Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I am seeking an example of using Audio Queue Services.

I would like to create a sound using a mathematical equation and then hear it.

share|improve this question
up vote 23 down vote accepted

Here's my code for generating sound from a function. I'm assuming you know how to use AudioQueue services, set up an AudioSession, and properly start and stop an audio output queue.

Here's a snippet for setting up and starting an output AudioQueue:

// Get the preferred sample rate (8,000 Hz on iPhone, 44,100 Hz on iPod touch)
size = sizeof(sampleRate);
err = AudioSessionGetProperty (kAudioSessionProperty_CurrentHardwareSampleRate, &size, &sampleRate);
if (err != noErr) NSLog(@"AudioSessionGetProperty(kAudioSessionProperty_CurrentHardwareSampleRate) error: %d", err); 
//NSLog (@"Current hardware sample rate: %1.0f", sampleRate);

BOOL isHighSampleRate = (sampleRate > 16000);
int bufferByteSize;
AudioQueueBufferRef buffer;

// Set up stream format fields
AudioStreamBasicDescription streamFormat;
streamFormat.mSampleRate = sampleRate;
streamFormat.mFormatID = kAudioFormatLinearPCM;
streamFormat.mFormatFlags = kLinearPCMFormatFlagIsSignedInteger | kLinearPCMFormatFlagIsPacked;
streamFormat.mBitsPerChannel = 16;
streamFormat.mChannelsPerFrame = 1;
streamFormat.mBytesPerPacket = 2 * streamFormat.mChannelsPerFrame;
streamFormat.mBytesPerFrame = 2 * streamFormat.mChannelsPerFrame;
streamFormat.mFramesPerPacket = 1;
streamFormat.mReserved = 0;

// New output queue ---- PLAYBACK ----
if (isPlaying == NO) {
    err = AudioQueueNewOutput (&streamFormat, AudioEngineOutputBufferCallback, self, nil, nil, 0, &outputQueue);
    if (err != noErr) NSLog(@"AudioQueueNewOutput() error: %d", err);

    // Enqueue buffers
    //outputFrequency = 0.0;
    outputBuffersToRewrite = 3;
    bufferByteSize = (sampleRate > 16000)? 2176 : 512; // 40.5 Hz : 31.25 Hz 
    for (i=0; i<3; i++) {
        err = AudioQueueAllocateBuffer (outputQueue, bufferByteSize, &buffer); 
        if (err == noErr) {
            [self generateTone: buffer];
            err = AudioQueueEnqueueBuffer (outputQueue, buffer, 0, nil);
            if (err != noErr) NSLog(@"AudioQueueEnqueueBuffer() error: %d", err);
        } else {
            NSLog(@"AudioQueueAllocateBuffer() error: %d", err); 
            return;
        }
    }

    // Start playback
    isPlaying = YES;
    err = AudioQueueStart(outputQueue, nil);
    if (err != noErr) { NSLog(@"AudioQueueStart() error: %d", err); isPlaying= NO; return; }
} else {
    NSLog (@"Error: audio is already playing back.");
}

Here's the part that generates the tone:

// AudioQueue output queue callback.
void AudioEngineOutputBufferCallback (void *inUserData, AudioQueueRef inAQ, AudioQueueBufferRef inBuffer) {
    AudioEngine *engine = (AudioEngine*) inUserData;
    [engine processOutputBuffer:inBuffer queue:inAQ];
}

- (void) processOutputBuffer: (AudioQueueBufferRef) buffer queue:(AudioQueueRef) queue {
    OSStatus err;
    if (isPlaying == YES) {
        [outputLock lock];
        if (outputBuffersToRewrite > 0) {
            outputBuffersToRewrite--;
            [self generateTone:buffer];
        }
        err = AudioQueueEnqueueBuffer(queue, buffer, 0, NULL);
        if (err == 560030580) { // Queue is not active due to Music being started or other reasons
            isPlaying = NO;
        } else if (err != noErr) {
            NSLog(@"AudioQueueEnqueueBuffer() error %d", err);
        }
        [outputLock unlock];
    } else {
        err = AudioQueueStop (queue, NO);
        if (err != noErr) NSLog(@"AudioQueueStop() error: %d", err);
    }
}

-(void) generateTone: (AudioQueueBufferRef) buffer {
    if (outputFrequency == 0.0) {
        memset(buffer->mAudioData, 0, buffer->mAudioDataBytesCapacity);
        buffer->mAudioDataByteSize = buffer->mAudioDataBytesCapacity;
    } else {
        // Make the buffer length a multiple of the wavelength for the output frequency.
        int sampleCount = buffer->mAudioDataBytesCapacity / sizeof (SInt16);
        double bufferLength = sampleCount;
        double wavelength = sampleRate / outputFrequency;
        double repetitions = floor (bufferLength / wavelength);
        if (repetitions > 0.0) {
            sampleCount = round (wavelength * repetitions);
        }

        double      x, y;
        double      sd = 1.0 / sampleRate;
        double      amp = 0.9;
        double      max16bit = SHRT_MAX;
        int i;
        SInt16 *p = buffer->mAudioData;

        for (i = 0; i < sampleCount; i++) {
            x = i * sd * outputFrequency;
            switch (outputWaveform) {
                case kSine: 
                    y = sin (x * 2.0 * M_PI);
                    break;
                case kTriangle:
                    x = fmod (x, 1.0);
                    if (x < 0.25)
                        y = x * 4.0; // up 0.0 to 1.0
                    else if (x < 0.75)
                        y = (1.0 - x) * 4.0 - 2.0; // down 1.0 to -1.0
                    else 
                        y = (x - 1.0) * 4.0; // up -1.0 to 0.0
                    break;
                case kSawtooth:
                    y  = 0.8 - fmod (x, 1.0) * 1.8;
                    break;
                case kSquare:
                    y = (fmod(x, 1.0) < 0.5)? 0.7: -0.7;
                    break;
                default: y = 0; break;
            }
            p[i] = y * max16bit * amp;
        }

        buffer->mAudioDataByteSize = sampleCount * sizeof (SInt16);
    }
}

Something to watch out for is that your callback will be called on a non-main thread, so you have to practice thread safety with locks, mutexs, or other techniques.

share|improve this answer

This is a version using C# of the same sample from @lucius

    void SetupAudio ()
    {
        AudioSession.Initialize ();
        AudioSession.Category = AudioSessionCategory.MediaPlayback;

        sampleRate = AudioSession.CurrentHardwareSampleRate;
        var format = new AudioStreamBasicDescription () {
            SampleRate = sampleRate,
            Format = AudioFormatType.LinearPCM,
            FormatFlags = AudioFormatFlags.LinearPCMIsSignedInteger | AudioFormatFlags.LinearPCMIsPacked,
            BitsPerChannel = 16,
            ChannelsPerFrame = 1,
            BytesPerFrame = 2,
            BytesPerPacket = 2, 
            FramesPerPacket = 1,
        };

        var queue = new OutputAudioQueue (format);
        var bufferByteSize = (sampleRate > 16000)? 2176 : 512; // 40.5 Hz : 31.25 Hz 
        var buffers = new AudioQueueBuffer* [numBuffers];
        for (int i = 0; i < numBuffers; i++){
            queue.AllocateBuffer (bufferByteSize, out buffers [i]);
            GenerateTone (buffers [i]);
            queue.EnqueueBuffer (buffers [i], null);
        }
        queue.OutputCompleted += (object sender, OutputCompletedEventArgs e) => {
            queue.EnqueueBuffer (e.UnsafeBuffer, null);
        };

        queue.Start ();
        return true;
    }

This is the tone generator:

    void GenerateTone (AudioQueueBuffer *buffer)
    {
        // Make the buffer length a multiple of the wavelength for the output frequency.
        uint sampleCount = buffer->AudioDataBytesCapacity / 2;
        double bufferLength = sampleCount;
        double wavelength = sampleRate / outputFrequency;
        double repetitions = Math.Floor (bufferLength / wavelength);
        if (repetitions > 0) 
            sampleCount = (uint)Math.Round (wavelength * repetitions);

        double      x, y;
        double      sd = 1.0 / sampleRate;
        double      amp = 0.9;
        double      max16bit = Int16.MaxValue;
        int i;
        short *p = (short *) buffer->AudioData;

        for (i = 0; i < sampleCount; i++) {
            x = i * sd * outputFrequency;
            switch (outputWaveForm) {
                case WaveForm.Sine: 
                    y = Math.Sin (x * 2.0 * Math.PI);
                    break;
                case WaveForm.Triangle:
                    x = x % 1.0;
                    if (x < 0.25)
                        y = x * 4.0; // up 0.0 to 1.0
                    else if (x < 0.75)
                        y = (1.0 - x) * 4.0 - 2.0; // down 1.0 to -1.0
                    else 
                        y = (x - 1.0) * 4.0; // up -1.0 to 0.0
                    break;
                case WaveForm.Sawtooth:
                    y  = 0.8 - (x % 1.0) * 1.8;
                    break;
                case WaveForm.Square:
                    y = ((x % 1.0) < 0.5)? 0.7: -0.7;
                    break;
                default: y = 0; break;
            }
            p[i] = (short)(y * max16bit * amp);
        }
        buffer->AudioDataByteSize = sampleCount * 2;
    }
}

You also want these definitions:

    enum WaveForm {
        Sine, Triangle, Sawtooth, Square
    }
    WaveForm outputWaveForm;
    const float outputFrequency = 220;
share|improve this answer

High level: use AVAudioPlayer https://github.com/hollance/AVBufferPlayer

Med level: audio queues http://trailsinthesand.com/exploring-iphone-audio-part-1/ gets you going nicely.

Low level: alternatively, you can drop down a level and do it with audio units: http://cocoawithlove.com/2010/10/ios-tone-generator-introduction-to.html

share|improve this answer
2  
Audio Queues in Synth: github.com/hollance/AudioBufferPlayer – P i Apr 11 '11 at 13:01
    
your example helped me a lot, Thanks again – Amitg2k12 May 14 '11 at 14:53
    
trailsinthesand.com is now an adult website – blwinters Sep 12 '15 at 18:50
    
@blwinters, so it is?! Those cheeky trannies... luring us in -- they will stop at nothing! – P i Sep 14 '15 at 0:49

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.