/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2017 - ROLI Ltd. JUCE is an open source library subject to commercial or open-source licensing. By using JUCE, you agree to the terms of both the JUCE 5 End-User License Agreement and JUCE 5 Privacy Policy (both updated and effective as of the 27th April 2017). End User License Agreement: www.juce.com/juce-5-licence Privacy Policy: www.juce.com/juce-5-privacy-policy Or: You may also use this code under the terms of the GPL v3 (see www.gnu.org/licenses). JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE DISCLAIMED. ============================================================================== */ namespace juce { /** This class contains a ValueTree that is used to manage an AudioProcessor's entire state. It has its own internal class of parameter object that is linked to values within its ValueTree, and which are each identified by a string ID. You can get access to the underlying ValueTree object via the state member variable, so you can add extra properties to it as necessary. It also provides some utility child classes for connecting parameters directly to GUI controls like sliders. The favoured constructor of this class takes a collection of RangedAudioParameters or AudioProcessorParameterGroups of RangedAudioParameters and adds them to the attached AudioProcessor directly. The deprecated way of using this class is as follows: 1) Create an AudioProcessorValueTreeState, and give it some parameters using createAndAddParameter(). 2) Initialise the state member variable with a type name. The deprecated constructor will be removed from the API in a future version of JUCE! @tags{Audio} */ class JUCE_API AudioProcessorValueTreeState : private Timer, private ValueTree::Listener { public: //============================================================================== /** A class to contain a set of RangedAudioParameters and AudioProcessorParameterGroups containing RangedAudioParameters. This class is used in the AudioProcessorValueTreeState constructor to allow arbitrarily grouped RangedAudioParameters to be passed to an AudioProcessor. */ class JUCE_API ParameterLayout final { private: //============================================================================== template using ValidIfIterator = decltype (std::next (std::declval())); public: //============================================================================== template ParameterLayout (std::unique_ptr... items) { add (std::move (items)...); } template > ParameterLayout (It begin, It end) { add (begin, end); } template void add (std::unique_ptr... items) { parameters.reserve (parameters.size() + sizeof... (items)); // We can replace this with some nicer code once generic lambdas become available. A // sequential context like an array initialiser is required to ensure we get the correct // order from the parameter pack. int unused[] { (parameters.emplace_back (MakeContents() (std::move (items))), 0)... }; ignoreUnused (unused); } template > void add (It begin, It end) { parameters.reserve (parameters.size() + std::size_t (std::distance (begin, end))); std::transform (std::make_move_iterator (begin), std::make_move_iterator (end), std::back_inserter (parameters), MakeContents()); } ParameterLayout (const ParameterLayout& other) = delete; ParameterLayout (ParameterLayout&& other) noexcept { swap (other); } ParameterLayout& operator= (const ParameterLayout& other) = delete; ParameterLayout& operator= (ParameterLayout&& other) noexcept { swap (other); return *this; } void swap (ParameterLayout& other) noexcept { std::swap (other.parameters, parameters); } private: //============================================================================== struct Visitor { virtual ~Visitor() = default; // If you have a compiler error telling you that there is no matching // member function to call for 'visit', then you are probably attempting // to add a parameter that is not derived from RangedAudioParameter to // the AudioProcessorValueTreeState. virtual void visit (std::unique_ptr) const = 0; virtual void visit (std::unique_ptr) const = 0; }; struct ParameterStorageBase { virtual ~ParameterStorageBase() = default; virtual void accept (const Visitor& visitor) = 0; }; template struct ParameterStorage : ParameterStorageBase { explicit ParameterStorage (std::unique_ptr input) : contents (std::move (input)) {} void accept (const Visitor& visitor) override { visitor.visit (std::move (contents)); } std::unique_ptr contents; }; struct MakeContents final { template std::unique_ptr operator() (std::unique_ptr item) const { return std::unique_ptr (new ParameterStorage (std::move (item))); } }; void add() {} friend class AudioProcessorValueTreeState; std::vector> parameters; }; //============================================================================== /** Creates a state object for a given processor, and sets up all the parameters that will control that processor. You should *not* assign a new ValueTree to the state, or call createAndAddParameter, after using this constructor. Note that each AudioProcessorValueTreeState should be attached to only one processor, and must have the same lifetime as the processor, as they will have dependencies on each other. The ParameterLayout parameter has a set of constructors that allow you to add multiple RangedAudioParameters and AudioProcessorParameterGroups containing RangedAudioParameters to the AudioProcessorValueTreeState inside this constructor. @code YourAudioProcessor() : apvts (*this, &undoManager, "PARAMETERS", { std::make_unique ("a", "Parameter A", NormalisableRange (-100.0f, 100.0f), 0), std::make_unique ("b", "Parameter B", 0, 5, 2) }) @endcode To add parameters programatically you can use the iterator-based ParameterLayout constructor: @code AudioProcessorValueTreeState::ParameterLayout createParameterLayout() { std::vector> params; for (int i = 1; i < 9; ++i) params.push_back (std::make_unique (String (i), String (i), 0, i, 0)); return { params.begin(), params.end() }; } YourAudioProcessor() : apvts (*this, &undoManager, "PARAMETERS", createParameterLayout()) { } @endcode @param processorToConnectTo The Processor that will be managed by this object @param undoManagerToUse An optional UndoManager to use; pass nullptr if no UndoManager is required @param valueTreeType The identifier used to initialise the internal ValueTree @param parameterLayout An object that holds all parameters and parameter groups that the AudioProcessor should use. */ AudioProcessorValueTreeState (AudioProcessor& processorToConnectTo, UndoManager* undoManagerToUse, const Identifier& valueTreeType, ParameterLayout parameterLayout); /** This constructor is discouraged and will be deprecated in a future version of JUCE! Use the other constructor instead. Creates a state object for a given processor. The UndoManager is optional and can be a nullptr. After creating your state object, you should add parameters with the createAndAddParameter() method. Note that each AudioProcessorValueTreeState should be attached to only one processor, and must have the same lifetime as the processor, as they will have dependencies on each other. */ AudioProcessorValueTreeState (AudioProcessor& processorToConnectTo, UndoManager* undoManagerToUse); /** Destructor. */ ~AudioProcessorValueTreeState() override; //============================================================================== /** This function is deprecated and will be removed in a future version of JUCE! Previous calls to @code createAndAddParameter (paramID1, paramName1, ...); @endcode can be replaced with @code using Parameter = AudioProcessorValueTreeState::Parameter; createAndAddParameter (std::make_unique (paramID1, paramName1, ...)); @endcode However, a much better approach is to use the AudioProcessorValueTreeState constructor directly @code using Parameter = AudioProcessorValueTreeState::Parameter; YourAudioProcessor() : apvts (*this, &undoManager, "PARAMETERS", { std::make_unique (paramID1, paramName1, ...), std::make_unique (paramID2, paramName2, ...), ... }) @endcode @see AudioProcessorValueTreeState::AudioProcessorValueTreeState This function creates and returns a new parameter object for controlling a parameter with the given ID. Calling this will create and add a special type of AudioProcessorParameter to the AudioProcessor to which this state is attached. */ JUCE_DEPRECATED (RangedAudioParameter* createAndAddParameter (const String& parameterID, const String& parameterName, const String& labelText, NormalisableRange valueRange, float defaultValue, std::function valueToTextFunction, std::function textToValueFunction, bool isMetaParameter = false, bool isAutomatableParameter = true, bool isDiscrete = false, AudioProcessorParameter::Category category = AudioProcessorParameter::genericParameter, bool isBoolean = false)); /** This function adds a parameter to the attached AudioProcessor and that parameter will be managed by this AudioProcessorValueTreeState object. */ RangedAudioParameter* createAndAddParameter (std::unique_ptr parameter); //============================================================================== /** Returns a parameter by its ID string. */ RangedAudioParameter* getParameter (StringRef parameterID) const noexcept; /** Returns a pointer to a floating point representation of a particular parameter which a realtime process can read to find out its current value. Note that calling this method from within AudioProcessorValueTreeState::Listener::parameterChanged() is not guaranteed to return an up-to-date value for the parameter. */ float* getRawParameterValue (StringRef parameterID) const noexcept; //============================================================================== /** A listener class that can be attached to an AudioProcessorValueTreeState. Use AudioProcessorValueTreeState::addParameterListener() to register a callback. */ struct JUCE_API Listener { virtual ~Listener() = default; /** This callback method is called by the AudioProcessorValueTreeState when a parameter changes. Within this call, retrieving the value of the parameter that has changed via the getRawParameterValue() or getParameter() methods is not guaranteed to return the up-to-date value. If you need this you should instead use the newValue parameter. */ virtual void parameterChanged (const String& parameterID, float newValue) = 0; }; /** Attaches a callback to one of the parameters, which will be called when the parameter changes. */ void addParameterListener (StringRef parameterID, Listener* listener); /** Removes a callback that was previously added with addParameterCallback(). */ void removeParameterListener (StringRef parameterID, Listener* listener); //============================================================================== /** Returns a Value object that can be used to control a particular parameter. */ Value getParameterAsValue (StringRef parameterID) const; /** Returns the range that was set when the given parameter was created. */ NormalisableRange getParameterRange (StringRef parameterID) const noexcept; //============================================================================== /** Returns a copy of the state value tree. The AudioProcessorValueTreeState's ValueTree is updated internally on the message thread, but there may be cases when you may want to access the state from a different thread (getStateInformation is a good example). This method flushes all pending audio parameter value updates and returns a copy of the state in a thread safe way. Note: This method uses locks to synchronise thread access, so whilst it is thread-safe, it is not realtime-safe. Do not call this method from within your audio processing code! */ ValueTree copyState(); /** Replaces the state value tree. The AudioProcessorValueTreeState's ValueTree is updated internally on the message thread, but there may be cases when you may want to modify the state from a different thread (setStateInformation is a good example). This method allows you to replace the state in a thread safe way. Note: This method uses locks to synchronise thread access, so whilst it is thread-safe, it is not realtime-safe. Do not call this method from within your audio processing code! */ void replaceState (const ValueTree& newState); //============================================================================== /** A reference to the processor with which this state is associated. */ AudioProcessor& processor; /** The state of the whole processor. This must be initialised after all calls to createAndAddParameter(). You can replace this with your own ValueTree object, and can add properties and children to the tree. This class will automatically add children for each of the parameter objects that are created by createAndAddParameter(). */ ValueTree state; /** Provides access to the undo manager that this object is using. */ UndoManager* const undoManager; //============================================================================== /** A parameter class that maintains backwards compatibility with deprecated AudioProcessorValueTreeState functionality. Previous calls to @code createAndAddParameter (paramID1, paramName1, ...); @endcode can be replaced with @code using Parameter = AudioProcessorValueTreeState::Parameter; createAndAddParameter (std::make_unique (paramID1, paramName1, ...)); @endcode However, a much better approach is to use the AudioProcessorValueTreeState constructor directly @code using Parameter = AudioProcessorValueTreeState::Parameter; YourAudioProcessor() : apvts (*this, &undoManager, "PARAMETERS", { std::make_unique (paramID1, paramName1, ...), std::make_unique (paramID2, paramName2, ...), ... }) @endcode */ class Parameter final : public AudioParameterFloat { public: Parameter (const String& parameterID, const String& parameterName, const String& labelText, NormalisableRange valueRange, float defaultValue, std::function valueToTextFunction, std::function textToValueFunction, bool isMetaParameter = false, bool isAutomatableParameter = true, bool isDiscrete = false, AudioProcessorParameter::Category category = AudioProcessorParameter::genericParameter, bool isBoolean = false); float getDefaultValue() const override; int getNumSteps() const override; bool isMetaParameter() const override; bool isAutomatable() const override; bool isDiscrete() const override; bool isBoolean() const override; private: const float unsnappedDefault; const bool metaParameter, automatable, discrete, boolean; }; //============================================================================== /** An object of this class maintains a connection between a Slider and a parameter in an AudioProcessorValueTreeState. During the lifetime of this SliderAttachment object, it keeps the two things in sync, making it easy to connect a slider to a parameter. When this object is deleted, the connection is broken. Make sure that your AudioProcessorValueTreeState and Slider aren't deleted before this object! */ class JUCE_API SliderAttachment { public: SliderAttachment (AudioProcessorValueTreeState& stateToControl, const String& parameterID, Slider& sliderToControl); ~SliderAttachment(); private: struct Pimpl; std::unique_ptr pimpl; JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (SliderAttachment) }; //============================================================================== /** An object of this class maintains a connection between a ComboBox and a parameter in an AudioProcessorValueTreeState. Combobox items will be spaced linearly across the range of the parameter. For example if the range is specified by NormalisableRange (-0.5f, 0.5f, 0.5f) and you add three items then the first will be mapped to a value of -0.5, the second to 0, and the third to 0.5. During the lifetime of this ComboBoxAttachment object, it keeps the two things in sync, making it easy to connect a combo box to a parameter. When this object is deleted, the connection is broken. Make sure that your AudioProcessorValueTreeState and ComboBox aren't deleted before this object! */ class JUCE_API ComboBoxAttachment { public: ComboBoxAttachment (AudioProcessorValueTreeState& stateToControl, const String& parameterID, ComboBox& comboBoxToControl); ~ComboBoxAttachment(); private: struct Pimpl; std::unique_ptr pimpl; JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (ComboBoxAttachment) }; //============================================================================== /** An object of this class maintains a connection between a Button and a parameter in an AudioProcessorValueTreeState. During the lifetime of this ButtonAttachment object, it keeps the two things in sync, making it easy to connect a button to a parameter. When this object is deleted, the connection is broken. Make sure that your AudioProcessorValueTreeState and Button aren't deleted before this object! */ class JUCE_API ButtonAttachment { public: ButtonAttachment (AudioProcessorValueTreeState& stateToControl, const String& parameterID, Button& buttonToControl); ~ButtonAttachment(); private: struct Pimpl; std::unique_ptr pimpl; JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (ButtonAttachment) }; private: //============================================================================== /** This method was introduced to allow you to use AudioProcessorValueTreeState parameters in an AudioProcessorParameterGroup, but there is now a much nicer way to achieve this. Code that looks like this @code auto paramA = apvts.createParameter ("a", "Parameter A", {}, { -100, 100 }, ...); auto paramB = apvts.createParameter ("b", "Parameter B", {}, { 0, 5 }, ...); addParameterGroup (std::make_unique ("g1", "Group 1", " | ", std::move (paramA), std::move (paramB))); apvts.state = ValueTree (Identifier ("PARAMETERS")); @endcode can instead create the APVTS like this, avoiding the two-step initialization process and leveraging one of JUCE's pre-built parameter types (or your own custom type derived from RangedAudioParameter) @code using Parameter = AudioProcessorValueTreeState::Parameter; YourAudioProcessor() : apvts (*this, &undoManager, "PARAMETERS", { std::make_unique ("g1", "Group 1", " | ", std::make_unique ("a", "Parameter A", "", NormalisableRange (-100, 100), ...), std::make_unique ("b", "Parameter B", "", NormalisableRange (0, 5), ...)) }) @endcode */ JUCE_DEPRECATED (std::unique_ptr createParameter (const String&, const String&, const String&, NormalisableRange, float, std::function, std::function, bool, bool, bool, AudioProcessorParameter::Category, bool)); //============================================================================== class ParameterAdapter; #if JUCE_UNIT_TESTS friend struct ParameterAdapterTests; #endif void addParameterAdapter (RangedAudioParameter&); ParameterAdapter* getParameterAdapter (StringRef) const; bool flushParameterValuesToValueTree(); void setNewState (ValueTree); void timerCallback() override; void valueTreePropertyChanged (ValueTree&, const Identifier&) override; void valueTreeChildAdded (ValueTree&, ValueTree&) override; void valueTreeChildRemoved (ValueTree&, ValueTree&, int) override; void valueTreeChildOrderChanged (ValueTree&, int, int) override; void valueTreeParentChanged (ValueTree&) override; void valueTreeRedirected (ValueTree&) override; void updateParameterConnectionsToChildTrees(); const Identifier valueType { "PARAM" }, valuePropertyID { "value" }, idPropertyID { "id" }; struct StringRefLessThan final { bool operator() (StringRef a, StringRef b) const noexcept { return a.text.compare (b.text) < 0; } }; std::map, StringRefLessThan> adapterTable; CriticalSection valueTreeChanging; JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (AudioProcessorValueTreeState) }; } // namespace juce