An audio management library written in Qt
This library allows to manage stereo audio signals, 16bit PCM with a sampling rate of 44100Hz. It provides QAudioLibBuffer that overloads and improve the Qt QAudioBuffer, QAudioLibFreqBuffer that works with complex number to work in the frequency domain and Mathematics class that performs common signal processing operations like fft and convolution.
This library is static, if you want to build and run the example benchmark TESTqAudioLib do the following:
#build library
cd QAudioLib
qmake *.pro
make
#build the benchmark
cd TESTqAudioLib
qmake *.pro
make
#run the benchmark
./TESTqAudioLibThis is an example of benchmark output:
Generate 1s square wave...
Done in 9ms
Calculate fft...
Done in 86ms
Calculate ifft...
Done in 101ms
Generate 5000 samples sin wave...
Done in 1ms
Calculate dft...(take a while)
Done in 627ms
Generate 1s sin wave...
Done in 7ms
Generate 1s white noise...
Done in 6ms
Lowpass 2000Hz filtering...
Done in 132ms
Play noise...
Got a buffer underflow! <--This is not a problem, it warns that the buffer is ended
Currently QAudioLib works with an own audio format: DefaultAudioFormat:
setByteOrder(QAudioFormat::LittleEndian);
setChannelCount(2);
setCodec("audio/pcm");
setSampleRate(44100);
setSampleSize(16);
setSampleType(QAudioFormat::SignedInt);Use QAudioLibBuffer::getDefaultFormat() to get the default
format.
QAudioLibBuffer(); //a void, no samples buffer
QAudioLibBuffer(const QAudioBuffer & other); //a copy of `other` buffer
QAudioLibBuffer(const QByteArray & data); //a buffer from bytes `data`
QAudioLibBuffer(int numFrames); //a zeros buffer with `numFrames` length
QAudioLibBuffer(qreal sec); //a zeros buffer of `sec` seconds lengthThis type is provided by Qt and allows to manage left and right channels in the buffer, for example:
int position=0;
qint16 val=5;
mybuffer.data()[position].left=val;
mybuffer.data()[position].right=SHRT_MAX;const S16S* constData() const; //returns an S16S array, read only.
S16S* data(); //returns an `S16S array, read and writeSee also Qt QAudioBuffer for inner functions.
QAudioLibBuffer allows to manipulate buffers through its operators:
QAudioLibBuffer operator<<(const QAudioLibBuffer &x) const; //appends buffers
QAudioLibBuffer operator*(const QAudioLibBuffer &x) const; //multiplicates buffers
QAudioLibBuffer operator*(const qreal x) const; //multiplicates for a costant
QAudioLibBuffer operator+(const QAudioLibBuffer &x); const //sums buffersThis buffer is really similar to QAudioLibBuffer, then I will not explain each function. It works with complex number
qcomplex manage double complex numbers, to declare a complex number use qcomplex(re,im)
QAudioLibFreqBuffer(int numFrames);
QAudioLibFreqBuffer(const QAudioLibFreqBuffer & other);
static QAudioLibFreqBuffer newByRealBuffer(const QAudioLibBuffer & x); //it is not a constructor but create a complex buffer from a real bufferIt is defined in the library, it is like S16S but complex
S64CD* data();
const S64CD* constData() const;
int frameCount() const;
int byteCount() const;
void appendZeros(int n); //zero padding, used by FFT
void clear(); //clears the bufferqreal deltaf(); //returns the frequency increment between successive samples
qreal nyquistfreq(); //returns the nyquist frequency
QAudioLibFreqBuffer mod() const; //returns a new buffer of samples module
QAudioLibFreqBuffer phase() const; //returns a new buffer of samples phase
QAudioLibFreqBuffer conj() const; //returns a new buffer of samples conjugateQAudioLibFreqBuffer operator*(const QAudioLibFreqBuffer &x);
QAudioLibFreqBuffer operator*(const qreal x);
void operator=(const QAudioLibFreqBuffer &x);This class provides a list of static functions to generate waveforms and to analyze sounds
static QAudioLibBuffer sinwave(qreal f, qreal sec); //generates a new sinusoidal waveform (with rotation matrix) of frequency `f` and duration `sec`
static QAudioLibBuffer squarewave(qreal f, qreal sec); //generates a new sqaure waveform of frequency `f` and duration `sec`static QAudioLibBuffer conv(QAudioLibBuffer &u ,QAudioLibBuffer &v); //does the convolution of two signals
static QAudioLibBuffer corr(QAudioLibBuffer &u ,QAudioLibBuffer &v);//does the cross correlation of two signals
static QAudioLibBuffer filter(QAudioLibBuffer &x, int N, char type, int f0, int f1=0); //filters the signal (type can be 'l': lowpass, 'h' highpass, 'b' bandpass) set f1 only for bandpass filtersstatic QAudioLibFreqBuffer fft(const QAudioLibFreqBuffer & x); //does the fft of a complex signal, woks only if the length is a power of 2
static QAudioLibFreqBuffer dft(const QAudioLibFreqBuffer & x); //does the dft, it is very slow (uses at your own risk)
static QAudioLibFreqBuffer fft(const QAudioLibBuffer & x, bool zeropadding=true); //does the dft of a real signal, if signal is a power of 2 or if `zeropadding` is `true` uses the fft alghoritm othermise uses the slow dft. If `zeropadding` is true the signal lenght will change to become a power of 2.
static QAudioLibBuffer ifft(const QAudioLibFreqBuffer & x); //does the inverse dft, uses fft alghorithm only if the input singal is a power of 2 length.