As discussed in Chapter 13, "Introduction to the Service Provider
Interfaces," the Java Sound API includes two packages,
javax.sound.sampled.spi and
javax.sound.midi.spi, that define abstract classes to
be used by developers of sound services. By implementing and
installing a subclass of one of these abstract classes, a service
provider registers the new service, extending the functionality of
the runtime system. The present chapter tells you how to go about
using the javax.sound.sampled.spi package to provide
new services for handling sampled audio.
This chapter can be safely skipped by application programmers who merely wish to use existing audio services in their programs. For the use of the installed audio services in an application program, see Part I, "Sampled Audio," of this Programmer's Guide. This chapter assumes that the reader is familiar with the JavaTM Sound API methods that application programs invoke to access installed audio services.
There are four abstract classes in the
javax.sound.sampled.spi package, representing four
different types of services that you can provide for the
sampled-audio system:
AudioFileWriter provides sound file-writing
services. These services make it possible for an application
program to write a stream of audio data to a file of a particular
type. AudioFileReader provides file-reading services.
These services enable an application program to ascertain a sound
file's characteristics, and to obtain a stream from which the
file's audio data can be read. FormatConversionProvider provides services for
converting audio data formats. These services allow an application
program to translate audio streams from one data format to another.
MixerProvider provides management of a particular
kind of mixer. This mechanism allows an application program to
obtain information about, and access instances of, a given kind of
mixer.
In essence there is a double isolation of
the service instances from the application developer. An
application program never directly creates instances of the service
objects, such as mixers or format converters, that it needs for its
audio processing tasks. Nor does the program even directly request
these objects from the SPI classes that administer them. The
application program makes requests to the AudioSystem
object in the javax.sound.sampled package, and
AudioSystem in turn uses the SPI objects to process
these queries and service requests.
The existence of new audio services might
be completely transparent to both the user and the application
programmer. All application references are through standard objects
of the javax.sound.sampled package, primarily
AudioSystem, and the special handling that new
services might be providing is often completely hidden.
In this chapter, we'll continue the
previous chapter's convention of referring to new SPI subclasses by
names like AcmeMixer and
AcmeMixerProvider.
Let's start with
AudioFileWriter, one of the simpler SPI classes.
A subclass that implements the methods of
AudioFileWriter must provide implementations of a set
of methods to handle queries about the file formats and file types
supported by the class, as well as provide methods that actually
write out a supplied audio data stream to a File or
OutputStream.
AudioFileWriter includes two
methods that have concrete implementations in the base class:
boolean isFileTypeSupported(AudioFileFormat.Type fileType)
boolean isFileTypeSupported(AudioFileFormat.Type fileType,
AudioInputStream stream)
The first of these methods informs the caller whether this file
writer can write sound files of the specified type. This method is
a general inquiry, it will return true if the file
writer can write that kind of file, assuming the file writer is
handed appropriate audio data. However, the ability to write a file
can depend on the format of the specific audio data that's handed
to the file writer. A file writer might not support every audio
data format, or the constraint might be imposed by the file format
itself. (Not all kinds of audio data can be written to all kinds of
sound files.) The second method is more specific, then, asking
whether a particular AudioInputStream can be written
to a particular type of file.
Generally, you won't need to override these two concrete methods. Each is simply a wrapper that invokes one of two other query methods and iterates over the results returned. These other two query methods are abstract and therefore need to be implemented in the subclass:
abstract AudioFileFormat.Type[] getAudioFileTypes()
abstract AudioFileFormat.Type[]
getAudioFileTypes(AudioInputStream stream)
These methods correspond directly to the previous two. Each returns
an array of all the supported file types-all that are supported in
general, in the case of the first method, and all that are
supported for a specific audio stream, in the case of the second
method. A typical implementation of the first method might simply
return an array that the file writer's constructor initializes. An
implementation of the second method might test the stream's
AudioFormat object to see whether it's a data format
that the requested type of file supports.
The final two methods of
AudioFileWriter do the actual file-writing work:
abstract int write(AudioInputStream stream,
AudioFileFormat.Type fileType, java.io.File out)
abstract int write(AudioInputStream stream,
AudioFileFormat.Type fileType, java.io.OutputStream out)
These methods write a stream of bytes representing the audio data
to the stream or file specified by the third argument. The details
of how this is done depend on the structure of the specified type
of file. The write method must write the file's header
and the audio data in the manner prescribed for sound files of this
format (whether it's a standard type of sound file or a new,
possibly proprietary one).
The AudioFileReader class
consists of six abstract methods that your subclass needs to
implement-actually, two different overloaded methods, each of which
can take a File, URL, or
InputStream argument. The first of these overloaded
methods accepts queries about the file format of a specified
file:
abstract AudioFileFormat getAudioFileFormat(
java.io.File file)
abstract AudioFileFormat getAudioFileFormat(
java.io.InputStream stream)
abstract AudioFileFormat getAudioFileFormat(
java.net.URL url)
A typical implementation of getAudioFileFormat method
reads and parses the sound file's header to ascertain its file
format. See the description of the AudioFileFormat class to see
what fields need to be read from the header, and refer to the
specification for the particular file type to figure out how to
parse the header.
Because the caller providing a stream as an argument to this method expects the stream to be unaltered by the method, the file reader should generally start by marking the stream. After reading to the end of the header, it should reset the stream to its original position.
The other overloaded
AudioFileReader method provides file-reading services,
by returning an AudioInputStream from which the file's audio data
can be read:
abstract AudioInputStream getAudioInputStream(
java.io.File file)
abstract AudioInputStream getAudioInputStream(
java.io.InputStream stream)
abstract AudioInputStream getAudioInputStream(
java.net.URL url)
Typically, an implementation of getAudioInputStream
returns an AudioInputStream wound to the beginning of
the file's data chunk (after the header), ready for reading. It
would be conceivable, though, for a file reader to return an
AudioInputStream whose audio format represents a
stream of data that is in some way decoded from what is contained
in the file. The important thing is that the method return a
formatted stream from which the audio data contained in the file
can be read. The AudioFormat encapsulated in the
returned AudioInputStream object will inform the
caller about the stream's data format, which is usually, but not
necessarily, the same as the data format in the file itself.
Generally, the returned stream is an
instance of AudioInputStream; it's unlikely you would
ever need to subclass AudioInputStream.
A FormatConversionProvider
subclass transforms an AudioInputStream that has one
audio data format into one that has another format. The former
(input) stream is referred to as the source stream, and
the latter (output) stream is referred to as the target
stream. Recall from Chapter 2, "Overview of the Sampled Package,"
that an AudioInputStream contains an
AudioFormat, and the AudioFormat in turn
contains a particular type of data encoding, represented by an
AudioFormat.Encoding object. The format and encoding
in the source stream are called the source format and source
encoding, and those in the target stream are likewise called the
target format and target encoding.
The work of conversion is performed in the
overloaded abstract method of FormatConversionProvider
called getAudioInputStream. The class also has
abstract query methods for learning about all the supported target
and source formats and encodings. There are concrete wrapper
methods for querying about a specific conversion.
The two variants of
getAudioInputStream are:
abstract AudioInputStream getAudioInputStream(
AudioFormat.Encoding targetEncoding,
AudioInputStream sourceStream)
and
abstract AudioInputStream getAudioInputStream(
AudioFormat targetFormat,
AudioInputStream sourceStream)
These differ in the first argument, according to whether the caller
is specifying a complete target format or just the format's
encoding.
A typical implementation of
getAudioInputStream works by returning a new subclass
of AudioInputStream that wraps around the original
(source) AudioInputStream and applies a data format
conversion to its data whenever a read method is
invoked. For example, consider the case of a new
FormatConversionProvider subclass called
AcmeCodec, which works with a new
AudioInputStream subclass called
AcmeCodecStream.
The implementation of
AcmeCodec's second getAudioInputStream
method might be:
public AudioInputStream getAudioInputStream
(AudioFormat outputFormat, AudioInputStream stream) {
AudioInputStream cs = null;
AudioFormat inputFormat = stream.getFormat();
if (inputFormat.matches(outputFormat) ) {
cs = stream;
} else {
cs = (AudioInputStream)
(new AcmeCodecStream(stream, outputFormat));
tempBuffer = new byte[tempBufferSize];
}
return cs;
}
The actual format conversion takes place in new read
methods of the returned AcmeCodecStream, a subclass of
AudioInputStream. Again, application programs that
access this returned AcmeCodecStream simply operate on
it as an AudioInputStream, and don't need to know the
details of its implementation.
The other methods of a
FormatConversionProvider all permit queries about the
input and output encodings and formats that the object supports.
The following four methods, being abstract, need to be
implemented:
abstract AudioFormat.Encoding[] getSourceEncodings()
abstract AudioFormat.Encoding[] getTargetEncodings()
abstract AudioFormat.Encoding[] getTargetEncodings(
AudioFormat sourceFormat)
abstract AudioFormat[] getTargetFormats(
AudioFormat.Encoding targetEncoding,
AudioFormat sourceFormat)
As in the query methods of the AudioFileReader
class discussed above, these queries are typically handled by
checking private data of the object and, for the latter two
methods, comparing them against the argument(s).
The remaining four
FormatConversionProvider methods are concrete and
generally don't need to be overridden:
boolean isConversionSupported(
AudioFormat.Encoding targetEncoding,
AudioFormat sourceFormat)
boolean isConversionSupported(AudioFormat targetFormat,
AudioFormat sourceFormat)
boolean isSourceEncodingSupported(
AudioFormat.Encoding sourceEncoding)
boolean isTargetEncodingSupported(
AudioFormat.Encoding targetEncoding)
As with AudioFileWriter.isFileTypeSupported(), the
default implementation of each of these methods is essentially a
wrapper that invokes one of the other query methods and iterates
over the results returned.
As its name implies, a
MixerProvider supplies instances of mixers. Each
concrete MixerProvider subclass acts as a factory for
the Mixer objects used by an application program. Of
course, defining a new MixerProvider only makes sense
if one or more new implementations of the Mixer
interface are also defined. As in the
FormatConversionProvider example above, where our
getAudioInputStream method returned a subclass of
AudioInputStream that performed the conversion, our
new class AcmeMixerProvider has a method
getMixer that returns an instance of another new class
that implements the Mixer interface. We'll call the
latter class AcmeMixer. Particularly if the mixer is
implemented in hardware, the provider might support only one static
instance of the requested device. If so, it should return this
static instance in response to each invocation of
getMixer.
Since AcmeMixer supports the
Mixer interface, application programs don't require
any additional information to access its basic functionality.
However, if AcmeMixer supports functionality not
defined in the Mixer interface, and the vendor wants
to make this extended functionality accessible to application
programs, the mixer should of course be defined as a public class
with additional, well-documented public methods, so that a program
that wishes to make use of this extended functionality can import
AcmeMixer and cast the object returned by
getMixer to this type.
The other two methods of
MixerProvider are:
abstract Mixer.Info[] getMixerInfo()and
boolean isMixerSupported(Mixer.Info info)These methods allow the audio system to determine whether this particular provider class can produce a device that an application program needs. In other words, the
AudioSystem object
can iterate over all the installed MixerProviders to
see which ones, if any, can supply the device that the application
program has requested of the AudioSystem. (See the
discussion under "Getting a
Mixer" in Chapter 3, "Accessing Audio
System Resources.") The getMixerInfo method
returns an array of objects containing information about the kinds
of mixer available from this provider object. The system can pass
these information objects, along with those from other providers,
to an application program.
A single MixerProvider can
provide more than one kind of mixer. When the system invokes the
MixerProvider's getMixerInfo method, it gets a list of
information objects identifying the different kinds of mixer that
this provider supports. The system can then invoke
MixerProvider.getMixer(Mixer.Info) to obtain each
mixer of interest.
Your subclass needs to implement
getMixerInfo, as it's abstract. The
isMixerSupported method is concrete and doesn't
generally need to be overridden. The default implementation simply
compares the provided Mixer.Info to each one in the
array returned by getMixerInfo.
