/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2020 - Raw Material Software Limited 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 6 End-User License Agreement and JUCE Privacy Policy (both effective as of the 16th June 2020). End User License Agreement: www.juce.com/juce-6-licence Privacy Policy: www.juce.com/juce-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 { namespace dsp { /** This structure is passed into a DSP algorithm's prepare() method, and contains information about various aspects of the context in which it can expect to be called. @tags{DSP} */ struct ProcessSpec { /** The sample rate that will be used for the data that is sent to the processor. */ double sampleRate; /** The maximum number of samples that will be in the blocks sent to process() method. */ uint32 maximumBlockSize; /** The number of channels that the process() method will be expected to handle. */ uint32 numChannels; }; //============================================================================== /** This is a handy base class for the state of a processor (such as parameter values) which is typically shared among several processors. This is useful for multi-mono filters which share the same state among several mono processors. @tags{DSP} */ struct ProcessorState : public ReferenceCountedObject { /** The ProcessorState structure is ref-counted, so this is a handy type that can be used as a pointer to one. */ using Ptr = ReferenceCountedObjectPtr; }; //============================================================================== /** Contains context information that is passed into an algorithm's process method. This context is intended for use in situations where a single block is being used for both the input and output, so it will return the same object for both its getInputBlock() and getOutputBlock() methods. @see ProcessContextNonReplacing @tags{DSP} */ template struct ProcessContextReplacing { public: /** The type of a single sample (which may be a vector if multichannel). */ using SampleType = ContextSampleType; /** The type of audio block that this context handles. */ using AudioBlockType = AudioBlock; using ConstAudioBlockType = AudioBlock; /** Creates a ProcessContextReplacing that uses the given audio block. Note that the caller must not delete the block while it is still in use by this object! */ ProcessContextReplacing (AudioBlockType& block) noexcept : ioBlock (block) {} ProcessContextReplacing (const ProcessContextReplacing&) = default; ProcessContextReplacing (ProcessContextReplacing&&) = default; /** Returns the audio block to use as the input to a process function. */ const ConstAudioBlockType& getInputBlock() const noexcept { return constBlock; } /** Returns the audio block to use as the output to a process function. */ AudioBlockType& getOutputBlock() const noexcept { return ioBlock; } /** All process context classes will define this constant method so that templated code can determine whether the input and output blocks refer to the same buffer, or to two different ones. */ static constexpr bool usesSeparateInputAndOutputBlocks() { return false; } /** If set to true, then a processor's process() method is expected to do whatever is appropriate for it to be in a bypassed state. */ bool isBypassed = false; private: AudioBlockType& ioBlock; ConstAudioBlockType constBlock { ioBlock }; }; //============================================================================== /** Contains context information that is passed into an algorithm's process method. This context is intended for use in situations where two different blocks are being used the input and output to the process algorithm, so the processor must read from the block returned by getInputBlock() and write its results to the block returned by getOutputBlock(). @see ProcessContextReplacing @tags{DSP} */ template struct ProcessContextNonReplacing { public: /** The type of a single sample (which may be a vector if multichannel). */ using SampleType = ContextSampleType; /** The type of audio block that this context handles. */ using AudioBlockType = AudioBlock; using ConstAudioBlockType = AudioBlock; /** Creates a ProcessContextReplacing that uses the given input and output blocks. Note that the caller must not delete these blocks while they are still in use by this object! */ ProcessContextNonReplacing (const ConstAudioBlockType& input, AudioBlockType& output) noexcept : inputBlock (input), outputBlock (output) { // If the input and output blocks are the same then you should use // ProcessContextReplacing instead. jassert (input != output); } ProcessContextNonReplacing (const ProcessContextNonReplacing&) = default; ProcessContextNonReplacing (ProcessContextNonReplacing&&) = default; /** Returns the audio block to use as the input to a process function. */ const ConstAudioBlockType& getInputBlock() const noexcept { return inputBlock; } /** Returns the audio block to use as the output to a process function. */ AudioBlockType& getOutputBlock() const noexcept { return outputBlock; } /** All process context classes will define this constant method so that templated code can determine whether the input and output blocks refer to the same buffer, or to two different ones. */ static constexpr bool usesSeparateInputAndOutputBlocks() { return true; } /** If set to true, then a processor's process() method is expected to do whatever is appropriate for it to be in a bypassed state. */ bool isBypassed = false; private: ConstAudioBlockType inputBlock; AudioBlockType& outputBlock; }; } // namespace dsp } // namespace juce