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/*
Copyright (C) 2000 Stefan Westerfeld
stefan@space.twc.de
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Library General Public
License as published by the Free Software Foundation; either
version 2 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Library General Public License for more details.
You should have received a copy of the GNU Library General Public License
along with this library; see the file COPYING.LIB. If not, write to
the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA.
*/
#include "resample.h"
#include "debug.h"
#include <math.h>
#include <assert.h>
#include <stdio.h>
#define compose_16le(first,second) \
(((((second)+128)&0xff) << 8)+(first))
#define compose_16be(first,second) \
(((((first)+128)&0xff) << 8)+(second))
#define conv_16_float(x) \
((float)((x)-32768)/32768.0)
#define conv_8_float(x) \
((float)((x)-128)/128.0)
using namespace Arts;
class Arts::ResamplerPrivate {
public:
bool underrun;
Resampler::Endianness endianness;
};
const unsigned int Resampler::bufferSize;
const unsigned int Resampler::bufferWrap;
Resampler::Resampler(Refiller *refiller) :
dropBytes(0), refiller(refiller), pos(0.0), step(1.0), channels(2),
bits(16),
block(0), haveBlock(-1)
{
d = new ResamplerPrivate();
d->underrun = false;
d->endianness = littleEndian;
updateSampleSize();
}
Resampler::~Resampler()
{
delete d;
}
void Resampler::updateSampleSize()
{
sampleSize = channels * bits / 8;
bufferSamples = bufferSize / sampleSize;
}
void Resampler::setStep(double newStep)
{
arts_return_if_fail(newStep > 0);
step = newStep;
}
void Resampler::setChannels(int newChannels)
{
arts_return_if_fail(newChannels == 1 || newChannels == 2);
channels = newChannels;
updateSampleSize();
}
void Resampler::setBits(int newBits)
{
arts_return_if_fail(newBits == 8 || newBits == 16);
bits = newBits;
updateSampleSize();
}
void Resampler::setEndianness(Endianness newEndianness)
{
arts_return_if_fail(newEndianness == bigEndian || newEndianness == littleEndian);
d->endianness = newEndianness;
}
bool Resampler::underrun()
{
return d->underrun;
}
void Resampler::ensureRefill()
{
if(haveBlock == block) return;
unsigned long missing;
if(block == 0)
{
missing = bufferSize+sampleSize
- refiller->read(buffer,bufferSize+sampleSize);
d->underrun = (missing == bufferSize+sampleSize);
}
else
{
/*
* try to drop away "half-sample" reads from the last refill
*/
if(dropBytes > 0)
dropBytes -= refiller->read(buffer,dropBytes);
/*
* only if this worked there is hope that we can read sane data
*/
if(dropBytes == 0)
{
missing = bufferSize
- refiller->read(&buffer[sampleSize], bufferSize);
d->underrun = (missing == bufferSize);
}
else
{
missing = bufferSize;
d->underrun = true;
}
}
haveBlock++;
assert(haveBlock == block);
/*
* If we don't have enough input to fill the block fully, it might be
* that the input stall occurred in the middle of a sample. For instance,
* if samples are 4 bytes long, it might be that we would have needed
* 13 more bytes to do a full refill.
*
* In this situation, there are four samples and one byte missing to
* refill the buffer - the one byte is what we need to care about here:
* on the next read, we'll have one byte too much (if we simply ignore
* the fact, we end up with misaligned reading, causing noise, or
* swapped stereo channels or similar).
*
* So we set dropBytes here, which is a variable which indicates how
* many bytes to drop away upon next refill.
*/
if(missing & (sampleSize - 1))
dropBytes = missing & (sampleSize - 1);
unsigned int i = 0, wrap = (block == 0)?0:sampleSize;
if(bits == 16)
{
// wrap the last part of the buffer back to the beginning (history)
while(i<wrap)
{
fbuffer[i/2] = fbuffer[(bufferSize+i)/2];
i += 2;
}
// convert data from incoming
if(d->endianness == littleEndian)
{
while(i<bufferSize+sampleSize-missing)
{
fbuffer[i/2] = conv_16_float(compose_16le(buffer[i],buffer[i+1]));
i += 2;
}
}
else
{
while(i<bufferSize+sampleSize-missing)
{
fbuffer[i/2] = conv_16_float(compose_16be(buffer[i],buffer[i+1]));
i += 2;
}
}
// fill up missing bytes with zero samples
while(i<bufferSize+sampleSize)
{
fbuffer[i/2] = 0.0;
i += 2;
}
}
else if(bits == 8)
{
// wrap the last part of the buffer back to the beginning (history)
while(i<wrap)
{
fbuffer[i] = fbuffer[bufferSize+i];
i++;
}
// convert data from incoming
while(i<bufferSize+sampleSize-missing)
{
fbuffer[i] = conv_8_float(buffer[i]);
i++;
}
// fill up missing bytes with zero samples
while(i<bufferSize+sampleSize)
{
fbuffer[i++] = 0.0;
}
}
else
{
assert(false);
}
}
#define RESAMPLER_STEP() \
pos += step; \
i++; \
while(pos >= bufferSamples) \
{ \
pos -= bufferSamples; \
block++; \
ensureRefill(); \
}
void Resampler::run(float *left, float *right, unsigned long samples)
{
ensureRefill();
unsigned long i = 0;
double delta = step - floor(step);
bool interpolate = fabs(delta) > 0.001;
if(channels == 2 && interpolate)
{
while(i < samples)
{
double error = pos - floor(pos);
unsigned long offset = 2*(unsigned long)pos;
left[i] = fbuffer[offset+0]*(1.0-error)+fbuffer[offset+2]*error;
right[i] = fbuffer[offset+1]*(1.0-error)+fbuffer[offset+3]*error;
RESAMPLER_STEP();
}
}
else if(channels == 1 && interpolate)
{
while(i < samples)
{
double error = pos - floor(pos);
unsigned long offset = (unsigned long)pos;
left[i] = right[i] = fbuffer[offset]*(1.0-error)
+ fbuffer[offset+1]*error;
RESAMPLER_STEP();
}
}
else if(channels == 2)
{
while(i < samples)
{
unsigned long offset = 2*(unsigned long)pos;
left[i] = fbuffer[offset+0];
right[i] = fbuffer[offset+1];
RESAMPLER_STEP();
}
}
else if(channels == 1)
{
while(i < samples)
{
unsigned long offset = (unsigned long)pos;
left[i] = right[i] = fbuffer[offset];
RESAMPLER_STEP();
}
}
else
{
assert(false);
}
}
Refiller::~Refiller()
{
}
#undef RESAMPLER_STEP
#undef compose_16le
#undef compose_16be
#undef conv_16_float
#undef conv_8_float
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