void unsubscribeInput(int deviceId, Input *input) {}
 	virtual std::vector<int> getInputDeviceIds() {
 		return {};
 	}
 	virtual std::string getInputDeviceName(int deviceId) {
 		return "";
 	}
 	virtual InputDevice* subscribeInput(int deviceId, Input* input) {
 		return NULL;
 	}
 	virtual void unsubscribeInput(int deviceId, Input* input) {}
 	virtual std::vector<int> getOutputDeviceIds() {return {};}
 	virtual std::string getOutputDeviceName(int deviceId) {return "";}
 	virtual OutputDevice *subscribeOutput(int deviceId, Output *output) {return NULL;}
 	virtual void unsubscribeOutput(int deviceId, Output *output) {}
 	virtual std::vector<int> getOutputDeviceIds() {
 		return {};
 	}
 	virtual std::string getOutputDeviceName(int deviceId) {
 		return "";
 	}
 	virtual OutputDevice* subscribeOutput(int deviceId, Output* output) {
 		return NULL;
 	}
 	virtual void unsubscribeOutput(int deviceId, Output* output) {}
 };
 ////////////////////
@@ -82,15 +96,15 @@ struct Device {
 struct InputDevice : Device {
 	std::set<Input*> subscribed;
 	void subscribe(Input *input);
 	void unsubscribe(Input *input);
 	void subscribe(Input* input);
 	void unsubscribe(Input* input);
 	void onMessage(Message message);
 };
 struct OutputDevice : Device {
 	std::set<Output*> subscribed;
 	void subscribe(Output *input);
 	void unsubscribe(Output *input);
 	void subscribe(Output* input);
 	void unsubscribe(Output* input);
 	virtual void sendMessage(Message message) {}
 };
@@ -108,7 +122,7 @@ struct Port {
 	*/
 	int channel = -1;
 	/** Not owned */
 	Driver *driver = NULL;
 	Driver* driver = NULL;
 	/** Remember to call setDriverId(-1) in subclass destructors. */
 	virtual ~Port() {}
@@ -125,14 +139,14 @@ struct Port {
 	std::string getChannelName(int channel);
 	void setChannel(int channel);
 	json_t *toJson();
 	void fromJson(json_t *rootJ);
 	json_t* toJson();
 	void fromJson(json_t* rootJ);
 };
 struct Input : Port {
 	/** Not owned */
 	InputDevice *inputDevice = NULL;
 	InputDevice* inputDevice = NULL;
 	Input();
 	~Input();
@@ -152,13 +166,13 @@ struct InputQueue : Input {
 	std::queue<Message> queue;
 	void onMessage(Message message) override;
 	/** If a Message is available, writes `message` and return true */
 	bool shift(Message *message);
 	bool shift(Message* message);
 };
 struct Output : Port {
 	/** Not owned */
 	OutputDevice *outputDevice = NULL;
 	OutputDevice* outputDevice = NULL;
 	Output();
 	~Output();
@@ -176,7 +190,7 @@ struct Output : Port {
 void init();
 void destroy();
 /** Registers a new MIDI driver. Takes pointer ownership. */
 void addDriver(int driverId, Driver *driver);
 void addDriver(int driverId, Driver* driver);
 } // namespace midi
--- a/include/network.hpp
+++ b/include/network.hpp
@@ -21,13 +21,13 @@ enum Method {
 /** Requests a JSON API URL over HTTP(S), using the data as the query (GET) or the body (POST, etc)
 Caller must json_decref().
 */
 json_t *requestJson(Method method, std::string url, json_t *dataJ);
 json_t* requestJson(Method method, std::string url, json_t* dataJ);
 /** Returns true if downloaded successfully */
 bool requestDownload(std::string url, const std::string &filename, float *progress);
 bool requestDownload(std::string url, const std::string& filename, float* progress);
 /** URL-encodes `s` */
 std::string encodeUrl(const std::string &s);
 std::string encodeUrl(const std::string& s);
 /** Gets the path portion of the URL. */
 std::string urlPath(const std::string &url);
 std::string urlPath(const std::string& url);
 } // namespace network
--- a/include/patch.hpp
+++ b/include/patch.hpp
@@ -30,8 +30,8 @@ struct PatchManager {
 	/** Disconnects all cables */
 	void disconnectDialog();
 	json_t *toJson();
 	void fromJson(json_t *rootJ);
 	json_t* toJson();
 	void fromJson(json_t* rootJ);
 	bool isLegacy(int level);
 };
--- a/include/plugin.hpp
+++ b/include/plugin.hpp
@@ -3,7 +3,6 @@
 #include <plugin/Plugin.hpp>
 #include <plugin/Model.hpp>
 #include <vector>
 #include <set>
 namespace rack {
@@ -25,24 +24,22 @@ struct Update {
 void init();
 void destroy();
 void logIn(const std::string &email, const std::string &password);
 void logIn(const std::string& email, const std::string& password);
 void logOut();
 bool isLoggedIn();
 void queryUpdates();
 bool hasUpdates();
 void syncUpdate(Update *update);
 void syncUpdate(Update* update);
 void syncUpdates();
 bool isSyncing();
 Plugin *getPlugin(const std::string &pluginSlug);
 Model *getModel(const std::string &pluginSlug, const std::string &modelSlug);
 std::string normalizeTag(const std::string &tag);
 Plugin* getPlugin(const std::string& pluginSlug);
 Model* getModel(const std::string& pluginSlug, const std::string& modelSlug);
 /** Checks that the slug contains only alphanumeric characters, "-", and "_" */
 bool isSlugValid(const std::string &slug);
 bool isSlugValid(const std::string& slug);
 /** Returns a string containing only the valid slug characters. */
 std::string normalizeSlug(const std::string &slug);
 std::string normalizeSlug(const std::string& slug);
 extern const std::set<std::string> allowedTags;
 extern std::vector<Plugin*> plugins;
 extern std::string loginStatus;
--- a/include/plugin/Model.hpp
+++ b/include/plugin/Model.hpp
@@ -9,12 +9,12 @@ namespace rack {
 namespace app {
 	struct ModuleWidget;
 struct ModuleWidget;
 } // namespace app
 namespace engine {
 	struct Module;
 struct Module;
 } // namespace engine
@@ -22,7 +22,7 @@ namespace plugin {
 struct Model {
 	Plugin *plugin = NULL;
 	Plugin* plugin = NULL;
 	std::vector<std::string> presetPaths;
 	/** Must be unique. Used for saving patches. Never change this after releasing your module.
@@ -31,20 +31,28 @@ struct Model {
 	std::string slug;
 	/** Human readable name for your model, e.g. "Voltage Controlled Oscillator" */
 	std::string name;
 	/** List of tags representing the function(s) of the module */
 	std::vector<std::string> tags;
 	/** List of tag IDs representing the function(s) of the module.
 	Tag IDs are not part of the ABI and may change at any time.
 	*/
 	std::vector<int> tags;
 	/** A one-line summary of the module's purpose */
 	std::string description;
 	virtual ~Model() {}
 	/** Creates a headless Module */
 	virtual engine::Module *createModule() { return NULL; }
 	virtual engine::Module* createModule() {
 		return NULL;
 	}
 	/** Creates a ModuleWidget with a Module attached */
 	virtual app::ModuleWidget *createModuleWidget() { return NULL; }
 	virtual app::ModuleWidget* createModuleWidget() {
 		return NULL;
 	}
 	/** Creates a ModuleWidget with no Module, useful for previews */
 	virtual app::ModuleWidget *createModuleWidgetNull() { return NULL; }
 	virtual app::ModuleWidget* createModuleWidgetNull() {
 		return NULL;
 	}
 	void fromJson(json_t *rootJ);
 	void fromJson(json_t* rootJ);
 };
--- a/include/plugin/Plugin.hpp
+++ b/include/plugin/Plugin.hpp
@@ -18,7 +18,7 @@ struct Plugin {
 	/** The file path to the plugin's directory */
 	std::string path;
 	/** OS-dependent library handle */
 	void *handle = NULL;
 	void* handle = NULL;
 	/** Must be unique. Used for saving patches. Never change this after releasing your plugin.
 	To guarantee uniqueness, it is a good idea to prefix the slug by your "company name" if available, e.g. "MyCompany-MyPlugin"
@@ -63,9 +63,9 @@ struct Plugin {
 	double modifiedTimestamp = -INFINITY;
 	~Plugin();
 	void addModel(Model *model);
 	Model *getModel(std::string slug);
 	void fromJson(json_t *rootJ);
 	void addModel(Model* model);
 	Model* getModel(std::string slug);
 	void fromJson(json_t* rootJ);
 };
--- a/include/plugin/callbacks.hpp
+++ b/include/plugin/callbacks.hpp
@@ -6,4 +6,4 @@
 You must implement this in your plugin
 */
 extern "C"
 void init(rack::plugin::Plugin *plugin);
 void init(rack::plugin::Plugin* plugin);
--- a/include/rack.hpp
+++ b/include/rack.hpp
@@ -91,6 +91,7 @@
 #include <dsp/ringbuffer.hpp>
 #include <dsp/vumeter.hpp>
 #include <dsp/window.hpp>
 #include <dsp/approx.hpp>
 #include <simd/vector.hpp>
 #include <simd/functions.hpp>
@@ -101,16 +102,16 @@ namespace rack {
 /** Define this macro before including this header to prevent common namespaces from being included in the main `rack::` namespace. */
 #ifndef RACK_FLATTEN_NAMESPACES
 // Import some namespaces for convenience
 using namespace logger;
 using namespace math;
 using namespace widget;
 using namespace ui;
 using namespace app;
 using plugin::Plugin;
 using plugin::Model;
 using namespace engine;
 using namespace componentlibrary;
 	// Import some namespaces for convenience
 	using namespace logger;
 	using namespace math;
 	using namespace widget;
 	using namespace ui;
 	using namespace app;
 	using plugin::Plugin;
 	using plugin::Model;
 	using namespace engine;
 	using namespace componentlibrary;
 #endif
--- a/include/rack0.hpp
+++ b/include/rack0.hpp
@@ -17,35 +17,91 @@ namespace rack {
 using namespace math;
 DEPRECATED inline int min(int a, int b) {return std::min(a, b);}
 DEPRECATED inline int max(int a, int b) {return std::max(a, b);}
 DEPRECATED inline int eucmod(int a, int base) {return eucMod(a, base);}
 DEPRECATED inline bool ispow2(int n) {return isPow2(n);}
 DEPRECATED inline int clamp2(int x, int a, int b) {return clampSafe(x, a, b);}
 DEPRECATED inline float min(float a, float b) {return std::min(a, b);}
 DEPRECATED inline float max(float a, float b) {return std::max(a, b);}
 DEPRECATED inline float eucmod(float a, float base) {return eucMod(a, base);}
 DEPRECATED inline float clamp2(float x, float a, float b) {return clampSafe(x, a, b);}
 DEPRECATED inline int mini(int a, int b) {return std::min(a, b);}
 DEPRECATED inline int maxi(int a, int b) {return std::max(a, b);}
 DEPRECATED inline int clampi(int x, int min, int max) {return math::clamp(x, min, max);}
 DEPRECATED inline int absi(int a) {return std::fabs(a);}
 DEPRECATED inline int eucmodi(int a, int base) {return eucMod(a, base);}
 DEPRECATED inline int log2i(int n) {return math::log2(n);}
 DEPRECATED inline bool ispow2i(int n) {return isPow2(n);}
 DEPRECATED inline float absf(float x) {return std::fabs(x);}
 DEPRECATED inline float sgnf(float x) {return sgn(x);}
 DEPRECATED inline float eucmodf(float a, float base) {return eucMod(a, base);}
 DEPRECATED inline bool nearf(float a, float b, float epsilon = 1.0e-6f) {return math::isNear(a, b, epsilon);}
 DEPRECATED inline float clampf(float x, float min, float max) {return math::clamp(x, min, max);}
 DEPRECATED inline float clamp2f(float x, float min, float max) {return clampSafe(x, min, max);}
 DEPRECATED inline float chopf(float x, float eps) {return chop(x, eps);}
 DEPRECATED inline float rescalef(float x, float a, float b, float yMin, float yMax) {return math::rescale(x, a, b, yMin, yMax);}
 DEPRECATED inline float crossf(float a, float b, float frac) {return crossfade(a, b, frac);}
 DEPRECATED inline float interpf(const float *p, float x) {return interpolateLinear(p, x);}
 DEPRECATED inline void complexMult(float *cr, float *ci, float ar, float ai, float br, float bi) {complexMult(ar, ai, br, bi, cr, ci);}
 DEPRECATED inline void cmultf(float *cr, float *ci, float ar, float ai, float br, float bi) {return complexMult(ar, ai, br, bi, cr, ci);}
 DEPRECATED inline int min(int a, int b) {
 	return std::min(a, b);
 }
 DEPRECATED inline int max(int a, int b) {
 	return std::max(a, b);
 }
 DEPRECATED inline int eucmod(int a, int base) {
 	return eucMod(a, base);
 }
 DEPRECATED inline bool ispow2(int n) {
 	return isPow2(n);
 }
 DEPRECATED inline int clamp2(int x, int a, int b) {
 	return clampSafe(x, a, b);
 }
 DEPRECATED inline float min(float a, float b) {
 	return std::min(a, b);
 }
 DEPRECATED inline float max(float a, float b) {
 	return std::max(a, b);
 }
 DEPRECATED inline float eucmod(float a, float base) {
 	return eucMod(a, base);
 }
 DEPRECATED inline float clamp2(float x, float a, float b) {
 	return clampSafe(x, a, b);
 }
 DEPRECATED inline int mini(int a, int b) {
 	return std::min(a, b);
 }
 DEPRECATED inline int maxi(int a, int b) {
 	return std::max(a, b);
 }
 DEPRECATED inline int clampi(int x, int min, int max) {
 	return math::clamp(x, min, max);
 }
 DEPRECATED inline int absi(int a) {
 	return std::fabs(a);
 }
 DEPRECATED inline int eucmodi(int a, int base) {
 	return eucMod(a, base);
 }
 DEPRECATED inline int log2i(int n) {
 	return math::log2(n);
 }
 DEPRECATED inline bool ispow2i(int n) {
 	return isPow2(n);
 }
 DEPRECATED inline float absf(float x) {
 	return std::fabs(x);
 }
 DEPRECATED inline float sgnf(float x) {
 	return sgn(x);
 }
 DEPRECATED inline float eucmodf(float a, float base) {
 	return eucMod(a, base);
 }
 DEPRECATED inline bool nearf(float a, float b, float epsilon = 1.0e-6f) {
 	return math::isNear(a, b, epsilon);
 }
 DEPRECATED inline float clampf(float x, float min, float max) {
 	return math::clamp(x, min, max);
 }
 DEPRECATED inline float clamp2f(float x, float min, float max) {
 	return clampSafe(x, min, max);
 }
 DEPRECATED inline float chopf(float x, float eps) {
 	return chop(x, eps);
 }
 DEPRECATED inline float rescalef(float x, float a, float b, float yMin, float yMax) {
 	return math::rescale(x, a, b, yMin, yMax);
 }
 DEPRECATED inline float crossf(float a, float b, float frac) {
 	return crossfade(a, b, frac);
 }
 DEPRECATED inline float interpf(const float* p, float x) {
 	return interpolateLinear(p, x);
 }
 DEPRECATED inline void complexMult(float* cr, float* ci, float ar, float ai, float br, float bi) {
 	complexMult(ar, ai, br, bi, cr, ci);
 }
 DEPRECATED inline void cmultf(float* cr, float* ci, float ar, float ai, float br, float bi) {
 	return complexMult(ar, ai, br, bi, cr, ci);
 }
 ////////////////////
 // string
@@ -57,11 +113,21 @@ DEPRECATED inline void cmultf(float *cr, float *ci, float ar, float ai, float br
 // random
 ////////////////////
 DEPRECATED inline uint32_t randomu32() {return random::u32();}
 DEPRECATED inline uint64_t randomu64() {return random::u64();}
 DEPRECATED inline float randomUniform() {return random::uniform();}
 DEPRECATED inline float randomNormal() {return random::normal();}
 DEPRECATED inline float randomf() {return random::uniform();}
 DEPRECATED inline uint32_t randomu32() {
 	return random::u32();
 }
 DEPRECATED inline uint64_t randomu64() {
 	return random::u64();
 }
 DEPRECATED inline float randomUniform() {
 	return random::uniform();
 }
 DEPRECATED inline float randomNormal() {
 	return random::normal();
 }
 DEPRECATED inline float randomf() {
 	return random::uniform();
 }
 ////////////////////
 // logger
@@ -77,23 +143,47 @@ DEPRECATED inline float randomf() {return random::uniform();}
 // asset
 ////////////////////
 DEPRECATED inline std::string assetGlobal(std::string filename) {return asset::system(filename);}
 DEPRECATED inline std::string assetLocal(std::string filename) {return asset::user(filename);}
 DEPRECATED inline std::string assetPlugin(Plugin *plugin, std::string filename) {return asset::plugin(plugin, filename);}
 DEPRECATED inline std::string assetGlobal(std::string filename) {
 	return asset::system(filename);
 }
 DEPRECATED inline std::string assetLocal(std::string filename) {
 	return asset::user(filename);
 }
 DEPRECATED inline std::string assetPlugin(Plugin* plugin, std::string filename) {
 	return asset::plugin(plugin, filename);
 }
 ////////////////////
 // color
 ////////////////////
 DEPRECATED inline NVGcolor colorClip(NVGcolor a) {return color::clamp(a);}
 DEPRECATED inline NVGcolor colorMinus(NVGcolor a, NVGcolor b) {return color::minus(a, b);}
 DEPRECATED inline NVGcolor colorPlus(NVGcolor a, NVGcolor b) {return color::plus(a, b);}
 DEPRECATED inline NVGcolor colorMult(NVGcolor a, NVGcolor b) {return color::mult(a, b);}
 DEPRECATED inline NVGcolor colorMult(NVGcolor a, float x) {return color::mult(a, x);}
 DEPRECATED inline NVGcolor colorScreen(NVGcolor a, NVGcolor b) {return color::screen(a, b);}
 DEPRECATED inline NVGcolor colorAlpha(NVGcolor a, float alpha) {return color::alpha(a, alpha);}
 DEPRECATED inline NVGcolor colorFromHexString(std::string s) {return color::fromHexString(s);}
 DEPRECATED inline std::string colorToHexString(NVGcolor c) {return color::toHexString(c);}
 DEPRECATED inline NVGcolor colorClip(NVGcolor a) {
 	return color::clamp(a);
 }
 DEPRECATED inline NVGcolor colorMinus(NVGcolor a, NVGcolor b) {
 	return color::minus(a, b);
 }
 DEPRECATED inline NVGcolor colorPlus(NVGcolor a, NVGcolor b) {
 	return color::plus(a, b);
 }
 DEPRECATED inline NVGcolor colorMult(NVGcolor a, NVGcolor b) {
 	return color::mult(a, b);
 }
 DEPRECATED inline NVGcolor colorMult(NVGcolor a, float x) {
 	return color::mult(a, x);
 }
 DEPRECATED inline NVGcolor colorScreen(NVGcolor a, NVGcolor b) {
 	return color::screen(a, b);
 }
 DEPRECATED inline NVGcolor colorAlpha(NVGcolor a, float alpha) {
 	return color::alpha(a, alpha);
 }
 DEPRECATED inline NVGcolor colorFromHexString(std::string s) {
 	return color::fromHexString(s);
 }
 DEPRECATED inline std::string colorToHexString(NVGcolor c) {
 	return color::toHexString(c);
 }
 ////////////////////
 // componentlibrary
@@ -118,14 +208,14 @@ DEPRECATED static const NVGcolor COLOR_DARK_PANEL = componentlibrary::SCHEME_DAR
 /** Use createWidget() instead */
 template <class TScrew>
 DEPRECATED TScrew *createScrew(math::Vec pos) {
 DEPRECATED TScrew* createScrew(math::Vec pos) {
 	return createWidget<TScrew>(pos);
 }
 /** Use createParam(pos, module, paramId) and set the Param properties in your Module constructor */
 template <class TParamWidget>
 DEPRECATED TParamWidget *createParam(math::Vec pos, Module *module, int paramId, float minValue, float maxValue, float defaultValue) {
 	TParamWidget *o = createParam<TParamWidget>(pos, module, paramId);
 DEPRECATED TParamWidget* createParam(math::Vec pos, Module* module, int paramId, float minValue, float maxValue, float defaultValue) {
 	TParamWidget* o = createParam<TParamWidget>(pos, module, paramId);
 	if (module) {
 		module->configParam(paramId, minValue, maxValue, defaultValue);
 	}
@@ -133,8 +223,8 @@ DEPRECATED TParamWidget *createParam(math::Vec pos, Module *module, int paramId,
 }
 template <class TParamWidget>
 DEPRECATED TParamWidget *createParamCentered(math::Vec pos, Module *module, int paramId, float minValue, float maxValue, float defaultValue) {
 	TParamWidget *o = createParamCentered<TParamWidget>(pos, module, paramId);
 DEPRECATED TParamWidget* createParamCentered(math::Vec pos, Module* module, int paramId, float minValue, float maxValue, float defaultValue) {
 	TParamWidget* o = createParamCentered<TParamWidget>(pos, module, paramId);
 	if (module) {
 		module->configParam(paramId, minValue, maxValue, defaultValue);
 	}
@@ -143,8 +233,8 @@ DEPRECATED TParamWidget *createParamCentered(math::Vec pos, Module *module, int
 /** Use createInput() and createOutput() without the `type` variable */
 template <class TPortWidget>
 DEPRECATED TPortWidget *createPort(math::Vec pos, PortWidget::Type type, Module *module, int inputId) {
 	TPortWidget *o = new TPortWidget;
 DEPRECATED TPortWidget* createPort(math::Vec pos, PortWidget::Type type, Module* module, int inputId) {
 	TPortWidget* o = new TPortWidget;
 	o->box.pos = pos;
 	o->type = type;
 	o->module = module;
--- a/include/settings.hpp
+++ b/include/settings.hpp
@@ -42,10 +42,10 @@ extern bool skipLoadOnLaunch;
 extern std::string patchPath;
 extern std::vector<NVGcolor> cableColors;
 json_t *toJson();
 void fromJson(json_t *rootJ);
 void save(const std::string &path);
 void load(const std::string &path);
 json_t* toJson();
 void fromJson(json_t* rootJ);
 void save(const std::string& path);
 void load(const std::string& path);
 } // namespace settings
--- a/include/simd/functions.hpp
+++ b/include/simd/functions.hpp
@@ -1,14 +1,53 @@
 #pragma once
 #include <simd/vector.hpp>
 #include <simd/sse_mathfun.h>
 #include <simd/sse_mathfun_extension.h>
 #include <common.hpp>
 #include <math.hpp>
 #include <cmath>
 namespace rack {
 namespace simd {
 // Nonstandard functions
 inline float ifelse(bool cond, float a, float b) {
 	return cond ? a : b;
 }
 /** Given a mask, returns a if mask is 0xffffffff per element, b if mask is 0x00000000 */
 inline float_4 ifelse(float_4 mask, float_4 a, float_4 b) {
 	return (a & mask) | andnot(mask, b);
 }
 /** Returns the approximate reciprocal square root.
 Much faster than `1/sqrt(x)`.
 */
 inline float_4 rsqrt(float_4 x) {
 	return float_4(_mm_rsqrt_ps(x.v));
 }
 /** Returns the approximate reciprocal.
 Much faster than `1/x`.
 */
 inline float_4 rcp(float_4 x) {
 	return float_4(_mm_rcp_ps(x.v));
 }
 /** Given a mask `a`, returns a vector with each element either 0's or 1's depending on the mask bit.
 */
 template <typename T>
 T movemaskInverse(int a);
 template <>
 inline float_4 movemaskInverse<float_4>(int x) {
 	__m128i msk8421 = _mm_set_epi32(8, 4, 2, 1);
 	__m128i x_bc = _mm_set1_epi32(x);
 	__m128i t = _mm_and_si128(x_bc, msk8421);
 	return float_4(_mm_castsi128_ps(_mm_cmpeq_epi32(x_bc, t)));
 }
 // Standard math functions from std::
 /* Import std:: math functions into the simd namespace so you can use `sin(T)` etc in templated functions and get both the scalar and vector versions.
@@ -75,40 +114,66 @@ inline float_4 cos(float_4 x) {
 	return float_4(sse_mathfun_cos_ps(x.v));
 }
 using std::tan;
 inline float_4 tan(float_4 x) {
 	return float_4(sse_mathfun_tan_ps(x.v));
 }
 using std::atan;
 inline float_4 atan(float_4 x) {
 	return float_4(sse_mathfun_atan_ps(x.v));
 }
 using std::atan2;
 inline float_4 atan2(float_4 x, float_4 y) {
 	return float_4(sse_mathfun_atan2_ps(x.v, y.v));
 }
 using std::trunc;
 inline float_4 trunc(float_4 a) {
 	return float_4(_mm_cvtepi32_ps(_mm_cvttps_epi32(a.v)));
 }
 using std::floor;
 inline float_4 floor(float_4 a) {
 	return float_4(sse_mathfun_floor_ps(a.v));
 	float_4 b = trunc(a);
 	b -= (b > a) & 1.f;
 	return b;
 }
 using std::ceil;
 inline float_4 ceil(float_4 a) {
 	return float_4(sse_mathfun_ceil_ps(a.v));
 	float_4 b = trunc(a);
 	b += (b < a) & 1.f;
 	return b;
 }
 using std::round;
 inline float_4 round(float_4 a) {
 	return float_4(sse_mathfun_round_ps(a.v));
 	a += ifelse(a < 0, -0.5f, 0.5f);
 	float_4 b = trunc(a);
 	return b;
 }
 using std::fmod;
 inline float_4 fmod(float_4 a, float_4 b) {
 	return float_4(sse_mathfun_fmod_ps(a.v, b.v));
 	return a - trunc(a / b) * b;
 }
 using std::fabs;
 inline float_4 fabs(float_4 a) {
 	return float_4(sse_mathfun_fabs_ps(a.v));
 }
 using std::trunc;
 inline float_4 trunc(float_4 a) {
 	return float_4(sse_mathfun_trunc_ps(a.v));
 	// Sign bit
 	int32_4 mask = ~0x80000000;
 	return a & float_4::cast(mask);
 }
 using std::pow;
@@ -133,31 +198,6 @@ T pow(T a, int b) {
 	return p;
 }
 // Nonstandard functions
 inline float ifelse(bool cond, float a, float b) {
 	return cond ? a : b;
 }
 /** Given a mask, returns a if mask is 0xffffffff per element, b if mask is 0x00000000 */
 inline float_4 ifelse(float_4 mask, float_4 a, float_4 b) {
 	return (a & mask) | andnot(mask, b);
 }
 /** Returns the approximate reciprocal square root.
 Much faster than `1/sqrt(x)`.
 */
 inline float_4 rsqrt(float_4 x) {
 	return float_4(_mm_rsqrt_ps(x.v));
 }
 /** Returns the approximate reciprocal.
 Much faster than `1/x`.
 */
 inline float_4 rcp(float_4 x) {
 	return float_4(_mm_rcp_ps(x.v));
 }
 // From math.hpp
 using math::clamp;
@@ -186,18 +226,6 @@ inline float_4 sgn(float_4 x) {
 	return signbit | (nonzero & 1.f);
 }
 /** Given a mask `a`, returns a vector with each element either 0's or 1's depending on the mask bit. */
 template <typename T>
 inline T movemaskInverse(int a);
 template <>
 inline float_4 movemaskInverse<float_4>(int x) {
 	__m128i msk8421 = _mm_set_epi32(8, 4, 2, 1);
 	__m128i x_bc = _mm_set1_epi32(x);
 	__m128i t = _mm_and_si128(x_bc, msk8421);
 	return float_4(_mm_castsi128_ps(_mm_cmpeq_epi32(x_bc, t)));
 }
 } // namespace simd
 } // namespace rack
--- a/include/simd/sse_mathfun.h
+++ b/include/simd/sse_mathfun.h
@@ -1,4 +1,3 @@
 #pragma once
 /* Modified version of http://gruntthepeon.free.fr/ssemath/ for VCV Rack.
 The following changes were made.
@@ -6,7 +5,7 @@ The following changes were made.
 - Make all functions inline since this is a header file.
 - Remove non-SSE2 code, since Rack assumes SSE2 CPUs.
 - Move `const static` variables to function variables for clarity. See https://stackoverflow.com/a/52139901/272642 for explanation of why the performance is not worse.
 - Change header file to <emmintrin.h> since we're using SSE2 intrinsics.
 - Change header file to <pmmintrin.h> since we're using SSE2 intrinsics.
 - Prefix functions with `sse_mathfun_`.
 - Add floor, ceil, fmod.
@@ -43,8 +42,7 @@ This derived source file is released under the zlib license.
  (this is the zlib license)
 */
 #pragma once
 #include <pmmintrin.h>
@@ -376,7 +374,7 @@ inline __m128 sse_mathfun_cos_ps(__m128 x) { // any x
 /* since sin_ps and cos_ps are almost identical, sincos_ps could replace both of them..
   it is almost as fast, and gives you a free cosine with your sine */
 inline void sse_mathfun_sincos_ps(__m128 x, __m128 *s, __m128 *c) {
 inline void sse_mathfun_sincos_ps(__m128 x, __m128* s, __m128* c) {
 	__m128 xmm1, xmm2, xmm3 = _mm_setzero_ps(), sign_bit_sin, y;
 	__m128i emm0, emm2, emm4;
 	sign_bit_sin = x;
@@ -470,45 +468,3 @@ inline void sse_mathfun_sincos_ps(__m128 x, __m128 *s, __m128 *c) {
 	*s = _mm_xor_ps(xmm1, sign_bit_sin);
 	*c = _mm_xor_ps(xmm2, sign_bit_cos);
 }
 inline __m128 sse_mathfun_trunc_ps(__m128 a) {
 	return _mm_cvtepi32_ps(_mm_cvttps_epi32(a));
 }
 inline __m128 sse_mathfun_floor_ps(__m128 a) {
 	__m128 b = sse_mathfun_trunc_ps(a);
 	// If b > a, subtract 1 fom b
 	b = _mm_sub_ps(b, _mm_and_ps(_mm_cmpgt_ps(b, a), sse_mathfun_one_ps()));
 	return b;
 }
 inline __m128 sse_mathfun_ceil_ps(__m128 a) {
 	__m128 b = sse_mathfun_trunc_ps(a);
 	// If b < a, add 1 to b
 	b = _mm_add_ps(b, _mm_and_ps(_mm_cmplt_ps(b, a), sse_mathfun_one_ps()));
 	return b;
 }
 inline __m128 sse_mathfun_round_ps(__m128 a) {
 	// TODO Incorrect for -0.5, -1.5, etc.
 	return sse_mathfun_floor_ps(_mm_add_ps(a, _mm_set_ps1(0.5f)));
 }
 inline __m128 sse_mathfun_fmod_ps(__m128 a, __m128 b) {
 	__m128 c = _mm_div_ps(a, b);
 	c = sse_mathfun_trunc_ps(c);
 	c = _mm_mul_ps(c, b);
 	return _mm_sub_ps(a, c);
 }
 inline __m128 sse_mathfun_fabs_ps(__m128 a) {
 	__m128i minus1 = _mm_set1_epi32(-1);
 	__m128 abs_mask = _mm_castsi128_ps(_mm_srli_epi32(minus1, 1));
 	return _mm_and_ps(abs_mask, a);
 }
--- a/include/simd/sse_mathfun_extension.h
+++ b/include/simd/sse_mathfun_extension.h
@@ -0,0 +1,295 @@
 /* Modified version of https://github.com/to-miz/sse_mathfun_extension for VCV Rack.
 The following changes were made.
 - Make functions inline.
 - Change global constants to function-scope.
 This derived source file is released under the zlib license.
 */
 /*
 sse_mathfun_extension.h - zlib license
 Written by Tolga Mizrak 2016
 Extension of sse_mathfun.h, which is written by Julien Pommier
 Based on the corresponding algorithms of the cephes math library
 This is written as an extension to sse_mathfun.h instead of modifying it, just because I didn't want
 to maintain a modified version of the original library. This way switching to a newer version of the
 library won't be a hassle.
 Note that non SSE2 implementations of tan_ps, atan_ps, cot_ps and atan2_ps are not implemented yet.
 As such, currently you need to #define USE_SSE2 to compile.
 With tan_ps, cot_ps you get good precision on input ranges that are further away from the domain
 borders (-PI/2, PI/2 for tan and 0, 1 for cot). See the results on the deviations for these
 functions on my machine:
 checking tan on [-0.25*Pi, 0.25*Pi]
 max deviation from tanf(x): 1.19209e-07 at 0.250000006957*Pi, max deviation from cephes_tan(x):
 5.96046e-08
   ->> precision OK for the tan_ps <<-
 checking tan on [-0.49*Pi, 0.49*Pi]
 max deviation from tanf(x): 3.8147e-06 at -0.490000009841*Pi, max deviation from cephes_tan(x):
 9.53674e-07
   ->> precision OK for the tan_ps <<-
 checking cot on [0.2*Pi, 0.7*Pi]
 max deviation from cotf(x): 1.19209e-07 at 0.204303119606*Pi, max deviation from cephes_cot(x):
 1.19209e-07
   ->> precision OK for the cot_ps <<-
 checking cot on [0.01*Pi, 0.99*Pi]
 max deviation from cotf(x): 3.8147e-06 at 0.987876517942*Pi, max deviation from cephes_cot(x):
 9.53674e-07
   ->> precision OK for the cot_ps <<-
 With atan_ps and atan2_ps you get pretty good precision, atan_ps max deviation is < 2e-7 and
 atan2_ps max deviation is < 2.5e-7
 */
 /* Copyright (C) 2016 Tolga Mizrak
  This software is provided 'as-is', without any express or implied
  warranty.  In no event will the authors be held liable for any damages
  arising from the use of this software.
  Permission is granted to anyone to use this software for any purpose,
  including commercial applications, and to alter it and redistribute it
  freely, subject to the following restrictions:
  1. The origin of this software must not be misrepresented; you must not
 	 claim that you wrote the original software. If you use this software
 	 in a product, an acknowledgment in the product documentation would be
 	 appreciated but is not required.
  2. Altered source versions must be plainly marked as such, and must not be
 	 misrepresented as being the original software.
  3. This notice may not be removed or altered from any source distribution.
  (this is the zlib license)
 */
 #pragma once
 #include "sse_mathfun.h"
 inline __m128 sse_mathfun_tancot_ps(__m128 x, int cotFlag) {
 	__m128 p0 = _mm_set_ps1(9.38540185543E-3);
 	__m128 p1 = _mm_set_ps1(3.11992232697E-3);
 	__m128 p2 = _mm_set_ps1(2.44301354525E-2);
 	__m128 p3 = _mm_set_ps1(5.34112807005E-2);
 	__m128 p4 = _mm_set_ps1(1.33387994085E-1);
 	__m128 p5 = _mm_set_ps1(3.33331568548E-1);
 	__m128 xmm1, xmm2 = _mm_setzero_ps(), xmm3, sign_bit, y;
 	__m128i emm2;
 	sign_bit = x;
 	/* take the absolute value */
 	__m128 sign_mask = _mm_castsi128_ps(_mm_set1_epi32(0x80000000));
 	__m128 inv_sign_mask = _mm_castsi128_ps(_mm_set1_epi32(~0x80000000));
 	x = _mm_and_ps(x, inv_sign_mask);
 	/* extract the sign bit (upper one) */
 	sign_bit = _mm_and_ps(sign_bit, sign_mask);
 	/* scale by 4/Pi */
 	__m128 cephes_FOPI = _mm_set_ps1(1.27323954473516);
 	y = _mm_mul_ps(x, cephes_FOPI);
 	/* store the integer part of y in mm0 */
 	emm2 = _mm_cvttps_epi32(y);
 	/* j=(j+1) & (~1) (see the cephes sources) */
 	emm2 = _mm_add_epi32(emm2, _mm_set1_epi32(1));
 	emm2 = _mm_and_si128(emm2, _mm_set1_epi32(~1));
 	y = _mm_cvtepi32_ps(emm2);
 	emm2 = _mm_and_si128(emm2, _mm_set1_epi32(2));
 	emm2 = _mm_cmpeq_epi32(emm2, _mm_setzero_si128());
 	__m128 poly_mask = _mm_castsi128_ps(emm2);
 	/* The magic pass: "Extended precision modular arithmetic"
 	   x = ((x - y * DP1) - y * DP2) - y * DP3; */
 	__m128 minus_cephes_DP1 = _mm_set_ps1(-0.78515625);
 	__m128 minus_cephes_DP2 = _mm_set_ps1(-2.4187564849853515625e-4);
 	__m128 minus_cephes_DP3 = _mm_set_ps1(-3.77489497744594108e-8);
 	xmm1 = minus_cephes_DP1;
 	xmm2 = minus_cephes_DP2;
 	xmm3 = minus_cephes_DP3;
 	xmm1 = _mm_mul_ps(y, xmm1);
 	xmm2 = _mm_mul_ps(y, xmm2);
 	xmm3 = _mm_mul_ps(y, xmm3);
 	__m128 z = _mm_add_ps(x, xmm1);
 	z = _mm_add_ps(z, xmm2);
 	z = _mm_add_ps(z, xmm3);
 	__m128 zz = _mm_mul_ps(z, z);
 	y = p0;
 	y = _mm_mul_ps(y, zz);
 	y = _mm_add_ps(y, p1);
 	y = _mm_mul_ps(y, zz);
 	y = _mm_add_ps(y, p2);
 	y = _mm_mul_ps(y, zz);
 	y = _mm_add_ps(y, p3);
 	y = _mm_mul_ps(y, zz);
 	y = _mm_add_ps(y, p4);
 	y = _mm_mul_ps(y, zz);
 	y = _mm_add_ps(y, p5);
 	y = _mm_mul_ps(y, zz);
 	y = _mm_mul_ps(y, z);
 	y = _mm_add_ps(y, z);
 	__m128 y2;
 	if (cotFlag) {
 		y2 = _mm_xor_ps(y, sign_mask);
 		/* y = _mm_rcp_ps(y); */
 		/* using _mm_rcp_ps here loses on way too much precision, better to do a div */
 		y = _mm_div_ps(_mm_set_ps1(1.f), y);
 	}
 	else {
 		/* y2 = _mm_rcp_ps(y); */
 		/* using _mm_rcp_ps here loses on way too much precision, better to do a div */
 		y2 = _mm_div_ps(_mm_set_ps1(1.f), y);
 		y2 = _mm_xor_ps(y2, sign_mask);
 	}
 	/* select the correct result from the two polynoms */
 	xmm3 = poly_mask;
 	y = _mm_and_ps(xmm3, y);
 	y2 = _mm_andnot_ps(xmm3, y2);
 	y = _mm_or_ps(y, y2);
 	/* update the sign */
 	y = _mm_xor_ps(y, sign_bit);
 	return y;
 }
 inline __m128 sse_mathfun_tan_ps(__m128 x) {
 	return sse_mathfun_tancot_ps(x, 0);
 }
 inline __m128 sse_mathfun_cot_ps(__m128 x) {
 	return sse_mathfun_tancot_ps(x, 1);
 }
 inline __m128 sse_mathfun_atan_ps(__m128 x) {
 	__m128 sign_mask = _mm_castsi128_ps(_mm_set1_epi32(0x80000000));
 	__m128 inv_sign_mask = _mm_castsi128_ps(_mm_set1_epi32(~0x80000000));
 	__m128 atanrange_hi = _mm_set_ps1(2.414213562373095);
 	__m128 atanrange_lo = _mm_set_ps1(0.4142135623730950);
 	__m128 cephes_PIO2F = _mm_set_ps1(1.5707963267948966192);
 	__m128 cephes_PIO4F = _mm_set_ps1(0.7853981633974483096);
 	__m128 atancof_p0 = _mm_set_ps1(8.05374449538e-2);
 	__m128 atancof_p1 = _mm_set_ps1(1.38776856032E-1);
 	__m128 atancof_p2 = _mm_set_ps1(1.99777106478E-1);
 	__m128 atancof_p3 = _mm_set_ps1(3.33329491539E-1);
 	__m128 sign_bit, y;
 	sign_bit = x;
 	/* take the absolute value */
 	x = _mm_and_ps(x, inv_sign_mask);
 	/* extract the sign bit (upper one) */
 	sign_bit = _mm_and_ps(sign_bit, sign_mask);
 	/* range reduction, init x and y depending on range */
 	/* x > 2.414213562373095 */
 	__m128 cmp0 = _mm_cmpgt_ps(x, atanrange_hi);
 	/* x > 0.4142135623730950 */
 	__m128 cmp1 = _mm_cmpgt_ps(x, atanrange_lo);
 	/* x > 0.4142135623730950 && !(x > 2.414213562373095) */
 	__m128 cmp2 = _mm_andnot_ps(cmp0, cmp1);
 	/* -(1.0/x) */
 	__m128 y0 = _mm_and_ps(cmp0, cephes_PIO2F);
 	__m128 x0 = _mm_div_ps(_mm_set_ps1(1.f), x);
 	x0 = _mm_xor_ps(x0, sign_mask);
 	__m128 y1 = _mm_and_ps(cmp2, cephes_PIO4F);
 	/* (x-1.0)/(x+1.0) */
 	__m128 x1_o = _mm_sub_ps(x, _mm_set_ps1(1.f));
 	__m128 x1_u = _mm_add_ps(x, _mm_set_ps1(1.f));
 	__m128 x1 = _mm_div_ps(x1_o, x1_u);
 	__m128 x2 = _mm_and_ps(cmp2, x1);
 	x0 = _mm_and_ps(cmp0, x0);
 	x2 = _mm_or_ps(x2, x0);
 	cmp1 = _mm_or_ps(cmp0, cmp2);
 	x2 = _mm_and_ps(cmp1, x2);
 	x = _mm_andnot_ps(cmp1, x);
 	x = _mm_or_ps(x2, x);
 	y = _mm_or_ps(y0, y1);
 	__m128 zz = _mm_mul_ps(x, x);
 	__m128 acc = atancof_p0;
 	acc = _mm_mul_ps(acc, zz);
 	acc = _mm_sub_ps(acc, atancof_p1);
 	acc = _mm_mul_ps(acc, zz);
 	acc = _mm_add_ps(acc, atancof_p2);
 	acc = _mm_mul_ps(acc, zz);
 	acc = _mm_sub_ps(acc, atancof_p3);
 	acc = _mm_mul_ps(acc, zz);
 	acc = _mm_mul_ps(acc, x);
 	acc = _mm_add_ps(acc, x);
 	y = _mm_add_ps(y, acc);
 	/* update the sign */
 	y = _mm_xor_ps(y, sign_bit);
 	return y;
 }
 inline __m128 sse_mathfun_atan2_ps(__m128 y, __m128 x) {
 	__m128 sign_mask = _mm_castsi128_ps(_mm_set1_epi32(0x80000000));
 	__m128 x_eq_0 = _mm_cmpeq_ps(x, _mm_setzero_ps());
 	__m128 x_gt_0 = _mm_cmpgt_ps(x, _mm_setzero_ps());
 	__m128 x_le_0 = _mm_cmple_ps(x, _mm_setzero_ps());
 	__m128 y_eq_0 = _mm_cmpeq_ps(y, _mm_setzero_ps());
 	__m128 x_lt_0 = _mm_cmplt_ps(x, _mm_setzero_ps());
 	__m128 y_lt_0 = _mm_cmplt_ps(y, _mm_setzero_ps());
 	__m128 cephes_PIF = _mm_set_ps1(3.141592653589793238);
 	__m128 cephes_PIO2F = _mm_set_ps1(1.5707963267948966192);
 	__m128 zero_mask = _mm_and_ps(x_eq_0, y_eq_0);
 	__m128 zero_mask_other_case = _mm_and_ps(y_eq_0, x_gt_0);
 	zero_mask = _mm_or_ps(zero_mask, zero_mask_other_case);
 	__m128 pio2_mask = _mm_andnot_ps(y_eq_0, x_eq_0);
 	__m128 pio2_mask_sign = _mm_and_ps(y_lt_0, sign_mask);
 	__m128 pio2_result = cephes_PIO2F;
 	pio2_result = _mm_xor_ps(pio2_result, pio2_mask_sign);
 	pio2_result = _mm_and_ps(pio2_mask, pio2_result);
 	__m128 pi_mask = _mm_and_ps(y_eq_0, x_le_0);
 	__m128 pi = cephes_PIF;
 	__m128 pi_result = _mm_and_ps(pi_mask, pi);
 	__m128 swap_sign_mask_offset = _mm_and_ps(x_lt_0, y_lt_0);
 	swap_sign_mask_offset = _mm_and_ps(swap_sign_mask_offset, sign_mask);
 	__m128 offset0 = _mm_setzero_ps();
 	__m128 offset1 = cephes_PIF;
 	offset1 = _mm_xor_ps(offset1, swap_sign_mask_offset);
 	__m128 offset = _mm_andnot_ps(x_lt_0, offset0);
 	offset = _mm_and_ps(x_lt_0, offset1);
 	__m128 arg = _mm_div_ps(y, x);
 	__m128 atan_result = sse_mathfun_atan_ps(arg);
 	atan_result = _mm_add_ps(atan_result, offset);
 	/* select between zero_result, pio2_result and atan_result */
 	__m128 result = _mm_andnot_ps(zero_mask, pio2_result);
 	atan_result = _mm_andnot_ps(pio2_mask, atan_result);
 	atan_result = _mm_andnot_ps(pio2_mask, atan_result);
 	result = _mm_or_ps(result, atan_result);
 	result = _mm_or_ps(result, pi_result);
 	return result;
 }
--- a/include/simd/vector.hpp
+++ b/include/simd/vector.hpp
@@ -63,13 +63,13 @@ struct Vector<float, 4> {
 	/** Returns a vector with all 1 bits. */
 	static Vector mask() {
    return _mm_castsi128_ps(_mm_cmpeq_epi32(_mm_setzero_si128(), _mm_setzero_si128()));
 		return _mm_castsi128_ps(_mm_cmpeq_epi32(_mm_setzero_si128(), _mm_setzero_si128()));
 	}
 	/** Reads an array of 4 values.
 	On little-endian machines (e.g. x86), the order is reversed, so `x[0]` corresponds to `vector.s[3]`.
 	*/
 	static Vector load(const float *x) {
 	static Vector load(const float* x) {
 		/*
 		My benchmarks show that _mm_loadu_ps() performs equally as fast as _mm_load_ps() when data is actually aligned.
 		This post seems to agree. https://stackoverflow.com/a/20265193/272642
@@ -81,12 +81,16 @@ struct Vector<float, 4> {
 	/** Writes an array of 4 values.
 	On little-endian machines (e.g. x86), the order is reversed, so `x[0]` corresponds to `vector.s[3]`.
 	*/
 	void store(float *x) {
 	void store(float* x) {
 		_mm_storeu_ps(x, v);
 	}
 	float &operator[](int i) {return s[i];}
 	const float &operator[](int i) const {return s[i];}
 	float& operator[](int i) {
 		return s[i];
 	}
 	const float& operator[](int i) const {
 		return s[i];
 	}
 	// Conversions
 	Vector(Vector<int32_t, 4> a);
@@ -119,18 +123,22 @@ struct Vector<int32_t, 4> {
 	static Vector mask() {
 		return Vector(_mm_cmpeq_epi32(_mm_setzero_si128(), _mm_setzero_si128()));
 	}
 	static Vector load(const int32_t *x) {
 	static Vector load(const int32_t* x) {
 		// HACK
 		// Use _mm_loadu_si128() because GCC doesn't support _mm_loadu_si32()
 		return Vector(_mm_loadu_si128((__m128i*) x));
 	}
 	void store(int32_t *x) {
 	void store(int32_t* x) {
 		// HACK
 		// Use _mm_storeu_si128() because GCC doesn't support _mm_storeu_si32()
 		_mm_storeu_si128((__m128i*) x, v);
 	}
 	int32_t &operator[](int i) {return s[i];}
 	const int32_t &operator[](int i) const {return s[i];}
 	int32_t& operator[](int i) {
 		return s[i];
 	}
 	const int32_t& operator[](int i) const {
 		return s[i];
 	}
 	Vector(Vector<float, 4> a);
 	static Vector cast(Vector<float, 4> a);
 };
@@ -144,7 +152,7 @@ inline Vector<float, 4>::Vector(Vector<int32_t, 4> a) {
 }
 inline Vector<int32_t, 4>::Vector(Vector<float, 4> a) {
 	v = _mm_cvtps_epi32(a.v);
 	v = _mm_cvttps_epi32(a.v);
 }
 inline Vector<float, 4> Vector<float, 4>::cast(Vector<int32_t, 4> a) {
@@ -160,21 +168,21 @@ inline Vector<int32_t, 4> Vector<int32_t, 4>::cast(Vector<float, 4> a) {
 /** `~a & b` */
 inline Vector<float, 4> andnot(const Vector<float, 4> &a, const Vector<float, 4> &b) {
 inline Vector<float, 4> andnot(const Vector<float, 4>& a, const Vector<float, 4>& b) {
 	return Vector<float, 4>(_mm_andnot_ps(a.v, b.v));
 }
 /** Returns an integer with each bit corresponding to the most significant bit of each element.
 For example, `movemask(float_4::mask())` returns 0xf.
 */
 inline int movemask(const Vector<float, 4> &a) {
 inline int movemask(const Vector<float, 4>& a) {
 	return _mm_movemask_ps(a.v);
 }
 /** Returns an integer with each bit corresponding to the most significant bit of each byte.
 For example, `movemask(int32_4::mask())` returns 0xffff.
 */
 inline int movemask(const Vector<int32_t, 4> &a) {
 inline int movemask(const Vector<int32_t, 4>& a) {
 	return _mm_movemask_epi8(a.v);
 }
@@ -250,7 +258,7 @@ DECLARE_VECTOR_OPERATOR_INFIX(float, 4, operator==, _mm_cmpeq_ps)
 DECLARE_VECTOR_OPERATOR_INFIX(int32_t, 4, operator==, _mm_cmpeq_epi32)
 DECLARE_VECTOR_OPERATOR_INFIX(float, 4, operator>=, _mm_cmpge_ps)
 inline Vector<int32_t, 4> operator>=(const Vector<int32_t, 4> &a, const Vector<int32_t, 4> &b) {
 inline Vector<int32_t, 4> operator>=(const Vector<int32_t, 4>& a, const Vector<int32_t, 4>& b) {
 	return Vector<int32_t, 4>(_mm_cmpgt_epi32(a.v, b.v)) ^ Vector<int32_t, 4>::mask();
 }
@@ -258,7 +266,7 @@ DECLARE_VECTOR_OPERATOR_INFIX(float, 4, operator>, _mm_cmpgt_ps)
 DECLARE_VECTOR_OPERATOR_INFIX(int32_t, 4, operator>, _mm_cmpgt_epi32)
 DECLARE_VECTOR_OPERATOR_INFIX(float, 4, operator<=, _mm_cmple_ps)
 inline Vector<int32_t, 4> operator<=(const Vector<int32_t, 4> &a, const Vector<int32_t, 4> &b) {
 inline Vector<int32_t, 4> operator<=(const Vector<int32_t, 4>& a, const Vector<int32_t, 4>& b) {
 	return Vector<int32_t, 4>(_mm_cmplt_epi32(a.v, b.v)) ^ Vector<int32_t, 4>::mask();
 }
@@ -266,78 +274,88 @@ DECLARE_VECTOR_OPERATOR_INFIX(float, 4, operator<, _mm_cmplt_ps)
 DECLARE_VECTOR_OPERATOR_INFIX(int32_t, 4, operator<, _mm_cmplt_epi32)
 DECLARE_VECTOR_OPERATOR_INFIX(float, 4, operator!=, _mm_cmpneq_ps)
 inline Vector<int32_t, 4> operator!=(const Vector<int32_t, 4> &a, const Vector<int32_t, 4> &b) {
 inline Vector<int32_t, 4> operator!=(const Vector<int32_t, 4>& a, const Vector<int32_t, 4>& b) {
 	return Vector<int32_t, 4>(_mm_cmpeq_epi32(a.v, b.v)) ^ Vector<int32_t, 4>::mask();
 }
 /** `+a` */
 inline Vector<float, 4> operator+(const Vector<float, 4> &a) {
 inline Vector<float, 4> operator+(const Vector<float, 4>& a) {
 	return a;
 }
 inline Vector<int32_t, 4> operator+(const Vector<int32_t, 4> &a) {
 inline Vector<int32_t, 4> operator+(const Vector<int32_t, 4>& a) {
 	return a;
 }
 /** `-a` */
 inline Vector<float, 4> operator-(const Vector<float, 4> &a) {
 inline Vector<float, 4> operator-(const Vector<float, 4>& a) {
 	return 0.f - a;
 }
 inline Vector<int32_t, 4> operator-(const Vector<int32_t, 4> &a) {
 inline Vector<int32_t, 4> operator-(const Vector<int32_t, 4>& a) {
 	return 0 - a;
 }
 /** `++a` */
 inline Vector<float, 4> &operator++(Vector<float, 4> &a) {
 inline Vector<float, 4>& operator++(Vector<float, 4>& a) {
 	a += 1.f;
 	return a;
 }
 inline Vector<int32_t, 4> &operator++(Vector<int32_t, 4> &a) {
 inline Vector<int32_t, 4>& operator++(Vector<int32_t, 4>& a) {
 	a += 1;
 	return a;
 }
 /** `--a` */
 inline Vector<float, 4> &operator--(Vector<float, 4> &a) {
 inline Vector<float, 4>& operator--(Vector<float, 4>& a) {
 	a -= 1.f;
 	return a;
 }
 inline Vector<int32_t, 4> &operator--(Vector<int32_t, 4> &a) {
 inline Vector<int32_t, 4>& operator--(Vector<int32_t, 4>& a) {
 	a -= 1;
 	return a;
 }
 /** `a++` */
 inline Vector<float, 4> operator++(Vector<float, 4> &a, int) {
 inline Vector<float, 4> operator++(Vector<float, 4>& a, int) {
 	Vector<float, 4> b = a;
 	++a;
 	return b;
 }
 inline Vector<int32_t, 4> operator++(Vector<int32_t, 4> &a, int) {
 inline Vector<int32_t, 4> operator++(Vector<int32_t, 4>& a, int) {
 	Vector<int32_t, 4> b = a;
 	++a;
 	return b;
 }
 /** `a--` */
 inline Vector<float, 4> operator--(Vector<float, 4> &a, int) {
 inline Vector<float, 4> operator--(Vector<float, 4>& a, int) {
 	Vector<float, 4> b = a;
 	--a;
 	return b;
 }
 inline Vector<int32_t, 4> operator--(Vector<int32_t, 4> &a, int) {
 inline Vector<int32_t, 4> operator--(Vector<int32_t, 4>& a, int) {
 	Vector<int32_t, 4> b = a;
 	--a;
 	return b;
 }
 /** `~a` */
 inline Vector<float, 4> operator~(const Vector<float, 4> &a) {
 inline Vector<float, 4> operator~(const Vector<float, 4>& a) {
 	return a ^ Vector<float, 4>::mask();
 }
 inline Vector<int32_t, 4> operator~(const Vector<int32_t, 4> &a) {
 inline Vector<int32_t, 4> operator~(const Vector<int32_t, 4>& a) {
 	return a ^ Vector<int32_t, 4>::mask();
 }
 /** `a << b` */
 inline Vector<int32_t, 4> operator<<(const Vector<int32_t, 4>& a, const int& b) {
 	return Vector<int32_t, 4>(_mm_slli_epi32(a.v, b));
 }
 /** `a >> b` */
 inline Vector<int32_t, 4> operator>>(const Vector<int32_t, 4>& a, const int& b) {
 	return Vector<int32_t, 4>(_mm_srli_epi32(a.v, b));
 }
 // Typedefs
--- a/include/string.hpp
+++ b/include/string.hpp
@@ -11,55 +11,65 @@ namespace string {
 /** Converts a UTF-16/32 string (depending on the size of wchar_t) to a UTF-8 string. */
 std::string fromWstring(const std::wstring &s);
 std::wstring toWstring(const std::string &s);
 std::string fromWstring(const std::wstring& s);
 std::wstring toWstring(const std::string& s);
 /** Converts a `printf()` format string and optional arguments into a std::string.
 Remember that "%s" must reference a `char *`, so use `.c_str()` for `std::string`s, otherwise you might get binary garbage.
 */
 std::string f(const char *format, ...);
 std::string f(const char* format, ...);
 /** Replaces all characters to lowercase letters */
 std::string lowercase(const std::string &s);
 std::string lowercase(const std::string& s);
 /** Replaces all characters to uppercase letters */
 std::string uppercase(const std::string &s);
 std::string uppercase(const std::string& s);
 /** Removes whitespace from beginning and end of string. */
 std::string trim(const std::string &s);
 std::string trim(const std::string& s);
 /** Truncates and adds "..." to a string, not exceeding `len` characters */
 std::string ellipsize(const std::string &s, size_t len);
 std::string ellipsizePrefix(const std::string &s, size_t len);
 bool startsWith(const std::string &str, const std::string &prefix);
 bool endsWith(const std::string &str, const std::string &suffix);
 std::string ellipsize(const std::string& s, size_t len);
 std::string ellipsizePrefix(const std::string& s, size_t len);
 bool startsWith(const std::string& str, const std::string& prefix);
 bool endsWith(const std::string& str, const std::string& suffix);
 /** Extracts the directory of the path.
 Example: directory("dir/file.txt") // "dir"
 Calls POSIX dirname().
 */
 std::string directory(const std::string &path);
 std::string directory(const std::string& path);
 /** Extracts the filename of the path.
 Example: directory("dir/file.txt") // "file.txt"
 Calls POSIX basename().
 */
 std::string filename(const std::string &path);
 std::string filename(const std::string& path);
 /** Extracts the portion of a filename without the extension.
 Example: filenameBase("file.txt") // "file"
 Note: Only works on filenames. Call filename(path) to get the filename of the path.
 */
 std::string filenameBase(const std::string &filename);
 std::string filenameBase(const std::string& filename);
 /** Extracts the extension of a filename.
 Example: filenameExtension("file.txt") // "txt"
 Note: Only works on filenames. Call filename(path) to get the filename of the path.
 */
 std::string filenameExtension(const std::string &filename);
 std::string filenameExtension(const std::string& filename);
 /** Returns the canonicalized absolute path pointed to by `path`, following symlinks.
 Returns "" if the symbol is not found.
 */
 std::string absolutePath(const std::string &path);
 std::string absolutePath(const std::string& path);
 /** Scores how well a query matches a string.
 A score of 0 means no match.
 The score is arbitrary and is only meaningful for sorting.
 */
 float fuzzyScore(const std::string &s, const std::string &query);
 float fuzzyScore(const std::string& s, const std::string& query);
 /** Converts a byte array to a Base64-encoded string.
 https://en.wikipedia.org/wiki/Base64
 */
 std::string toBase64(const uint8_t* data, size_t len);
 /** Converts a Base64-encoded string to a byte array.
 `outLen` is set to the length of the byte array.
 If non-NULL, caller must delete[] the result.
 */
 uint8_t* fromBase64(const std::string& str, size_t* outLen);
 struct CaseInsensitiveCompare {
 	bool operator()(const std::string &a, const std::string &b) const {
 	bool operator()(const std::string& a, const std::string& b) const {
 		return lowercase(a) < lowercase(b);
 	}
 };
--- a/include/svg.hpp
+++ b/include/svg.hpp
@@ -7,7 +7,7 @@
 namespace rack {
 void svgDraw(NVGcontext *vg, NSVGimage *svg);
 void svgDraw(NVGcontext* vg, NSVGimage* svg);
 } // namespace rack
--- a/include/system.hpp
+++ b/include/system.hpp
@@ -12,38 +12,40 @@ namespace system {
 /** Returns a list of all entries (directories, files, symbols) in a directory. */
 std::list<std::string> getEntries(const std::string &path);
 std::list<std::string> getEntries(const std::string& path);
 /** Returns whether the given path is a file. */
 bool isFile(const std::string &path);
 bool isFile(const std::string& path);
 /** Returns whether the given path is a directory. */
 bool isDirectory(const std::string &path);
 bool isDirectory(const std::string& path);
 /** Moves a file. */
 void moveFile(const std::string &srcPath, const std::string &destPath);
 void moveFile(const std::string& srcPath, const std::string& destPath);
 /** Copies a file. */
 void copyFile(const std::string &srcPath, const std::string &destPath);
 void copyFile(const std::string& srcPath, const std::string& destPath);
 /** Creates a directory.
 The parent directory must exist.
 */
 void createDirectory(const std::string &path);
 void createDirectory(const std::string& path);
 /** Returns the number of logical simultaneous multithreading (SMT) (e.g. Intel Hyperthreaded) threads on the CPU. */
 int getLogicalCoreCount();
 /** Sets a name of the current thread for debuggers and OS-specific process viewers. */
 void setThreadName(const std::string &name);
 void setThreadName(const std::string& name);
 /** Sets the current thread to be high-priority. */
 void setThreadRealTime(bool realTime);
 /** Returns the number of seconds the current thread has been active. */
 double getThreadTime();
 /** Returns the caller's human-readable stack trace with "\n"-separated lines. */
 std::string getStackTrace();
 /** Opens a URL, also happens to work with PDFs and folders.
 Shell injection is possible, so make sure the URL is trusted or hard coded.
 May block, so open in a new thread.
 */
 void openBrowser(const std::string &url);
 void openBrowser(const std::string& url);
 /** Opens Windows Explorer, Finder, etc at the folder location. */
 void openFolder(const std::string &path);
 void openFolder(const std::string& path);
 /** Runs an executable without blocking.
 The launched process will continue running if the current process is closed.
 */
 void runProcessDetached(const std::string &path);
 void runProcessDetached(const std::string& path);
 std::string getOperatingSystemInfo();
--- a/include/tag.hpp
+++ b/include/tag.hpp
@@ -0,0 +1,28 @@
 #pragma once
 #include <common.hpp>
 #include <vector>
 namespace rack {
 namespace tag {
 /** List of tags and their aliases.
 The first alias of each tag `tag[tagId][0]` is the "canonical" alias.
 It is guaranteed to exist and should be used as the human-readable form.
 This list is manually alphabetized by the canonical alias.
 */
 extern const std::vector<std::vector<std::string>> tagAliases;
 /** Searches for a tag ID.
 Searches tag aliases.
 Case-insensitive.
 Returns -1 if not found.
 */
 int findId(const std::string& tag);
 } // namespace tag
 } // namespace rack
--- a/include/ui/Button.hpp
+++ b/include/ui/Button.hpp
@@ -11,13 +11,13 @@ namespace ui {
 struct Button : widget::OpaqueWidget {
 	std::string text;
 	/** Not owned. Tracks the pressed state of the button.*/
 	Quantity *quantity = NULL;
 	Quantity* quantity = NULL;
 	Button();
 	void draw(const DrawArgs &args) override;
 	void onDragStart(const event::DragStart &e) override;
 	void onDragEnd(const event::DragEnd &e) override;
 	void onDragDrop(const event::DragDrop &e) override;
 	void draw(const DrawArgs& args) override;
 	void onDragStart(const event::DragStart& e) override;
 	void onDragEnd(const event::DragEnd& e) override;
 	void onDragDrop(const event::DragDrop& e) override;
 };
--- a/include/ui/ChoiceButton.hpp
+++ b/include/ui/ChoiceButton.hpp
@@ -8,7 +8,7 @@ namespace ui {
 struct ChoiceButton : Button {
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
--- a/include/ui/IconButton.hpp
+++ b/include/ui/IconButton.hpp
@@ -10,12 +10,14 @@ namespace ui {
 struct IconButton : Button {
 	widget::FramebufferWidget *fw;
 	widget::SvgWidget *sw;
 	widget::FramebufferWidget* fw;
 	widget::SvgWidget* sw;
 	IconButton();
 	void setSvg(std::shared_ptr<Svg> svg);
 	DEPRECATED void setSVG(std::shared_ptr<Svg> svg) {setSvg(svg);}
 	DEPRECATED void setSVG(std::shared_ptr<Svg> svg) {
 		setSvg(svg);
 	}
 };
--- a/include/ui/Label.hpp
+++ b/include/ui/Label.hpp
@@ -20,7 +20,7 @@ struct Label : widget::Widget {
 	Alignment alignment = LEFT_ALIGNMENT;
 	Label();
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
--- a/include/ui/Menu.hpp
+++ b/include/ui/Menu.hpp
@@ -9,17 +9,17 @@ namespace ui {
 struct Menu : widget::OpaqueWidget {
 	Menu *parentMenu = NULL;
 	Menu *childMenu = NULL;
 	Menu* parentMenu = NULL;
 	Menu* childMenu = NULL;
 	/** The entry which created the child menu */
 	MenuEntry *activeEntry = NULL;
 	MenuEntry* activeEntry = NULL;
 	Menu();
 	~Menu();
 	void setChildMenu(Menu *menu);
 	void setChildMenu(Menu* menu);
 	void step() override;
 	void draw(const DrawArgs &args) override;
 	void onHoverScroll(const event::HoverScroll &e) override;
 	void draw(const DrawArgs& args) override;
 	void onHoverScroll(const event::HoverScroll& e) override;
 };
--- a/include/ui/MenuItem.hpp
+++ b/include/ui/MenuItem.hpp
@@ -15,12 +15,14 @@ struct MenuItem : MenuEntry {
 	bool disabled = false;
 	bool active = false;
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 	void step() override;
 	void onEnter(const event::Enter &e) override;
 	void onDragDrop(const event::DragDrop &e) override;
 	void onEnter(const event::Enter& e) override;
 	void onDragDrop(const event::DragDrop& e) override;
 	void doAction();
 	virtual Menu *createChildMenu() {return NULL;}
 	virtual Menu* createChildMenu() {
 		return NULL;
 	}
 };
--- a/include/ui/MenuLabel.hpp
+++ b/include/ui/MenuLabel.hpp
@@ -10,7 +10,7 @@ namespace ui {
 struct MenuLabel : MenuEntry {
 	std::string text;
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 	void step() override;
 };
--- a/include/ui/MenuOverlay.hpp
+++ b/include/ui/MenuOverlay.hpp
@@ -10,8 +10,8 @@ namespace ui {
 /** Deletes itself from parent when clicked */
 struct MenuOverlay : widget::OpaqueWidget {
 	void step() override;
 	void onButton(const event::Button &e) override;
 	void onHoverKey(const event::HoverKey &e) override;
 	void onButton(const event::Button& e) override;
 	void onHoverKey(const event::HoverKey& e) override;
 };
--- a/include/ui/MenuSeparator.hpp
+++ b/include/ui/MenuSeparator.hpp
@@ -9,7 +9,7 @@ namespace ui {
 struct MenuSeparator : MenuEntry {
 	MenuSeparator();
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
--- a/include/ui/PasswordField.hpp
+++ b/include/ui/PasswordField.hpp
@@ -8,7 +8,7 @@ namespace ui {
 struct PasswordField : TextField {
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
--- a/include/ui/ProgressBar.hpp
+++ b/include/ui/ProgressBar.hpp
@@ -10,10 +10,10 @@ namespace ui {
 struct ProgressBar : widget::Widget {
 	/** Not owned. Stores the progress value and label. */
 	Quantity *quantity = NULL;
 	Quantity* quantity = NULL;
 	ProgressBar();
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
--- a/include/ui/RadioButton.hpp
+++ b/include/ui/RadioButton.hpp
@@ -12,11 +12,11 @@ namespace ui {
 struct RadioButton : widget::OpaqueWidget {
 	/** Not owned. */
 	Quantity *quantity = NULL;
 	Quantity* quantity = NULL;
 	RadioButton();
 	void draw(const DrawArgs &args) override;
 	void onDragDrop(const event::DragDrop &e) override;
 	void draw(const DrawArgs& args) override;
 	void onDragDrop(const event::DragDrop& e) override;
 };
--- a/include/ui/ScrollBar.hpp
+++ b/include/ui/ScrollBar.hpp
@@ -18,10 +18,10 @@ struct ScrollBar : widget::OpaqueWidget {
 	float size = 0.0;
 	ScrollBar();
 	void draw(const DrawArgs &args) override;
 	void onDragStart(const event::DragStart &e) override;
 	void onDragMove(const event::DragMove &e) override;
 	void onDragEnd(const event::DragEnd &e) override;
 	void draw(const DrawArgs& args) override;
 	void onDragStart(const event::DragStart& e) override;
 	void onDragMove(const event::DragMove& e) override;
 	void onDragEnd(const event::DragEnd& e) override;
 };
--- a/include/ui/ScrollWidget.hpp
+++ b/include/ui/ScrollWidget.hpp
@@ -10,19 +10,19 @@ namespace ui {
 /** Handles a container with ScrollBar */
 struct ScrollWidget : widget::OpaqueWidget {
 	widget::Widget *container;
 	ScrollBar *horizontalScrollBar;
 	ScrollBar *verticalScrollBar;
 	widget::Widget* container;
 	ScrollBar* horizontalScrollBar;
 	ScrollBar* verticalScrollBar;
 	math::Vec offset;
 	ScrollWidget();
 	void scrollTo(math::Rect r);
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 	void step() override;
 	void onButton(const event::Button &e) override;
 	void onDragStart(const event::DragStart &e) override;
 	void onDragMove(const event::DragMove &e) override;
 	void onHoverScroll(const event::HoverScroll &e) override;
 	void onButton(const event::Button& e) override;
 	void onDragStart(const event::DragStart& e) override;
 	void onDragMove(const event::DragMove& e) override;
 	void onHoverScroll(const event::HoverScroll& e) override;
 };
--- a/include/ui/Slider.hpp
+++ b/include/ui/Slider.hpp
@@ -11,14 +11,14 @@ namespace ui {
 struct Slider : widget::OpaqueWidget {
 	/** Not owned. */
 	Quantity *quantity = NULL;
 	Quantity* quantity = NULL;
 	Slider();
 	void draw(const DrawArgs &args) override;
 	void onDragStart(const event::DragStart &e) override;
 	void onDragMove(const event::DragMove &e) override;
 	void onDragEnd(const event::DragEnd &e) override;
 	void onDoubleClick(const event::DoubleClick &e) override;
 	void draw(const DrawArgs& args) override;
 	void onDragStart(const event::DragStart& e) override;
 	void onDragMove(const event::DragMove& e) override;
 	void onDragEnd(const event::DragEnd& e) override;
 	void onDoubleClick(const event::DoubleClick& e) override;
 };
--- a/include/ui/TextField.hpp
+++ b/include/ui/TextField.hpp
@@ -20,11 +20,11 @@ struct TextField : widget::OpaqueWidget {
 	int selection = 0;
 	TextField();
 	void draw(const DrawArgs &args) override;
 	void onDragHover(const event::DragHover &e) override;
 	void onButton(const event::Button &e) override;
 	void onSelectText(const event::SelectText &e) override;
 	void onSelectKey(const event::SelectKey &e) override;
 	void draw(const DrawArgs& args) override;
 	void onDragHover(const event::DragHover& e) override;
 	void onButton(const event::Button& e) override;
 	void onSelectText(const event::SelectText& e) override;
 	void onSelectKey(const event::SelectKey& e) override;
 	/** Inserts text at the cursor, replacing the selection if necessary */
 	void insertText(std::string text);
--- a/include/ui/Tooltip.hpp
+++ b/include/ui/Tooltip.hpp
@@ -11,7 +11,7 @@ struct Tooltip : widget::Widget {
 	std::string text;
 	void step() override;
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 };
--- a/include/widget/FramebufferWidget.hpp
+++ b/include/widget/FramebufferWidget.hpp
@@ -15,7 +15,7 @@ struct FramebufferWidget : Widget {
 	bool dirty = true;
 	bool bypass = false;
 	float oversample = 1.0;
 	NVGLUframebuffer *fb = NULL;
 	NVGLUframebuffer* fb = NULL;
 	/** Scale relative to the world */
 	math::Vec scale;
 	/** Offset in world coordinates */
@@ -34,7 +34,7 @@ struct FramebufferWidget : Widget {
 	FramebufferWidget();
 	~FramebufferWidget();
 	void step() override;
 	void draw(const DrawArgs &args) override;
 	void draw(const DrawArgs& args) override;
 	virtual void drawFramebuffer();
 	int getImageHandle();
 };