Documentation Contents |
Chapter 13, "Introduction to the Service Provider
Interfaces," explained that the
javax.sound.sampled.spi
and
javax.sound.midi.spi
packages define abstract classes
to be used by developers of sound services. By implementing a
subclass of one of these abstract classes, a service provider can
create a new service that extends the functionality of the runtime
system. Chapter 14 covered the use of the
javax.sound.sampled.spi
package. The present chapter
discusses how to use the javax.sound.midi.spi
package
to provide new services for handling MIDI devices and files.
Applications programmers who only use existing MIDI services in their programs can safely skip this chapter. For an overview of MIDI and the use of the installed MIDI services in an application program, see Part II, "MIDI," 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 MIDI services.
There are four abstract classes in the
javax.sound.midi.spi
package, which represent four
different types of services that you can provide for the MIDI
system:
MidiFileWriter
provides MIDI file-writing
services. These services make it possible for an application
program to save, to a MIDI file, a MIDI Sequence
that
it has generated or processed. MidiFileReader
provides file-reading services that
return a MIDI Sequence
from a MIDI file for use in an
application program. MidiDeviceProvider
supplies instances of one or
more specific types of MIDI device, possibly including hardware
devices. SoundbankReader
supplies soundbank file-reading
services. Concrete subclasses of SoundbankReader
parse
a given soundbank file, producing a Soundbank
object
that can be loaded into a Synthesizer
.An application program will not directly create an instance of a
service object—whether a provider object, such as a
MidiDeviceProvider
, or an object, such as a
Synthesizer
, that is supplied by the provider object.
Nor will the program directly refer to the SPI classes. Instead,
the application program makes requests to the
MidiSystem
object in the javax.sound.midi
package, and MidiSystem
in turn uses concrete
subclasses of the javax.sound.midi.spi
classes to
process these requests.
There are three standard MIDI file formats, all of which an implementation of the Java Sound API can support: Type 0, Type 1, and Type 2. These file formats differ in their internal representation of the MIDI sequence data in the file, and are appropriate for different kinds of sequences. If an implementation doesn't itself support all three types, a service provider can supply the support for the unimplemented ones. There are also variants of the standard MIDI file formats, some of them proprietary, which similarly could be supported by a third-party vendor.
The ability to write MIDI files is
provided by concrete subclasses of MidiFileWriter
.
This abstract class is directly analogous to
javax.sampled.spi.AudioFileWriter
. Again, the methods
are grouped into query methods for learning what types of files can
be written, and methods for actually writing a file. As with
AudioFileWriter
, two of the query methods are
concrete:
The first of these provides general information about whether the file writer can ever write the specified type of MIDI file type. The second method is more specific: it asks whether a particular Sequence can be written to the specified type of MIDI file. Generally, you don't need to override either of these two concrete methods. In the default implementation, each invokes one of two other corresponding query methods and iterates over the results returned. Being abstract, these other two query methods need to be implemented in the subclass:boolean isFileTypeSupported(int fileType) boolean isFileTypeSupported(int fileType, Sequence sequence)
The first of these returns an array of all the file types that are supported in general. A typical implementation might initialize the array in the file writer's constructor and return the array from this method. From that set of file types, the second method finds the subset to which the file writer can write the given Sequence. In accordance with the MIDI specification, not all types of sequences can be written to all types of MIDI files.abstract int[] getMidiFileTypes() abstract int[] getMidiFileTypes(Sequence sequence)
The write
methods of a
MidiFileWriter
subclass perform the encoding of the
data in a given Sequence
into the correct data format
for the requested type of MIDI file, writing the coded stream to
either a file or an output stream:
To do this, theabstract int write(Sequence in, int fileType, java.io.File out) abstract int write(Sequence in, int fileType, java.io.OutputStream out)
write
method must parse the
Sequence
by iterating over its tracks, construct an
appropriate file header, and write the header and tracks to the
output. The MIDI file's header format is, of course, defined by the
MIDI specification. It includes such information as a "magic
number" identifying this as a MIDI file, the header's length, the
number of tracks, and the sequence's timing information (division
type and resolution). The rest of the MIDI file consists of the
track data, in the format defined by the MIDI specification.
Let's briefly look at how the application
program, MIDI system, and service provider cooperate in writing a
MIDI file. In a typical situation, an application program has a
particular MIDI Sequence
to save to a file. The
program queries the MidiSystem
object to see what MIDI
file formats, if any, are supported for the particular
Sequence
at hand, before attempting to write the file.
The MidiSystem.getMidiFileTypes(Sequence)
method
returns an array of all the MIDI file types to which the system can
write a particular sequence. It does this by invoking the
corresponding getMidiFileTypes
method for each of the
installed MidiFileWriter
services, and collecting and
returning the results in an array of integers that can be thought
of as a master list of all file types compatible with the given
Sequence
. When it comes to writing the
Sequence
to a file, the call to
MidiSystem.write
is passed an integer representing a
file type, along with the Sequence
to be written and
the output file; MidiSystem
uses the supplied type to
decide which installed MidiFileWriter
should handle
the write request, and dispatches a corresponding
write
to the appropriate
MidiFileWriter
.
The MidiFileReader
abstract
class is directly analogous to
javax.sampled.spi.AudioFileReader
class. Both consist
of two overloaded methods, each of which can take a
File
, URL
, or InputStream
argument. The first of the overloaded methods returns the file
format of a specified file. In the case of
MidiFileReader
, the API is:
Concrete subclasses must implement these methods to return a filled-outabstract MidiFileFormat getMidiFileFormat(java.io.File file) abstract MidiFileFormat getMidiFileFormat( java.io.InputStream stream) abstract MidiFileFormat getMidiFileFormat(java.net.URL url)
MidiFileFormat
object describing the format
of the specified MIDI file (or stream or URL), assuming that the
file is of a type supported by the file reader and that it contains
valid header information. Otherwise, an
InvalidMidiDataException
should be thrown.
The other overloaded method returns a MIDI
Sequence
from a given file, stream, or URL :
Theabstract Sequence getSequence(java.io.File file) abstract Sequence getSequence(java.io.InputStream stream) abstract Sequence getSequence(java.net.URL url)
getSequence
method performs the actual work of
parsing the bytes in the MIDI input file and constructing a
corresponding Sequence
object. This is essentially the
inverse of the process used by MidiFileWriter.write
.
Because there is a one-to-one correspondence between the contents
of a MIDI file as defined by the MIDI specification and a
Sequence
object as defined by the Java Sound API, the
details of the parsing are straightforward. If the file passed to
getSequence
contains data that the file reader can't
parse (for example, because the file has been corrupted or doesn't
conform to the MIDI specification), an
InvalidMidiDataException
should be thrown.
A MidiDeviceProvider
can be
considered a factory that supplies one or more particular types of
MIDI device. The class consists of a method that returns an
instance of a MIDI device, as well as query methods to learn what
kinds of devices this provider can supply.
As with the other
javax.sound.midi.spi
services, application developers
get indirect access to a MidiDeviceProvider
service
through a call to MidiSystem
methods, in this case
MidiSystem.getMidiDevice
and
MidiSystem.getMidiDeviceInfo
. The purpose of
subclassing MidiDeviceProvider
is to supply a new kind
of device, so the service developer must also create an
accompanying class for the device being returned—just as we saw
with MixerProvider
in the
javax.sound.sampled.spi
package. There, the returned
device's class implemented the
javax.sound.sampled.Mixer
interface; here it
implements the javax.sound.midi.MidiDevice
interface.
It might also implement a subinterface of MidiDevice
,
such as Synthesizer
or Sequencer
.
Because a single subclass of
MidiDeviceProvider
can provide more than one type of
MidiDevice
, the getDeviceInfo
method of
the class returns an array of MidiDevice.Info
objects
enumerating the different MidiDevices
available:
abstract MidiDevice.Info[] getDeviceInfo()
The returned array can contain a single element, of course. A
typical implementation of the provider might initialize an array in
its constructor and return it here. This allows
MidiSystem
to iterate over all installed
MidiDeviceProviders
to construct a list of all
installed devices. MidiSystem
can then return this
list (MidiDevice.Info[]
array) to an application
program.
MidiDeviceProvider
also
includes a concrete query method:
This method permits the system to query the provider about a specific kind of device. Generally, you don't need to override this convenience method. The default implementation iterates over the array returned by getDeviceInfo and compares the argument to each element.boolean isDeviceSupported(MidiDevice.Info info)
The third and final
MidiDeviceProvider
method returns the requested
device:
This method should first test the argument to make sure it describes a device that this provider can supply. If it doesn't, it should throw anabstract MidiDevice getDevice(MidiDevice.Info info)
IllegalArgumentException
. Otherwise,
it returns the device.
A SoundBank
is a set of
Instruments
that can be loaded into a
Synthesizer
. An Instrument
is an
implementation of a sound-synthesis algorithm that produces a
particular sort of sound, and includes accompanying name and
information strings. A SoundBank
roughly corresponds
to a bank in the MIDI specification, but it's a more extensive and
addressable collection; it can perhaps better be thought of as a
collection of MIDI banks. (For more background information on
SoundBanks
and Synthesizers
, see Chapter
12, "Synthesizing Sound.")
SoundbankReader
consists of a
single overloaded method, which the system invokes to read a
Soundbank
object from a soundbank file:
abstract Soundbank getSoundbank(java.io.File file) abstract Soundbank getSoundbank(java.io.InputStream stream) abstract Soundbank getSoundbank(java.net.URL url)
Concrete subclasses of SoundbankReader
will work in
tandem with particular provider-defined implementations of
SoundBank
, Instrument
, and
Synthesizer
to allow the system to load a
SoundBank
from a file into an instance of a particular
Synthesizer
class. Synthesis techniques may differ
wildly from one Synthesizer
to another, and, as a
consequence, the data stored in an Instrument
or
SoundBank
providing control or specification data for
the synthesis process of a Synthesizer
can take a
variety of forms. One synthesis technique may require only a few
bytes of parameter data; another may be based on extensive sound
samples. The resources present in a SoundBank
will
depend upon the nature of the Synthesizer
into which
they get loaded, and therefore the implementation of the
getSoundbank
method of a SoundbankReader
subclass has access to knowledge of a particular kind of
SoundBank
. In addition, a particular subclass of
SoundbankReader
understands a particular file format
for storing the SoundBank
data. That file format may
be vendor-specific and proprietary.
SoundBank
is just an
interface, with only weak constraints on the contents of a
SoundBank
object. The methods an object must support
to implement this interface (getResources
,
getInstruments
, getVendor
,
getName
, etc.) impose loose requirements on the data
that the object contains. For example, getResources
and getInstruments
can return empty arrays. The actual
contents of a subclassed SoundBank
object, in
particular its instruments and its non-instrument resources, are
defined by the service provider. Thus, the mechanism of parsing a
soundbank file depends entirely on the specification of that
particular kind of soundbank file.
Soundbank files are created outside the Java Sound API, typically by the vendor of the synthesizer that can load that kind of soundbank. Some vendors might supply end-user tools for creating such files.
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