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Exploring the Windows Vista Audio Engine

This topic presents an overview of the Windows Vista audio engine. It focuses on concepts that will help you understand how APOs and sAPOs work together.

The following diagram presents a simplified layout of the internal structure of the audio engine.

Diagram illustrating the simplified layout of a Windows Vista audio engine.

As the diagram shows, system-supplied APOs and sAPOs are the basic building blocks of the audio engine. The audio engine configures the system-supplied APOs and sAPOs into components called pipes. There are two types of pipes in the audio engine:

  • Stream pipes are made up of APOs and sAPOs that perform digital audio processing that is local to the stream from a single application. The sAPO in this type of pipe is referred to as local effects sAPO (LFX sAPO).

  • Device pipes are made up of APOs and sAPOs that perform digital audio processing that affects all the streams globally. The sAPO in this type of pipe is called a global effects sAPO (GFX sAPO).

The following table shows the sAPOs that are available in the Windows Vista audio engine and the type of system effects that they apply.

Windows Vista sAPO System effect

Bass Boost

LFX

Bass Management

LFX

Loudness Equalization

LFX

Low Frequency Protection

LFX

Speaker Fill

LFX

Speaker Phantoming

LFX

Virtual Surround

LFX

Virtualized Surround over Headphones

LFX

Enhanced Sound for Portable Computers

GFX

Room Correction

GFX

When an audio application initiates audio processing, the audio engine configures the system-supplied APOs and the sAPOs into an audio graph to process the digital audio data. The mechanism the audio engine uses for building the audio graph is a system detail and will not be discussed.

The audio application can initiate the connection in shared mode or exclusive mode. Although a default set of sAPOs is installed with Windows Vista, sAPOs are not considered to be system components and are therefore customizable.

Shared mode

In shared mode, an audio application shares the audio hardware with other audio applications that are running in other processes. The audio engine mixes the streams from these applications and plays the resulting mix through the hardware. Any application that opens a stream in shared mode must select the mix format that is used by the audio engine. The advantage of using shared mode is that the Windows Vista audio engine provides a built-in Audio Processing Object (APO) to provide the necessary supporting functionality. The disadvantage of using shared mode is that audio stream latency is higher than it is in exclusive mode. The following code example shows the syntax for initializing an audio stream in shared mode.

 hResult = pAudioClient->Initialize(
        AUDCLNT_SHAREMODE_SHARED, 
        0,
        0,
        0,
 pWfx,
        &m_SubmixGuid);

Exclusive mode

In contrast, when an application opens a stream in exclusive mode, the application has exclusive access to the audio hardware. In this mode the application can select any audio format that the endpoint supports. The advantage of using exclusive mode is that audio stream latency is lower than it is in shared mode. The disadvantage of using exclusive mode is that you must provide your own APO to handle the supporting functionality of the audio engine. Only a small number of professional level applications require this mode of operation. The following code example shows the syntax for initializing an audio stream in exclusive mode.

 hResult = pAudioClient->Initialize(
            AUDCLNT_SHAREMODE_EXCLUSIVE,
            0,
            0,
            0,  
 pWfxEx,
            &m_SubmixGuid);

After an application initiates audio processing, the graph builder configures the sAPOs into an audio graph and also initializes the sAPOs. The audio service then negotiates with the LFX APO to establish the format for the audio data at the input and output of the APO. For more information, see Format Negotiation.