示例#1
0
// Transposes the sample rate of the given samples using linear interpolation. 
// Returns the number of samples returned in the "dest" buffer
int TransposerBase::transpose(FIFOSampleBuffer &dest, FIFOSampleBuffer &src)
{
    int numSrcSamples = src.numSamples();
    int sizeDemand = (int)((double)numSrcSamples / rate) + 8;
    int numOutput;
    SAMPLETYPE *psrc = src.ptrBegin();
    SAMPLETYPE *pdest = dest.ptrEnd(sizeDemand);

#ifndef USE_MULTICH_ALWAYS
    if (numChannels == 1)
    {
        numOutput = transposeMono(pdest, psrc, numSrcSamples);
    }
    else if (numChannels == 2) 
    {
        numOutput = transposeStereo(pdest, psrc, numSrcSamples);
    } 
    else 
#endif // USE_MULTICH_ALWAYS
    {
        assert(numChannels > 0);
        numOutput = transposeMulti(pdest, psrc, numSrcSamples);
    }
    dest.putSamples(numOutput);
    src.receiveSamples(numSrcSamples);
    return numOutput;
}
示例#2
0
/// Applies the filter to the given src & dest pipes, so that processed amount of
/// samples get removed from src, and produced amount added to dest 
/// Note : The amount of outputted samples is by value of 'filter length' 
/// smaller than the amount of input samples.
uint AAFilter::evaluate(FIFOSampleBuffer &dest, FIFOSampleBuffer &src) const
{
    SAMPLETYPE *pdest;
    const SAMPLETYPE *psrc;
    uint numSrcSamples;
    uint result;
    int numChannels = src.getChannels();

    assert(numChannels == dest.getChannels());

    numSrcSamples = src.numSamples();
    psrc = src.ptrBegin();
    pdest = dest.ptrEnd(numSrcSamples);
    result = pFIR->evaluate(pdest, psrc, numSrcSamples, numChannels);
    src.receiveSamples(result);
    dest.putSamples(result);

    return result;
}