OSS Sequencer Emulation on ALSA

Copyright (c) 1998,1999 by Takashi Iwai

ver.0.1.8; Nov. 16, 1999

Description

This directory contains the OSS sequencer emulation driver on ALSA. Note that this program is still in the development state.

What this does - it provides the emulation of the OSS sequencer, access via /dev/sequencer and /dev/music devices. The most of applications using OSS can run if the appropriate ALSA sequencer is prepared.

The following features are emulated by this driver:

  • Normal sequencer and MIDI events:

    They are converted to the ALSA sequencer events, and sent to the corresponding port.

  • Timer events:

    The timer is not selectable by ioctl. The control rate is fixed to 100 regardless of HZ. That is, even on Alpha system, a tick is always 1/100 second. The base rate and tempo can be changed in /dev/music.

  • Patch loading:

    It purely depends on the synth drivers whether it’s supported since the patch loading is realized by callback to the synth driver.

  • I/O controls:

    Most of controls are accepted. Some controls are dependent on the synth driver, as well as even on original OSS.

Furthermore, you can find the following advanced features:

  • Better queue mechanism:

    The events are queued before processing them.

  • Multiple applications:

    You can run two or more applications simultaneously (even for OSS sequencer)! However, each MIDI device is exclusive - that is, if a MIDI device is opened once by some application, other applications can’t use it. No such a restriction in synth devices.

  • Real-time event processing:

    The events can be processed in real time without using out of bound ioctl. To switch to real-time mode, send ABSTIME 0 event. The followed events will be processed in real-time without queued. To switch off the real-time mode, send RELTIME 0 event.

  • /proc interface:

    The status of applications and devices can be shown via /proc/asound/seq/oss at any time. In the later version, configuration will be changed via /proc interface, too.

Installation

Run configure script with both sequencer support (--with-sequencer=yes) and OSS emulation (--with-oss=yes) options. A module snd-seq-oss.o will be created. If the synth module of your sound card supports for OSS emulation (so far, only Emu8000 driver), this module will be loaded automatically. Otherwise, you need to load this module manually.

At beginning, this module probes all the MIDI ports which have been already connected to the sequencer. Once after that, the creation and deletion of ports are watched by announcement mechanism of ALSA sequencer.

The available synth and MIDI devices can be found in proc interface. Run cat /proc/asound/seq/oss, and check the devices. For example, if you use an AWE64 card, you’ll see like the following:

OSS sequencer emulation version 0.1.8
ALSA client number 63
ALSA receiver port 0

Number of applications: 0

Number of synth devices: 1
synth 0: [EMU8000]
  type 0x1 : subtype 0x20 : voices 32
  capabilities : ioctl enabled / load_patch enabled

Number of MIDI devices: 3
midi 0: [Emu8000 Port-0] ALSA port 65:0
  capability write / opened none

midi 1: [Emu8000 Port-1] ALSA port 65:1
  capability write / opened none

midi 2: [0: MPU-401 (UART)] ALSA port 64:0
  capability read/write / opened none

Note that the device number may be different from the information of /proc/asound/oss-devices or ones of the original OSS driver. Use the device number listed in /proc/asound/seq/oss to play via OSS sequencer emulation.

Using Synthesizer Devices

Run your favorite program. I’ve tested playmidi-2.4, awemidi-0.4.3, gmod-3.1 and xmp-1.1.5. You can load samples via /dev/sequencer like sfxload, too.

If the lowlevel driver supports multiple access to synth devices (like Emu8000 driver), two or more applications are allowed to run at the same time.

Using MIDI Devices

So far, only MIDI output was tested. MIDI input was not checked at all, but hopefully it will work. Use the device number listed in /proc/asound/seq/oss. Be aware that these numbers are mostly different from the list in /proc/asound/oss-devices.

Module Options

The following module options are available:

maxqlen

specifies the maximum read/write queue length. This queue is private for OSS sequencer, so that it is independent from the queue length of ALSA sequencer. Default value is 1024.

seq_oss_debug

specifies the debug level and accepts zero (= no debug message) or positive integer. Default value is 0.

Queue Mechanism

OSS sequencer emulation uses an ALSA priority queue. The events from /dev/sequencer are processed and put onto the queue specified by module option.

All the events from /dev/sequencer are parsed at beginning. The timing events are also parsed at this moment, so that the events may be processed in real-time. Sending an event ABSTIME 0 switches the operation mode to real-time mode, and sending an event RELTIME 0 switches it off. In the real-time mode, all events are dispatched immediately.

The queued events are dispatched to the corresponding ALSA sequencer ports after scheduled time by ALSA sequencer dispatcher.

If the write-queue is full, the application sleeps until a certain amount (as default one half) becomes empty in blocking mode. The synchronization to write timing was implemented, too.

The input from MIDI devices or echo-back events are stored on read FIFO queue. If application reads /dev/sequencer in blocking mode, the process will be awaked.

Interface to Synthesizer Device

Registration

To register an OSS synthesizer device, use snd_seq_oss_synth_register() function:

int snd_seq_oss_synth_register(char *name, int type, int subtype, int nvoices,
        snd_seq_oss_callback_t *oper, void *private_data)

The arguments name, type, subtype and nvoices are used for making the appropriate synth_info structure for ioctl. The return value is an index number of this device. This index must be remembered for unregister. If registration is failed, -errno will be returned.

To release this device, call snd_seq_oss_synth_unregister() function:

int snd_seq_oss_synth_unregister(int index)

where the index is the index number returned by register function.

Callbacks

OSS synthesizer devices have capability for sample downloading and ioctls like sample reset. In OSS emulation, these special features are realized by using callbacks. The registration argument oper is used to specify these callbacks. The following callback functions must be defined:

snd_seq_oss_callback_t:
 int (*open)(snd_seq_oss_arg_t *p, void *closure);
 int (*close)(snd_seq_oss_arg_t *p);
 int (*ioctl)(snd_seq_oss_arg_t *p, unsigned int cmd, unsigned long arg);
 int (*load_patch)(snd_seq_oss_arg_t *p, int format, const char *buf, int offs, int count);
 int (*reset)(snd_seq_oss_arg_t *p);

Except for open and close callbacks, they are allowed to be NULL.

Each callback function takes the argument type snd_seq_oss_arg_t as the first argument.

struct snd_seq_oss_arg_t {
    int app_index;
    int file_mode;
    int seq_mode;
    snd_seq_addr_t addr;
    void *private_data;
    int event_passing;
};

The first three fields, app_index, file_mode and seq_mode are initialized by OSS sequencer. The app_index is the application index which is unique to each application opening OSS sequencer. The file_mode is bit-flags indicating the file operation mode. See seq_oss.h for its meaning. The seq_mode is sequencer operation mode. In the current version, only SND_OSSSEQ_MODE_SYNTH is used.

The next two fields, addr and private_data, must be filled by the synth driver at open callback. The addr contains the address of ALSA sequencer port which is assigned to this device. If the driver allocates memory for private_data, it must be released in close callback by itself.

The last field, event_passing, indicates how to translate note-on / off events. In PROCESS_EVENTS mode, the note 255 is regarded as velocity change, and key pressure event is passed to the port. In PASS_EVENTS mode, all note on/off events are passed to the port without modified. PROCESS_KEYPRESS mode checks the note above 128 and regards it as key pressure event (mainly for Emu8000 driver).

Open Callback

The open is called at each time this device is opened by an application using OSS sequencer. This must not be NULL. Typically, the open callback does the following procedure:

  1. Allocate private data record.

  2. Create an ALSA sequencer port.

  3. Set the new port address on arg->addr.

  4. Set the private data record pointer on arg->private_data.

Note that the type bit-flags in port_info of this synth port must NOT contain TYPE_MIDI_GENERIC bit. Instead, TYPE_SPECIFIC should be used. Also, CAP_SUBSCRIPTION bit should NOT be included, too. This is necessary to tell it from other normal MIDI devices. If the open procedure succeeded, return zero. Otherwise, return -errno.

Ioctl Callback

The ioctl callback is called when the sequencer receives device-specific ioctls. The following two ioctls should be processed by this callback:

IOCTL_SEQ_RESET_SAMPLES

reset all samples on memory -- return 0

IOCTL_SYNTH_MEMAVL

return the available memory size

FM_4OP_ENABLE

can be ignored usually

The other ioctls are processed inside the sequencer without passing to the lowlevel driver.

Load_Patch Callback

The load_patch callback is used for sample-downloading. This callback must read the data on user-space and transfer to each device. Return 0 if succeeded, and -errno if failed. The format argument is the patch key in patch_info record. The buf is user-space pointer where patch_info record is stored. The offs can be ignored. The count is total data size of this sample data.

Close Callback

The close callback is called when this device is closed by the application. If any private data was allocated in open callback, it must be released in the close callback. The deletion of ALSA port should be done here, too. This callback must not be NULL.

Reset Callback

The reset callback is called when sequencer device is reset or closed by applications. The callback should turn off the sounds on the relevant port immediately, and initialize the status of the port. If this callback is undefined, OSS seq sends a HEARTBEAT event to the port.

Events

Most of the events are processed by sequencer and translated to the adequate ALSA sequencer events, so that each synth device can receive by input_event callback of ALSA sequencer port. The following ALSA events should be implemented by the driver:

ALSA event

Original OSS events

NOTEON

SEQ_NOTEON, MIDI_NOTEON

NOTE

SEQ_NOTEOFF, MIDI_NOTEOFF

KEYPRESS

MIDI_KEY_PRESSURE

CHANPRESS

SEQ_AFTERTOUCH, MIDI_CHN_PRESSURE

PGMCHANGE

SEQ_PGMCHANGE, MIDI_PGM_CHANGE

PITCHBEND

SEQ_CONTROLLER(CTRL_PITCH_BENDER), MIDI_PITCH_BEND

CONTROLLER

MIDI_CTL_CHANGE, SEQ_BALANCE (with CTL_PAN)

CONTROL14

SEQ_CONTROLLER

REGPARAM

SEQ_CONTROLLER(CTRL_PITCH_BENDER_RANGE)

SYSEX

SEQ_SYSEX

The most of these behavior can be realized by MIDI emulation driver included in the Emu8000 lowlevel driver. In the future release, this module will be independent.

Some OSS events (SEQ_PRIVATE and SEQ_VOLUME events) are passed as event type SND_SEQ_OSS_PRIVATE. The OSS sequencer passes these event 8 byte packets without any modification. The lowlevel driver should process these events appropriately.

Interface to MIDI Device

Since the OSS emulation probes the creation and deletion of ALSA MIDI sequencer ports automatically by receiving announcement from ALSA sequencer, the MIDI devices don’t need to be registered explicitly like synth devices. However, the MIDI port_info registered to ALSA sequencer must include a group name SND_SEQ_GROUP_DEVICE and a capability-bit CAP_READ or CAP_WRITE. Also, subscription capabilities, CAP_SUBS_READ or CAP_SUBS_WRITE, must be defined, too. If these conditions are not satisfied, the port is not registered as OSS sequencer MIDI device.

The events via MIDI devices are parsed in OSS sequencer and converted to the corresponding ALSA sequencer events. The input from MIDI sequencer is also converted to MIDI byte events by OSS sequencer. This works just a reverse way of seq_midi module.

Known Problems / TODO’s

  • Patch loading via ALSA instrument layer is not implemented yet.