CUGL 2.1
Cornell University Game Library
|
#include <CUPoleZeroIIR.h>
Public Member Functions | |
PoleZeroFIR () | |
PoleZeroFIR (unsigned channels) | |
PoleZeroFIR (unsigned channels, float b0, float b1, float a1) | |
PoleZeroFIR (const PoleZeroFIR ©) | |
PoleZeroFIR (PoleZeroFIR &&filter) | |
~PoleZeroFIR () | |
unsigned | getChannels () const |
void | setChannels (unsigned channels) |
void | setCoeff (const std::vector< float > &bvals, const std::vector< float > &avals) |
const std::vector< float > | getBCoeff () const |
const std::vector< float > | getACoeff () const |
void | setBCoeff (float b0, float b1) |
void | setACoeff (float a1) |
void | setHighpass (float frequency) |
void | setAllpass (float coefficient) |
void | setBlockZero (float pole=0.99f) |
void | step (float gain, float *input, float *output) |
void | calculate (float gain, float *input, float *output, size_t size) |
void | clear () |
size_t | flush (float *output) |
Static Public Attributes | |
static bool | VECTORIZE |
This class implements a one-zero digital filter.
This filter is the preferred way to create a first-order highpass filter, and so we provide the method setHighpass for setting the highpass frequency. In addition, there are methods for creating an allpass filter, as well as a DC blocking filter.
Frequencies are specified in "normalized" format. A normalized frequency is frequency/sample rate. For example, a 7 kHz frequency with a 44100 Hz sample rate has a normalized value 7000/44100 = 0.15873. However, filters are not intended to be model classes, and so it does not save the defining frequency.
This class supports vector optimizations for SSE and Neon 64. In timed simulations, these optimizations provide at least a 3-4x performance increase (and for 4 or 8 channel audio, much higher). These optimizations make use of the matrix precomputation outlined in "Implementation of Recursive Digital Filters into Vector SIMD DSP Architectures".
https://pdfs.semanticscholar.org/d150/a3f75dc033916f14029cd9101a8ea1d050bb.pdf
The algorithm in this paper performs extremely well in our tests, and even out-performs Apple's Acceleration library. However, our implementation is limited to 128-bit words as 256-bit (e.g. AVX) and higher show no significant increase in performance.
For performance reasons, this class does not have a (virtualized) subclass relationship with other IIR or FIR filters. However, the signature of the the calculation and coefficient methods has been standardized so that it can support templated polymorphism.
This class is not thread safe. External locking may be required when the filter is shared between multiple threads (such as between an audio thread and the main thread).
cugl::dsp::PoleZeroFIR::PoleZeroFIR | ( | ) |
Creates a zero-order pass-through filter for a single channel.
cugl::dsp::PoleZeroFIR::PoleZeroFIR | ( | unsigned | channels | ) |
Creates a zero-order pass-through filter for the given number of channels.
channels | The number of channels |
cugl::dsp::PoleZeroFIR::PoleZeroFIR | ( | unsigned | channels, |
float | b0, | ||
float | b1, | ||
float | a1 | ||
) |
Creates a FIR filter with the given coefficients and number of channels.
This filter implements the standard difference equation:
y[n] = b[0]*x[n] + b[1]*x[n-1] - a[1]*y[n-1]
where y is the output and x in the input.
channels | The number of channels |
b0 | The upper zero-order coefficient |
b1 | The upper first-order coefficient |
a1 | The lower first-order coefficient |
cugl::dsp::PoleZeroFIR::PoleZeroFIR | ( | const PoleZeroFIR & | copy | ) |
Creates a copy of the FIR filter.
copy | The filter to copy |
cugl::dsp::PoleZeroFIR::PoleZeroFIR | ( | PoleZeroFIR && | filter | ) |
Creates a FIR filter with the resources of the original.
filter | The filter to acquire |
cugl::dsp::PoleZeroFIR::~PoleZeroFIR | ( | ) |
Destroys the filter, releasing all resources.
void cugl::dsp::PoleZeroFIR::calculate | ( | float | gain, |
float * | input, | ||
float * | output, | ||
size_t | size | ||
) |
Performs a filter of interleaved input data.
The output is written to the given output array, which should be the same size as the input array. The size is the number of frames, not samples. Hence the arrays must be size times the number of channels in size.
To provide real time processing, the output is delayed by the number of a-coefficients. Delayed results are buffered to be used the next time the filter is used (though they may be extracted with the flush method). The gain parameter is applied at the filter input, but does not affect the filter coefficients.
gain | The input gain factor |
input | The array of input samples |
output | The array to write the sample output |
size | The input size in frames |
void cugl::dsp::PoleZeroFIR::clear | ( | ) |
Clears the filter buffer of any delayed outputs or cached inputs
size_t cugl::dsp::PoleZeroFIR::flush | ( | float * | output | ) |
Flushes any delayed outputs to the provided array
The array size should be the number of channels. This method will also clear the buffer.
const std::vector<float> cugl::dsp::PoleZeroFIR::getACoeff | ( | ) | const |
Returns the lower coefficients for this IIR filter.
This filter implements the standard difference equation:
a[0]*y[n] = b[0]*x[n]+...+b[nb]*x[n-nb]-a[1]*y[n-1]-...-a[na]*y[n-na]
where y is the output and x in the input.
const std::vector<float> cugl::dsp::PoleZeroFIR::getBCoeff | ( | ) | const |
Returns the upper coefficients for this IIR filter.
This filter implements the standard difference equation:
a[0]*y[n] = b[0]*x[n]+...+b[nb]*x[n-nb]-a[1]*y[n-1]-...-a[na]*y[n-na]
where y is the output and x in the input.
|
inline |
Returns the number of channels for this filter
The data buffers depend on the number of channels. Changing this value will reset the data buffers to 0.
void cugl::dsp::PoleZeroFIR::setACoeff | ( | float | a1 | ) |
Sets the lower coefficient.
Setting this leaves the upper coefficients unchanged.
a1 | The lower first-order coefficient |
void cugl::dsp::PoleZeroFIR::setAllpass | ( | float | coefficient | ) |
Sets the filter to be a first-order allpass with the given coefficient.
The allpass filter has unity gain at all frequencies. The coefficient magnitude must be less than one to maintain filter stability.
coefficient | The allpass coefficient |
void cugl::dsp::PoleZeroFIR::setBCoeff | ( | float | b0, |
float | b1 | ||
) |
Sets the upper coefficients.
Setting this leaves the lower coefficient unchanged.
b0 | The upper zero-order coefficient |
b1 | The upper first-order coefficient |
void cugl::dsp::PoleZeroFIR::setBlockZero | ( | float | pole = 0.99f | ) |
Sets the filter to be a DC blocking filter with the given pole position.
This method sets the given pole position, together with a zero at z=1, to create a DC blocking filter. The argument magnitude should be close to (but less than) one to minimize low-frequency attenuation.
pole | The filter pole |
void cugl::dsp::PoleZeroFIR::setChannels | ( | unsigned | channels | ) |
Sets the number of channels for this filter
The data buffers depend on the number of channels. Changing this value will reset the data buffers to 0.
channels | The number of channels for this filter |
void cugl::dsp::PoleZeroFIR::setCoeff | ( | const std::vector< float > & | bvals, |
const std::vector< float > & | avals | ||
) |
Sets the coefficients for this IIR filter.
This filter implements the standard difference equation:
a[0]*y[n] = b[0]*x[n] + ... + b[nb]*x[n-nb]
where y is the output and x in the input. If a[0] is not equal to 1, the filter coeffcients are normalized by a[0]. All other a-coefficients are ignored (they are only present for signature standardization). Similarly, all b-coefficients after the second are ignored. If any coefficients are missing, they are replaced with 1 for b[0] and a[0], and 0 otherwise.
bvals | The upper coefficients |
avals | The lower coefficients |
void cugl::dsp::PoleZeroFIR::setHighpass | ( | float | frequency | ) |
Sets the filter to be a first-order highpass for the given frequency
The resulting filter is typically considered the simplest effective highpass filter. However, filters are not intended to be model classes, and so it does not save the defining frequency.
The frequency is specified in "normalized" format. A normalized frequency is frequency/sample rate. For example, a 7 kHz frequency with a 44100 Hz sample rate has a normalized value 7000/44100 = 0.15873.
frequency | The normalized cutoff frequency |
void cugl::dsp::PoleZeroFIR::step | ( | float | gain, |
float * | input, | ||
float * | output | ||
) |
Performs a filter of single frame of data.
The output is written to the given output array, which should be the same size as the input array. The size should be the number of channels.
To provide real time processing, the output is delayed by the number of a-coefficients. Delayed results are buffered to be used the next time the filter is used (though they may be extracted with the flush method). The gain parameter is applied at the filter input, but does not affect the filter coefficients.
gain | The input gain factor |
input | The input frame |
output | The frame to receive the output |
|
static |
Whether to use a vectorization algorithm (Access not thread safe)