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I have a really short audio file, say a 10th of a second in (say) .PCM format

I want to use RemoteIO to loop through the file repeatedly to produce a continuous musical tone. So how do I read this into an array of floats?

EDIT: while I could probably dig out the file format, extract the file into an NSData and process it manually, I'm guessing there is a more sensible generic approach... ( that eg copes with different formats )

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Why won't a NSData of the file suffice? –  August Lilleaas Sep 24 '11 at 7:16
I am guessing every audio file format will have some header information. Otherwise how would it know the sample rate / data format etc? –  P i Sep 24 '11 at 7:28

3 Answers 3

You can use ExtAudioFile to read data from any supported data format in numerous client formats. Here is an example to read a file as 16-bit integers:

CFURLRef url = /* ... */;
ExtAudioFileRef eaf;
OSStatus err = ExtAudioFileOpenURL((CFURLRef)url, &eaf);
if(noErr != err)
  /* handle error */

AudioStreamBasicDescription format;
format.mSampleRate = 44100;
format.mFormatID = kAudioFormatLinearPCM;
format.mFormatFlags = kAudioFormatFormatFlagIsPacked;
format.mBitsPerChannel = 16;
format.mChannelsPerFrame = 2;
format.mBytesPerFrame = format.mChannelsPerFrame * 2;
format.mFramesPerPacket = 1;
format.mBytesPerPacket = format.mFramesPerPacket * format.mBytesPerFrame;

err = ExtAudioFileSetProperty(eaf, kExtAudioFileProperty_ClientDataFormat, sizeof(format), &format);

/* Read the file contents using ExtAudioFileRead */

If you wanted Float32 data, you would set up format like this:

format.mFormatID = kAudioFormatLinearPCM;
format.mFormatFlags = kAudioFormatFlagsNativeFloatPacked;
format.mBitsPerChannel = 32;
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Looks like you found a superior api for reading audio files, but part of the code confuses me. Specifically, can you set the format using ExtAudioFileSetProperty(...), and if you do, does this do some kind of data conversion for you since the wav might have a different format than that specified? Honestly I'm curious to know. I was unaware of the Extended Audio File Services until you posted, so I have no experience with it. –  Sam Oct 4 '11 at 20:28
ExtAudioFile is a wrapper around a combination of an AudioFile and an AudioConverter. Whatever client format is set will be used in calls to ExtAudioFileRead and ExtAudioFileWrite, and the internal AudioConverter will convert from the client format to the file's data format. –  sbooth Oct 5 '11 at 0:39
+1 Good to know –  Sam Oct 5 '11 at 16:00

I'm not familiar with RemoteIO, but I am familiar with WAV's and thought I'd post some format information on them. If you need, you should be able to easily parse out information such as duration, bit rate, etc...

First, here is an excellent website detailing the WAVE PCM soundfile format. This site also does an excellent job illustrating what the different byte addresses inside the "fmt" sub-chunk refer to.

WAVE File format

  • A WAVE is composed of a "RIFF" chunk and subsequent sub-chunks
  • Every chunk is at least 8 bytes
  • First 4 bytes is the Chunk ID
  • Next 4 bytes is the Chunk Size (The Chunk Size gives the size of the remainder of the chunk excluding the 8 bytes used for the Chunk ID and Chunk Size)
  • Every WAVE has the following chunks / sub chunks
    • "RIFF" (first and only chunk. All the rest are technically sub-chunks.)
    • "fmt " (usually the first sub-chunk after "RIFF" but can be anywhere between "RIFF" and "data". This chunk has information about the WAV such as number of channels, sample rate, and byte rate)
    • "data" (must be the last sub-chunk and contains all the sound data)

Common WAVE Audio Formats:

  • PCM
  • IEEE_Float
  • PCM_EXTENSIBLE (with a sub format of PCM or IEEE_FLOAT)

WAVE Duration and Size

A WAVE File's duration can be calculated as follows:

seconds = DataChunkSize / ByteRate


ByteRate = SampleRate * NumChannels * BitsPerSample/8

and DataChunkSize does not include the 8 bytes reserved for the ID and Size of the "data" sub-chunk.

Knowing this, the DataChunkSize can be calculated if you know the duration of the WAV and the ByteRate.

DataChunkSize = seconds * ByteRate

This can be useful for calculating the size of the wav data when converting from formats like mp3 or wma. Note that a typical wav header is 44 bytes followed by DataChunkSize (this is always the case if the wav was converted using the Normalizer tool - at least as of this writing).

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This is the code I have used to convert my audio data (audio file ) into floating point representation and saved into an array.

-(void) PrintFloatDataFromAudioFile {

NSString *  name = @"Filename";  //YOUR FILE NAME
NSString * source = [[NSBundle mainBundle] pathForResource:name ofType:@"m4a"]; // SPECIFY YOUR FILE FORMAT

const char *cString = [source cStringUsingEncoding:NSASCIIStringEncoding];

CFStringRef str = CFStringCreateWithCString(
CFURLRef inputFileURL = CFURLCreateWithFileSystemPath(

ExtAudioFileRef fileRef;
ExtAudioFileOpenURL(inputFileURL, &fileRef);

  AudioStreamBasicDescription audioFormat;
audioFormat.mSampleRate = 44100;   // GIVE YOUR SAMPLING RATE 
audioFormat.mFormatID = kAudioFormatLinearPCM;
audioFormat.mFormatFlags = kLinearPCMFormatFlagIsFloat;
audioFormat.mBitsPerChannel = sizeof(Float32) * 8;
audioFormat.mChannelsPerFrame = 1; // Mono
audioFormat.mBytesPerFrame = audioFormat.mChannelsPerFrame * sizeof(Float32);  // == sizeof(Float32)
audioFormat.mFramesPerPacket = 1;
audioFormat.mBytesPerPacket = audioFormat.mFramesPerPacket * audioFormat.mBytesPerFrame; // = sizeof(Float32)

// 3) Apply audio format to the Extended Audio File
                        sizeof (AudioStreamBasicDescription), //= audioFormat

int numSamples = 1024; //How many samples to read in at a time
UInt32 sizePerPacket = audioFormat.mBytesPerPacket; // = sizeof(Float32) = 32bytes
UInt32 packetsPerBuffer = numSamples;
UInt32 outputBufferSize = packetsPerBuffer * sizePerPacket;

// So the lvalue of outputBuffer is the memory location where we have reserved space
UInt8 *outputBuffer = (UInt8 *)malloc(sizeof(UInt8 *) * outputBufferSize);

AudioBufferList convertedData ;//= malloc(sizeof(convertedData));

convertedData.mNumberBuffers = 1;    // Set this to 1 for mono
convertedData.mBuffers[0].mNumberChannels = audioFormat.mChannelsPerFrame;  //also = 1
convertedData.mBuffers[0].mDataByteSize = outputBufferSize;
convertedData.mBuffers[0].mData = outputBuffer; //

UInt32 frameCount = numSamples;
float *samplesAsCArray;
int j =0;

while (frameCount > 0) {
    if (frameCount > 0)  {
        AudioBuffer audioBuffer = convertedData.mBuffers[0];
        samplesAsCArray = (float *)audioBuffer.mData; // CAST YOUR mData INTO FLOAT

       for (int i =0; i<1024 /*numSamples */; i++) { //YOU CAN PUT numSamples INTEAD OF 1024

            floatDataArray[j] = (double)samplesAsCArray[i] ; //PUT YOUR DATA INTO FLOAT ARRAY
              printf("\n%f",floatDataArray[j]);  //PRINT YOUR ARRAY'S DATA IN FLOAT FORM RANGING -1 TO +1

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Thanks for the snippet. I had to use malloc to init floatDataArray on iOS. Other than that, works great. –  VaporwareWolf Aug 27 '14 at 19:14

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