How to manually convert 8.24-bit deinterleaved lpcm to 16-bit lpcm?

I have a chunk of data (void*) which is 2 ch, 44100 Hz, 'lpcm' 8.24-bit little-endian signed integer, deinterleaved. I need to record that chunk to a file as 2 ch, 44100 Hz, 'lpcm' 16-bit little-endian signed integer.

How do I convert data? I can imagine I need to do something like this:

uint dataByteSize = sizeof(UInt32) * samplesCount;
UInt32* source = ...;
UInt32* dest = (UInt32*)malloc(dataByteSize);
for (int i = 0; i < samplesCount; ++i) {
UInt32 sourceSample = source[i];
UInt32 destSample = sourceSample>>24;
dest[i] = destSample;
}


But how do I convert deinterleaved to interleaved?

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What do you mean when you say your chunk of void * data is deinterleaved? Is the first half the entire L channel followed by the entire R channel samples? Typically deinterleaved data is stored in multiple buffers. –  sbooth Mar 18 '11 at 4:20

Ok, I've spent some time investigating the issue and realized that question contains too few information to be answered =) So heres the deal:

First, about non-interleaved: I initially thought that it would look like this: l1 l2 l3 l4...ln r1 r2 r3 r4...rn But it turned out that in my data right channel was just missing. It turned out that it wasn't a non-interleaved data, it was just a plain mono data. And yes, it should always be multiple buffers in case data is actually non-interleaved. If it's interleaved, it should be l1 r1 l2 r2 l3 r3 l4 r4...

Second, about actual transformation: it all depends on the range of samples. In my case (and in any case where core audio is involved if I'm correct) fixed-point 8.24 values should range between (-1, 1), while 16-bit signed values should range between (-32768, 32767). So 8.24 value will always have its first 8 bits set either to 0 (in case it is positive) or to 1 (in case it is negative). This first 8 bits should be removed (preserving sign ofc). Also you can remove as many trailing bits as you want - it'll just reduce quility of the sound, but it wont ruin the sound. In case of converting to 16 bits signed format, bits 8-22 (15 bits that is) will actually contain the data we need to use for SInt16. Bit 7 can be used as the sign bit. So to convert 8.24 to SInt16 you just need to shift 9 bits right (9 because you need to preserve the sign) and cast to SInt16

11111111 10110110 11101110 10000011 - > 11111111 11111111 (11011011 01110111)
00000000 01101111 00000000 11000001 - > 00000000 00000000 (00110111 10000000)

That's it. Nothing more then iterating through array and shifting bits right. Hope that's gonna save someone couple of hours.

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I'm glad to have found this! Something changed between iOS 4.2 and 4.3 and I found myself recording "static" instead of audio from the render notification callback via the Extended Audio Services. I tried setting kExtAudioFileProperty_ClientDataFormat to all sorts of things, but didn't manage to find the right combination. I had just started into figuring out how to do the conversion myself when I found your answer. Works like a champ! –  Fls'Zen Mar 25 '11 at 0:16
Very useful, thank you. –  Joe Qian Aug 24 '12 at 9:14
Thank you!!! I was wondering why my compression algorithm sounded so much like harmonic static! This explains it! –  David Morton Dec 6 '12 at 12:09
Well, this isn't actually the best way to preserve the data. If you have 24 bits of precision, that's a maximum of 16777215. So, the correct conversion is (assuming MASK masks off the sign bits) SIGN*((MASK & bit24Value) * (SHRT_MAX/16777215.0)) –  bobobobo Dec 28 '13 at 18:44
What this does is create an int value first (which will have maximum value 16777215), then it normalizes the value to be between 0.0 and 1.0 (as a double), then it expands that [0,1] value back out to between [0,SHRT_MAX]. You multiply by +1 or -1 in SIGN to preserve the sign. –  bobobobo Dec 28 '13 at 18:45

I have read the following clip in audiograph https://github.com/tkzic/audiograph

/* convert sample vector from fixed point 8.24 to SInt16 */
void fixedPointToSInt16( SInt32 * source, SInt16 * target, int length ) {
int i;

for(i = 0;i < length; i++ ) {
target[i] =  (SInt16) (source[i] >> 9);
}
}

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Best description can be found at http://lists.apple.com/archives/coreaudio-api/2011/Feb/msg00083.html

So,

8.24 numbers are interpreted as ranging from -128.000000000000 to +127.999999940393

But!

The convention in iOS/CoreAudio is to treat -1.000000000000 to +0.999969482421875 as non-clipped values that do not exceed Full Scale for the 16-bit analog audio converters.

Ok?

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I tested the popular method with shifting 9 bits and for some reason it does not work for me, as I further use the result to encode to ogg. The resulted ogg was verry noisy. What did work is this function, based on a method I found in audiograph https://github.com/tkzic/audiograph

void ConvertInputToInt16(AudioStreamBasicDescription inFormat, void *buf, void *outputBuf, size_t capacity) {
AudioConverterRef converter;
OSStatus err;

size_t bytesPerSample = sizeof(SInt16);
AudioStreamBasicDescription outFormat = {0};
outFormat.mFormatID = kAudioFormatLinearPCM;
outFormat.mFormatFlags = kAudioFormatFlagIsSignedInteger | kAudioFormatFlagIsPacked;
outFormat.mBitsPerChannel = 8 * bytesPerSample;
outFormat.mFramesPerPacket = 1;
outFormat.mChannelsPerFrame = 1;
outFormat.mBytesPerPacket = bytesPerSample * outFormat.mFramesPerPacket;
outFormat.mBytesPerFrame = bytesPerSample * outFormat.mChannelsPerFrame;
outFormat.mSampleRate = inFormat.mSampleRate;

NSLog(@"description for in format: %@", descriptionForAudioFormat(inFormat));
NSLog(@"description for out format: %@", descriptionForAudioFormat(outFormat));

UInt32 inSize = capacity*sizeof(SInt32);
UInt32 outSize = capacity*sizeof(SInt16);

// this is the famed audio converter

err = AudioConverterNew(&inFormat, &outFormat, &converter);
if(noErr != err) {
NSLog(@"error in audioConverterNew: %d", (int)err);
}

err = AudioConverterConvertBuffer(converter, inSize, buf, &outSize, outputBuf);
if(noErr != err) {
NSLog(@"error in audioConverterConvertBuffer: %d", err);
}

}

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