/// <summary>
/// Output samples from beginning of the sample buffer. Copies requested
/// samples to output buffer and removes them from the sample buffer.
/// If there are less than
/// <paramref name="maxSamples"/> samples in the buffer, returns all
/// that available.
/// </summary>
/// <param name="output">Buffer where to copy output samples.</param>
/// <param name="maxSamples">How many samples to receive at max.</param>
/// <returns>Number of samples returned.</returns>
public override int ReceiveSamples(ArrayPtr <TSampleType> output, int maxSamples)
{
int num = (maxSamples > _samplesInBuffer) ? _samplesInBuffer : maxSamples;
ArrayPtr <TSampleType> .CopyBytes(output, PtrBegin(), _channels *SIZEOF_SAMPLETYPE *num);
return(ReceiveSamples(num));
}
/// <summary>
/// Rewind the buffer by moving data from position pointed by
/// <see cref="_bufferPos"/> to real beginning of the buffer.
/// </summary>
/// <remarks>
/// if output location pointer <see cref="_bufferPos"/> isn't zero,
/// 'rewinds' the buffer and zeroes this pointer by copying samples from
/// the <see cref="_bufferPos"/> pointer location on to the beginning
/// of the buffer.
/// </remarks>
private void Rewind()
{
if ((_buffer == null) || (_bufferPos == 0))
{
return;
}
ArrayPtr <TSampleType> .CopyBytes(_buffer, PtrBegin(), SIZEOF_SAMPLETYPE *_channels *_samplesInBuffer);
_bufferPos = 0;
}
/// <summary>
/// Processes as many processing frames of the samples <see cref="_inputBuffer"/>, store
/// the result into <see cref="_outputBuffer"/>
/// </summary>
private void ProcessSamples()
{
// Process samples as long as there are enough samples in '_inputBuffer'
// to form a processing frame.
while (_inputBuffer.AvailableSamples >= _sampleReq)
{
// If tempo differs from the normal ('SCALE'), scan for the best overlapping
// position
int offset = SeekBestOverlapPosition(_inputBuffer.PtrBegin());
// Mix the samples in the '_inputBuffer' at position of 'offset' with the
// samples in 'midBuffer' using sliding overlapping
// ... first partially overlap with the end of the previous sequence
// (that's in 'midBuffer')
Overlap(_outputBuffer.PtrEnd(_overlapLength), _inputBuffer.PtrBegin(), offset);
_outputBuffer.PutSamples(_overlapLength);
// ... then copy sequence samples from '_inputBuffer' to output:
// length of sequence
int temp = (_seekWindowLength - 2 * _overlapLength);
// crosscheck that we don't have buffer overflow...
if (_inputBuffer.AvailableSamples < (offset + temp + _overlapLength * 2))
{
continue; // just in case, shouldn't really happen
}
_outputBuffer.PutSamples(_inputBuffer.PtrBegin() + _channels * (offset + _overlapLength), temp);
// Copies the end of the current sequence from '_inputBuffer' to
// 'midBuffer' for being mixed with the beginning of the next
// processing sequence and so on
Debug.Assert((offset + temp + _overlapLength * 2) <= _inputBuffer.AvailableSamples);
ArrayPtr <TSampleType> .CopyBytes(_midBuffer, _inputBuffer.PtrBegin() + _channels *(offset + temp + _overlapLength),
_channels *SIZEOF_SAMPLETYPE *_overlapLength);
// Remove the processed samples from the input buffer. Update
// the difference between integer & nominal skip step to '_skipFract'
// in order to prevent the error from accumulating over time.
_skipFract += _nominalSkip; // real skip size
var ovlSkip = (int)_skipFract;
_skipFract -= ovlSkip; // maintain the fraction part, i.e. real vs. integer skip
_inputBuffer.ReceiveSamples(ovlSkip);
}
}
/// <summary>
/// Set filter coefficients and length.
/// </summary>
/// <exception cref="ArgumentException">FIR filter length not divisible
/// by 8</exception>
public virtual void SetCoefficients(ArrayPtr <TSampleType> coeffs, int newLength, int resultDivFactor)
{
Debug.Assert(newLength > 0);
if ((newLength % 8) != 0)
{
throw new ArgumentException("FIR filter length not divisible by 8");
}
_lengthDiv8 = newLength / 8;
_length = _lengthDiv8 * 8;
Debug.Assert(_length == newLength);
_resultDivFactor = resultDivFactor;
var numPtr = new TSampleType[_length];
_filterCoeffs = numPtr;
ArrayPtr <TSampleType> .CopyBytes(_filterCoeffs, coeffs, _length *SIZEOF_SAMPLETYPE);
}
/// <summary>
/// Ensures that the buffer has capacity for at least this many samples.
/// </summary>
private void EnsureCapacity(int capacityRequirement)
{
if (capacityRequirement > GetCapacity())
{
// enlarge the buffer in 4kbyte steps (round up to next 4k boundary)
_sizeInBytes = (int)((capacityRequirement * _channels * SIZEOF_SAMPLETYPE + 4095) & unchecked ((uint)-4096));
Debug.Assert(_sizeInBytes % 2 == 0);
var temp = new TSampleType[_sizeInBytes / SIZEOF_SAMPLETYPE + 16 / SIZEOF_SAMPLETYPE];
if (_samplesInBuffer != 0)
{
ArrayPtr <TSampleType> .CopyBytes(temp, PtrBegin(), _samplesInBuffer *_channels *SIZEOF_SAMPLETYPE);
}
_buffer = temp;
_bufferPos = 0;
}
else
{
// simply rewind the buffer (if necessary)
Rewind();
}
}
/// <summary>
/// Adds <paramref name="numSamples"/> pcs of samples from the
/// <paramref name="samples"/> memory position to the sample buffer.
/// </summary>
/// <param name="samples">Pointer to samples.</param>
/// <param name="numSamples">Number of samples to insert.</param>
public override void PutSamples(ArrayPtr <TSampleType> samples, int numSamples)
{
ArrayPtr <TSampleType> .CopyBytes(PtrEnd(numSamples), samples, SIZEOF_SAMPLETYPE *numSamples *_channels);
_samplesInBuffer += numSamples;
}
