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i am interested in FFT analysis for mac osx. I have found an tutorial for iOS (http://demetrimiller.com/2011/01/25/pitch-detection-in-ios-4-x/) and tried to "port" it to OSX.

I have created a new Xcode-Project, integrated the code and removed the visible bugs. Although is does not work :(

I tried many modifications about the AudioUnit part, but it does not help.

Has anybody an idea what is wrong? Thank you very much :)


#import <Cocoa/Cocoa.h>

@class RIOInterface;

@interface myView : NSView {

BOOL isListening;
RIOInterface *rioRef;

NSMutableString *key;
float currentFrequency;
NSString *prevChar;

@property(nonatomic, retain) NSMutableString *key;
@property(nonatomic, retain) NSString *prevChar;
@property(readwrite) RIOInterface *rioRef;
@property(nonatomic, assign) float currentFrequency;
@property(assign) BOOL isListening;

#pragma mark Listener Controls
- (IBAction)toggleListening:(id)sender;
- (void)startListener;
- (void)stopListener;

- (void)frequencyChangedWithValue:(float)newFrequency;
- (void)updateFrequencyLabel;



#import "myView.h"
#import "RIOInterface.h"

@implementation myView
@synthesize key;
@synthesize prevChar;
@synthesize isListening;
@synthesize rioRef;
@synthesize currentFrequency;

#pragma mark -
#pragma mark Listener Controls
- (void)toggleListening {
if (isListening) {
    [self stopListener];
} else {
    [self startListener];

isListening = !isListening;

- (void)startListener {
[rioRef startListening:self];

- (void)stopListener {
[rioRef stopListening];

#pragma mark -
#pragma mark Lifecycle
// Implement viewDidLoad to do additional setup after loading the view, typically from a     nib.
- (void)viewDidLoad {
rioRef = [RIOInterface sharedInstance];
[self toggleListening];

-(id)initWithCoder:(NSCoder *)coder

if (self = [super initWithCoder:coder]) {

    [self viewDidLoad];

return self;



#import <Foundation/Foundation.h>
#import <AudioUnit/AudioUnit.h>
#import <AVFoundation/AVFoundation.h>
#import <AudioToolbox/AudioToolbox.h>
#import <Accelerate/Accelerate.h>
#include <stdlib.h>

@class myView;

 *  This is a singleton class that manages all the low level CoreAudio/RemoteIO
 *  elements. A singleton is used since we should never be instantiating more
 *  than one instance of this class per application lifecycle.

#define kInputBus 1
#define kOutputBus 0
#define kBufferSize 1024
#define kBufferCount 1
#define N 10

@interface RIOInterface : NSObject {
NSView *selectedViewController;
myView *listener;

AUGraph processingGraph;
AudioUnit ioUnit;
AudioBufferList* bufferList;
AudioStreamBasicDescription streamFormat;

FFTSetup fftSetup;
int log2n, n, nOver2;

void *dataBuffer;
float *outputBuffer;
size_t bufferCapacity;  // In samples
size_t index;   // In samples

float sampleRate;
float frequency;

@property(nonatomic, assign) id<AVAudioPlayerDelegate> audioPlayerDelegate;
@property(readwrite) myView *listener;

@property(assign) float sampleRate;
@property(assign) float frequency;

#pragma mark Lifecycle

#pragma mark Audio Session/Graph Setup
- (void)initializeAudioSession;
- (void)createAUProcessingGraph;
- (size_t)ASBDForSoundMode;

#pragma mark Playback Controls
- (void)startPlayback;
- (void)startPlaybackFromEncodedArray:(NSArray *)encodedArray;
- (void)stopPlayback;
- (void)printASBD:(AudioStreamBasicDescription)asbd;

#pragma mark Listener Controls
- (void)startListening:(myView*)aListener;
- (void)stopListening;

#pragma mark Generic Audio Controls
- (void)initializeAndStartProcessingGraph;
- (void)stopProcessingGraph;

#pragma mark Singleton Methods
+ (RIOInterface *)sharedInstance;



#import "RIOInterface.h"
#import "CAStreamBasicDescription.h"
#import "CAXException.h"
#import "myView.h"

@implementation RIOInterface

@synthesize listener;
@synthesize audioPlayerDelegate;
@synthesize sampleRate;
@synthesize frequency;

float MagnitudeSquared(float x, float y);
void ConvertInt16ToFloat(RIOInterface* THIS, void *buf, float *outputBuf, size_t capacity);

#pragma mark -
#pragma mark Lifecycle

- (void)dealloc {
if (processingGraph) {


#pragma mark -
#pragma mark Playback Controls
- (void)startPlayback {
[self createAUProcessingGraph];
[self initializeAndStartProcessingGraph];

- (void)startPlaybackFromEncodedArray:(NSArray *)encodedArray {
// TODO: once we have our generated array, set up the timer to
// play the encoded array correctly.

- (void)stopPlayback {

#pragma mark -
#pragma mark Listener Controls
- (void)startListening:(myView*)aListener {
self.listener = aListener;
[self createAUProcessingGraph];
[self initializeAndStartProcessingGraph];

- (void)stopListening {
[self stopProcessingGraph];

#pragma mark -
#pragma mark Generic Audio Controls
- (void)initializeAndStartProcessingGraph {
OSStatus result = AUGraphInitialize(processingGraph);
if (result >= 0) {
} else {
    XThrow(result, "error initializing processing graph");

- (void)stopProcessingGraph {

#pragma mark -
#pragma mark Audio Rendering
OSStatus RenderFFTCallback (void                    *inRefCon,
                        AudioUnitRenderActionFlags  *ioActionFlags,
                        const AudioTimeStamp            *inTimeStamp,
                        UInt32                      inBusNumber,
                        UInt32                      inNumberFrames,
                        AudioBufferList             *ioData)
RIOInterface* THIS = (__bridge RIOInterface *)inRefCon;
void *dataBuffer = THIS->dataBuffer;
float *outputBuffer = THIS->outputBuffer;
FFTSetup fftSetup = THIS->fftSetup;

uint32_t log2n = THIS->log2n;
uint32_t n = THIS->n;
uint32_t nOver2 = THIS->nOver2;
uint32_t stride = 1;
int bufferCapacity = THIS->bufferCapacity;
SInt16 index = THIS->index;

AudioUnit rioUnit = THIS->ioUnit;
OSStatus renderErr;
UInt32 bus1 = 1;

renderErr = AudioUnitRender(rioUnit, ioActionFlags,
                            inTimeStamp, bus1, inNumberFrames, THIS->bufferList);
if (renderErr < 0) {
    return renderErr;

// Fill the buffer with our sampled data. If we fill our buffer, run the
// fft.
int read = bufferCapacity - index;
if (read > inNumberFrames) {
    memcpy((SInt16 *)dataBuffer + index, THIS->bufferList->mBuffers[0].mData, inNumberFrames*sizeof(SInt16));
    THIS->index += inNumberFrames;
} else {
    // If we enter this conditional, our buffer will be filled and we should
    // perform the FFT.
    memcpy((SInt16 *)dataBuffer + index, THIS->bufferList->mBuffers[0].mData, read*sizeof(SInt16));

    // Reset the index.
    THIS->index = 0;

    /*************** FFT ***************/
    // We want to deal with only floating point values here.
    ConvertInt16ToFloat(THIS, dataBuffer, outputBuffer, bufferCapacity);

     Look at the real signal as an interleaved complex vector by casting it.
     Then call the transformation function vDSP_ctoz to get a split complex
     vector, which for a real signal, divides into an even-odd configuration.
    vDSP_ctoz((COMPLEX*)outputBuffer, 2, &A, 1, nOver2);

    // Carry out a Forward FFT transform.
    vDSP_fft_zrip(fftSetup, &A, stride, log2n, FFT_FORWARD);

    // The output signal is now in a split real form. Use the vDSP_ztoc to get
    // a split real vector.
    vDSP_ztoc(&A, 1, (COMPLEX *)outputBuffer, 2, nOver2);

    // Determine the dominant frequency by taking the magnitude squared and
    // saving the bin which it resides in.
    float dominantFrequency = 0;
    int bin = -1;
    for (int i=0; i<n; i+=2) {
        float curFreq = MagnitudeSquared(outputBuffer[i], outputBuffer[i+1]);
        if (curFreq > dominantFrequency) {
            dominantFrequency = curFreq;
            bin = (i+1)/2;
    memset(outputBuffer, 0, n*sizeof(SInt16));

    printf("Dominant frequency: %f   bin: %d \n", bin*(THIS->sampleRate/bufferCapacity), bin);

return noErr;

float MagnitudeSquared(float x, float y) {
return ((x*x) + (y*y));

void ConvertInt16ToFloat(RIOInterface* THIS, void *buf, float *outputBuf, size_t capacity) {
AudioConverterRef converter;
OSStatus err;

size_t bytesPerSample = sizeof(float);
AudioStreamBasicDescription outFormat = {0};
outFormat.mFormatID = kAudioFormatLinearPCM;
outFormat.mFormatFlags = kAudioFormatFlagIsFloat | kAudioFormatFlagIsPacked;
outFormat.mBitsPerChannel = 8 * bytesPerSample;
outFormat.mFramesPerPacket = 1;
outFormat.mChannelsPerFrame = 1;
outFormat.mBytesPerPacket = bytesPerSample * outFormat.mFramesPerPacket;
outFormat.mBytesPerFrame = bytesPerSample * outFormat.mChannelsPerFrame;
outFormat.mSampleRate = THIS->sampleRate;

const AudioStreamBasicDescription inFormat = THIS->streamFormat;

UInt32 inSize = capacity*sizeof(SInt16);
UInt32 outSize = capacity*sizeof(float);
err = AudioConverterNew(&inFormat, &outFormat, &converter);
err = AudioConverterConvertBuffer(converter, inSize, buf, &outSize, outputBuf);

/* Setup our FFT */
- (void)realFFTSetup {
UInt32 maxFrames = 2048;
dataBuffer = (void*)malloc(maxFrames * sizeof(SInt16));
outputBuffer = (float*)malloc(maxFrames *sizeof(float));
log2n = log2f(maxFrames);
n = 1 << log2n;
assert(n == maxFrames);
nOver2 = maxFrames/2;
bufferCapacity = maxFrames;
index = 0;
A.realp = (float *)malloc(nOver2 * sizeof(float));
A.imagp = (float *)malloc(nOver2 * sizeof(float));
fftSetup = vDSP_create_fftsetup(log2n, FFT_RADIX2);

#pragma mark -
#pragma mark Audio Session/Graph Setup
// Sets up the audio session based on the properties that were set in the init
// method.
- (void)initializeAudioSession {
NSError *err = nil;
    // After activation, update our sample rate. We need to update because there
// is a possibility the system cannot grant our request.

[self realFFTSetup];

// This method will create an AUGraph for either input or output.
// Our application will never perform both operations simultaneously.
- (void)createAUProcessingGraph {
OSStatus err;
// Configure the search parameters to find the default playback output unit
// (called the kAudioUnitSubType_RemoteIO on iOS but
// kAudioUnitSubType_DefaultOutput on Mac OS X)
AudioComponentDescription ioUnitDescription;
ioUnitDescription.componentType = kAudioUnitType_Output;
ioUnitDescription.componentSubType = kAudioUnitSubType_DefaultOutput;
ioUnitDescription.componentManufacturer = kAudioUnitManufacturer_Apple;
ioUnitDescription.componentFlags = 0;
ioUnitDescription.componentFlagsMask = 0;

// Declare and instantiate an audio processing graph

// Add an audio unit node to the graph, then instantiate the audio unit.
 An AUNode is an opaque type that represents an audio unit in the context
 of an audio processing graph. You receive a reference to the new audio unit
 instance, in the ioUnit parameter, on output of the AUGraphNodeInfo
 function call.
AUNode ioNode;
AUGraphAddNode(processingGraph, &ioUnitDescription, &ioNode);

AUGraphOpen(processingGraph); // indirectly performs audio unit instantiation

// Obtain a reference to the newly-instantiated I/O unit. Each Audio Unit
// requires its own configuration.
AUGraphNodeInfo(processingGraph, ioNode, NULL, &ioUnit);

// Initialize below.
AURenderCallbackStruct callbackStruct = {0};
UInt32 enableInput;
UInt32 enableOutput;

// Enable input and disable output.
enableInput = 1; enableOutput = 0;
callbackStruct.inputProc = RenderFFTCallback;

err = AudioUnitSetProperty(ioUnit, kAudioOutputUnitProperty_EnableIO,
                           kInputBus, &enableInput,     sizeof(enableInput));

err = AudioUnitSetProperty(ioUnit, kAudioOutputUnitProperty_EnableIO,
                           kOutputBus, &enableOutput, sizeof(enableOutput));

err = AudioUnitSetProperty(ioUnit, kAudioOutputUnitProperty_SetInputCallback,
                           kOutputBus, &callbackStruct, sizeof(callbackStruct));

// Set the stream format.
size_t bytesPerSample = [self ASBDForSoundMode];

err = AudioUnitSetProperty(ioUnit, kAudioUnitProperty_StreamFormat,
                           kInputBus, &streamFormat, sizeof(streamFormat));

err = AudioUnitSetProperty(ioUnit, kAudioUnitProperty_StreamFormat,
                           kOutputBus, &streamFormat, sizeof(streamFormat));

// Disable system buffer allocation. We'll do it ourselves.
UInt32 flag = 0;
err = AudioUnitSetProperty(ioUnit, kAudioUnitProperty_ShouldAllocateBuffer,
                           kInputBus, &flag, sizeof(flag));

// Allocate AudioBuffers for use when listening.
// TODO: Move into initialization...should only be required once.
bufferList = (AudioBufferList *)malloc(sizeof(AudioBuffer));
bufferList->mNumberBuffers = 1;
bufferList->mBuffers[0].mNumberChannels = 1;

bufferList->mBuffers[0].mDataByteSize = kBufferSize*bytesPerSample;
bufferList->mBuffers[0].mData = calloc(kBufferSize, bytesPerSample);

// Set the AudioStreamBasicDescription for listening to audio data. Set the
// stream member var here as well.
- (size_t)ASBDForSoundMode {
AudioStreamBasicDescription asbd = {0};
size_t bytesPerSample;
bytesPerSample = sizeof(SInt16);
asbd.mFormatID = kAudioFormatLinearPCM;
asbd.mFormatFlags = kAudioFormatFlagIsSignedInteger | kAudioFormatFlagIsPacked;
asbd.mBitsPerChannel = 8 * bytesPerSample;
asbd.mFramesPerPacket = 1;
asbd.mChannelsPerFrame = 1;
asbd.mBytesPerPacket = bytesPerSample * asbd.mFramesPerPacket;
asbd.mBytesPerFrame = bytesPerSample * asbd.mChannelsPerFrame;
asbd.mSampleRate = sampleRate;

streamFormat = asbd;
[self printASBD:streamFormat];

return bytesPerSample;

#pragma mark -
#pragma mark Utility
- (void)printASBD:(AudioStreamBasicDescription)asbd {

char formatIDString[5];
UInt32 formatID = CFSwapInt32HostToBig (asbd.mFormatID);
bcopy (&formatID, formatIDString, 4);
formatIDString[4] = '\0';

NSLog (@"  Sample Rate:         %10.0f",  asbd.mSampleRate);
NSLog (@"  Format ID:           %10s",    formatIDString);
NSLog (@"  Format Flags:        %10lX",    asbd.mFormatFlags);
NSLog (@"  Bytes per Packet:    %10ld",    asbd.mBytesPerPacket);
NSLog (@"  Frames per Packet:   %10ld",    asbd.mFramesPerPacket);
NSLog (@"  Bytes per Frame:     %10ld",    asbd.mBytesPerFrame);
NSLog (@"  Channels per Frame:  %10ld",    asbd.mChannelsPerFrame);
NSLog (@"  Bits per Channel:    %10ld",    asbd.mBitsPerChannel);

// *************** Singleton *********************

static RIOInterface *sharedInstance = nil;

#pragma mark -
#pragma mark Singleton Methods
+ (RIOInterface *)sharedInstance
if (sharedInstance == nil) {
    sharedInstance = [[RIOInterface alloc] init];

return sharedInstance;

+ (id)allocWithZone:(NSZone *)zone {
@synchronized(self) {
    if (sharedInstance == nil) {
        sharedInstance = [super allocWithZone:zone];
        return sharedInstance;  // assignment and return on first allocation
return nil; // on subsequent allocation attempts return nil

- (id)copyWithZone:(NSZone *)zone {
return self;

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2 Answers 2

up vote 0 down vote accepted

You can't use kAudioUnitSubType_DefaultOutput on a Mac for microphone input.

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what should i use instead of it? –  He Fo Sep 13 '13 at 16:41

-for audio unit sub type try


yet, unless you really know how to port iOS audio apps to OSX, I would suggest to break the ice by porting a much simpler proces than fft (such as play-through), then use the learned hands-on experience in more demanding scenarios. It has issues way too complex to fit into a mail reply. The learning curve is steep, there in no short way of understanding how things work. Be patient, it's not a quick fix job.

On the other hand, if you'd like to examine a working example of FFT on a Mac, perhaps you might also take a look at this:



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