Performs a fast fourier transform. More...
Public Member Functions  
FFT (int order)  
Initialises an object for performing forward and inverse FFT with the given size.  
FFT (FFT &&) noexcept  
Move constructor.  
FFT &  operator= (FFT &&) noexcept 
Move assignment operator.  
~FFT ()  
Destructor.  
void  perform (const Complex< float > *input, Complex< float > *output, bool inverse) const noexcept 
Performs an outofplace FFT, either forward or inverse.  
void  performRealOnlyForwardTransform (float *inputOutputData, bool onlyCalculateNonNegativeFrequencies=false) const noexcept 
Performs an inplace forward transform on a block of real data.  
void  performRealOnlyInverseTransform (float *inputOutputData) const noexcept 
Performs a reverse operation to data created in performRealOnlyForwardTransform().  
void  performFrequencyOnlyForwardTransform (float *inputOutputData, bool onlyCalculateNonNegativeFrequencies=false) const noexcept 
Takes an array and simply transforms it to the magnitude frequency response spectrum.  
int  getSize () const noexcept 
Returns the number of data points that this FFT was created to work with.  
Performs a fast fourier transform.
This is only a simple lowfootprint implementation and isn't tuned for speed  it may be useful for simple applications where one of the more complex FFT libraries would be overkill. (But in the future it may end up becoming optimised of course...)
The FFT class itself contains lookup tables, so there's some overhead in creating one, you should create and cache an FFT object for each size/direction of transform that you need, and reuse them to perform the actual operation.
dsp::FFT::FFT  (  int  order  ) 

noexcept 
Move constructor.
dsp::FFT::~FFT  (  ) 
Destructor.

noexcept 

noexcept 
Performs an inplace forward transform on a block of real data.
As the coefficients of the negative frequencies (frequencies higher than N/2 or pi) are the complex conjugate of their positive counterparts, it may not be necessary to calculate them for your particular application. You can use onlyCalculateNonNegativeFrequencies to let the FFT engine know that you do not plan on using them. Note that this is only a hint: some FFT engines (currently only the Fallback engine), will still calculate the negative frequencies even if onlyCalculateNonNegativeFrequencies is true.
The size of the array passed in must be 2 * getSize(), and the first half should contain your raw input sample data. On return, if onlyCalculateNonNegativeFrequencies is false, the array will contain size complex real + imaginary parts data interleaved. If onlyCalculateNonNegativeFrequencies is true, the array will contain at least (size / 2) + 1 complex numbers. Both outputs can be passed to performRealOnlyInverseTransform() in order to convert it back to reals.

noexcept 
Performs a reverse operation to data created in performRealOnlyForwardTransform().
Although performRealOnlyInverseTransform will only use the first ((size / 2) + 1) complex numbers, the size of the array passed in must still be 2 * getSize(), as some FFT engines require the extra space for the calculation. On return, the first half of the array will contain the reconstituted samples.

noexcept 
Takes an array and simply transforms it to the magnitude frequency response spectrum.
This may be handy for things like frequency displays or analysis. The size of the array passed in must be 2 * getSize().
On return, if onlyCalculateNonNegativeFrequencies is false, the array will contain size magnitude values. If onlyCalculateNonNegativeFrequencies is true, the array will contain at least size / 2 + 1 magnitude values.

noexcept 
Returns the number of data points that this FFT was created to work with.