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[/] [or1k/] [trunk/] [rc203soc/] [sw/] [uClinux/] [drivers/] [sound/] [sequencer.c] - Blame information for rev 1772

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/*
 * sound/sequencer.c
 *
 * The sequencer personality manager.
 */
/*
 * Copyright (C) by Hannu Savolainen 1993-1996
 *
 * USS/Lite for Linux is distributed under the GNU GENERAL PUBLIC LICENSE (GPL)
 * Version 2 (June 1991). See the "COPYING" file distributed with this software
 * for more info.
 */
#include <linux/config.h>
 
 
#define SEQUENCER_C
#include "sound_config.h"
 
#ifdef CONFIG_SEQUENCER
 
#include "midi_ctrl.h"
 
static int      sequencer_ok = 0;
static struct sound_timer_operations *tmr;
static int      tmr_no = -1;    /* Currently selected timer */
static int      pending_timer = -1;     /* For timer change operation */
 
/*
 * Local counts for number of synth and MIDI devices. These are initialized
 * by the sequencer_open.
 */
static int      max_mididev = 0;
static int      max_synthdev = 0;
 
/*
 * The seq_mode gives the operating mode of the sequencer:
 *      1 = level1 (the default)
 *      2 = level2 (extended capabilities)
 */
 
#define SEQ_1   1
#define SEQ_2   2
static int      seq_mode = SEQ_1;
 
static wait_handle *seq_sleeper = NULL;
static volatile struct snd_wait seq_sleep_flag =
{0};
static wait_handle *midi_sleeper = NULL;
static volatile struct snd_wait midi_sleep_flag =
{0};
 
static int      midi_opened[MAX_MIDI_DEV] =
{0};
static int      midi_written[MAX_MIDI_DEV] =
{0};
 
unsigned long   prev_input_time = 0;
int             prev_event_time;
unsigned long   seq_time = 0;
 
#include "tuning.h"
 
#define EV_SZ   8
#define IEV_SZ  8
static unsigned char *queue = NULL;
static unsigned char *iqueue = NULL;
 
static volatile int qhead = 0, qtail = 0, qlen = 0;
static volatile int iqhead = 0, iqtail = 0, iqlen = 0;
static volatile int seq_playing = 0;
static volatile int sequencer_busy = 0;
static int      output_threshold;
static int      pre_event_timeout;
static unsigned synth_open_mask;
 
static int      seq_queue (unsigned char *note, char nonblock);
static void     seq_startplay (void);
static int      seq_sync (void);
static void     seq_reset (void);
static int      pmgr_present[MAX_SYNTH_DEV] =
{0};
 
#if MAX_SYNTH_DEV > 15
#error Too many synthesizer devices enabled.
#endif
 
int
sequencer_read (int dev, struct fileinfo *file, char *buf, int count)
{
  int             c = count, p = 0;
  int             ev_len;
  unsigned long   flags;
 
  dev = dev >> 4;
 
  ev_len = seq_mode == SEQ_1 ? 4 : 8;
 
  if (dev)                      /*
                                 * Patch manager device
                                 */
    return pmgr_read (dev - 1, file, buf, count);
 
  save_flags (flags);
  cli ();
  if (!iqlen)
    {
      if ((file->flags & (O_NONBLOCK) ?
           1 : 0))
        {
          restore_flags (flags);
          return -(EAGAIN);
        }
 
 
      {
        unsigned long   tlimit;
 
        if (pre_event_timeout)
          current_set_timeout (tlimit = jiffies + (pre_event_timeout));
        else
          tlimit = (unsigned long) -1;
        midi_sleep_flag.flags = WK_SLEEP;
        module_interruptible_sleep_on (&midi_sleeper);
        if (!(midi_sleep_flag.flags & WK_WAKEUP))
          {
            if (jiffies >= tlimit)
              midi_sleep_flag.flags |= WK_TIMEOUT;
          }
        midi_sleep_flag.flags &= ~WK_SLEEP;
      };
 
      if (!iqlen)
        {
          restore_flags (flags);
          return 0;
        }
    }
 
  while (iqlen && c >= ev_len)
    {
 
      memcpy_tofs (&(buf)[p], (char *) &iqueue[iqhead * IEV_SZ], ev_len);
      p += ev_len;
      c -= ev_len;
 
      iqhead = (iqhead + 1) % SEQ_MAX_QUEUE;
      iqlen--;
    }
  restore_flags (flags);
 
  return count - c;
}
 
static void
sequencer_midi_output (int dev)
{
  /*
   * Currently NOP
   */
}
 
void
seq_copy_to_input (unsigned char *event_rec, int len)
{
  unsigned long   flags;
 
  /*
     * Verify that the len is valid for the current mode.
   */
 
  if (len != 4 && len != 8)
    return;
  if ((seq_mode == SEQ_1) != (len == 4))
    return;
 
  if (iqlen >= (SEQ_MAX_QUEUE - 1))
    return;                     /* Overflow */
 
  save_flags (flags);
  cli ();
  memcpy (&iqueue[iqtail * IEV_SZ], event_rec, len);
  iqlen++;
  iqtail = (iqtail + 1) % SEQ_MAX_QUEUE;
 
  if ((midi_sleep_flag.flags & WK_SLEEP))
    {
      {
        midi_sleep_flag.flags = WK_WAKEUP;
        module_wake_up (&midi_sleeper);
      };
    }
  restore_flags (flags);
}
 
static void
sequencer_midi_input (int dev, unsigned char data)
{
  unsigned int    tstamp;
  unsigned char   event_rec[4];
 
  if (data == 0xfe)             /* Ignore active sensing */
    return;
 
  tstamp = jiffies - seq_time;
  if (tstamp != prev_input_time)
    {
      tstamp = (tstamp << 8) | SEQ_WAIT;
 
      seq_copy_to_input ((unsigned char *) &tstamp, 4);
      prev_input_time = tstamp;
    }
 
  event_rec[0] = SEQ_MIDIPUTC;
  event_rec[1] = data;
  event_rec[2] = dev;
  event_rec[3] = 0;
 
  seq_copy_to_input (event_rec, 4);
}
 
void
seq_input_event (unsigned char *event_rec, int len)
{
  unsigned long   this_time;
 
  if (seq_mode == SEQ_2)
    this_time = tmr->get_time (tmr_no);
  else
    this_time = jiffies - seq_time;
 
  if (this_time != prev_input_time)
    {
      unsigned char   tmp_event[8];
 
      tmp_event[0] = EV_TIMING;
      tmp_event[1] = TMR_WAIT_ABS;
      tmp_event[2] = 0;
      tmp_event[3] = 0;
      *(unsigned int *) &tmp_event[4] = this_time;
 
      seq_copy_to_input (tmp_event, 8);
      prev_input_time = this_time;
    }
 
  seq_copy_to_input (event_rec, len);
}
 
int
sequencer_write (int dev, struct fileinfo *file, const char *buf, int count)
{
  unsigned char   event_rec[EV_SZ], ev_code;
  int             p = 0, c, ev_size;
  int             err;
  int             mode = file->mode & O_ACCMODE;
 
  dev = dev >> 4;
 
  DEB (printk ("sequencer_write(dev=%d, count=%d)\n", dev, count));
 
  if (mode == OPEN_READ)
    return -(EIO);
 
  if (dev)
    return pmgr_write (dev - 1, file, buf, count);
 
  c = count;
 
  while (c >= 4)
    {
      memcpy_fromfs ((char *) event_rec, &(buf)[p], 4);
      ev_code = event_rec[0];
 
      if (ev_code == SEQ_FULLSIZE)
        {
          int             err;
 
          dev = *(unsigned short *) &event_rec[2];
          if (dev < 0 || dev >= max_synthdev)
            return -(ENXIO);
 
          if (!(synth_open_mask & (1 << dev)))
            return -(ENXIO);
 
          err = synth_devs[dev]->load_patch (dev, *(short *) &event_rec[0], buf, p + 4, c, 0);
          if (err < 0)
            return err;
 
          return err;
        }
 
      if (ev_code >= 128)
        {
          if (seq_mode == SEQ_2 && ev_code == SEQ_EXTENDED)
            {
              printk ("Sequencer: Invalid level 2 event %x\n", ev_code);
              return -(EINVAL);
            }
 
          ev_size = 8;
 
          if (c < ev_size)
            {
              if (!seq_playing)
                seq_startplay ();
              return count - c;
            }
 
          memcpy_fromfs ((char *) &event_rec[4], &(buf)[p + 4], 4);
 
        }
      else
        {
          if (seq_mode == SEQ_2)
            {
              printk ("Sequencer: 4 byte event in level 2 mode\n");
              return -(EINVAL);
            }
          ev_size = 4;
        }
 
      if (event_rec[0] == SEQ_MIDIPUTC)
        {
 
          if (!midi_opened[event_rec[2]])
            {
              int             mode;
              int             dev = event_rec[2];
 
              if (dev >= max_mididev)
                {
                  printk ("Sequencer Error: Nonexistent MIDI device %d\n", dev);
                  return -(ENXIO);
                }
 
              mode = file->mode & O_ACCMODE;
 
              if ((err = midi_devs[dev]->open (dev, mode,
                          sequencer_midi_input, sequencer_midi_output)) < 0)
                {
                  seq_reset ();
                  printk ("Sequencer Error: Unable to open Midi #%d\n", dev);
                  return err;
                }
 
              midi_opened[dev] = 1;
            }
 
        }
 
      if (!seq_queue (event_rec, (file->flags & (O_NONBLOCK) ?
                                  1 : 0)))
        {
          int             processed = count - c;
 
          if (!seq_playing)
            seq_startplay ();
 
          if (!processed && (file->flags & (O_NONBLOCK) ?
                             1 : 0))
            return -(EAGAIN);
          else
            return processed;
        }
 
      p += ev_size;
      c -= ev_size;
    }
 
  if (!seq_playing)
    seq_startplay ();
 
  return count;                 /* This will "eat" chunks shorter than 4 bytes (if written
                                   * alone) Should we really do that ?
                                 */
}
 
static int
seq_queue (unsigned char *note, char nonblock)
{
 
  /*
   * Test if there is space in the queue
   */
 
  if (qlen >= SEQ_MAX_QUEUE)
    if (!seq_playing)
      seq_startplay ();         /*
                                 * Give chance to drain the queue
                                 */
 
  if (!nonblock && qlen >= SEQ_MAX_QUEUE && !(seq_sleep_flag.flags & WK_SLEEP))
    {
      /*
       * Sleep until there is enough space on the queue
       */
 
      seq_sleep_flag.flags = WK_SLEEP;
      module_interruptible_sleep_on (&seq_sleeper);
      seq_sleep_flag.flags &= ~WK_SLEEP;;
    }
 
  if (qlen >= SEQ_MAX_QUEUE)
    {
      return 0;                  /*
                                 * To be sure
                                 */
    }
  memcpy (&queue[qtail * EV_SZ], note, EV_SZ);
 
  qtail = (qtail + 1) % SEQ_MAX_QUEUE;
  qlen++;
 
  return 1;
}
 
static int
extended_event (unsigned char *q)
{
  int             dev = q[2];
 
  if (dev < 0 || dev >= max_synthdev)
    return -(ENXIO);
 
  if (!(synth_open_mask & (1 << dev)))
    return -(ENXIO);
 
  switch (q[1])
    {
    case SEQ_NOTEOFF:
      synth_devs[dev]->kill_note (dev, q[3], q[4], q[5]);
      break;
 
    case SEQ_NOTEON:
      if (q[4] > 127 && q[4] != 255)
        return 0;
 
      synth_devs[dev]->start_note (dev, q[3], q[4], q[5]);
      break;
 
    case SEQ_PGMCHANGE:
      synth_devs[dev]->set_instr (dev, q[3], q[4]);
      break;
 
    case SEQ_AFTERTOUCH:
      synth_devs[dev]->aftertouch (dev, q[3], q[4]);
      break;
 
    case SEQ_BALANCE:
      synth_devs[dev]->panning (dev, q[3], (char) q[4]);
      break;
 
    case SEQ_CONTROLLER:
      synth_devs[dev]->controller (dev, q[3], q[4], (short) (q[5] | (q[6] << 8)));
      break;
 
    case SEQ_VOLMODE:
      if (synth_devs[dev]->volume_method != NULL)
        synth_devs[dev]->volume_method (dev, q[3]);
      break;
 
    default:
      return -(EINVAL);
    }
 
  return 0;
}
 
static int
find_voice (int dev, int chn, int note)
{
  unsigned short  key;
  int             i;
 
  key = (chn << 8) | (note + 1);
 
  for (i = 0; i < synth_devs[dev]->alloc.max_voice; i++)
    if (synth_devs[dev]->alloc.map[i] == key)
      return i;
 
  return -1;
}
 
static int
alloc_voice (int dev, int chn, int note)
{
  unsigned short  key;
  int             voice;
 
  key = (chn << 8) | (note + 1);
 
  voice = synth_devs[dev]->alloc_voice (dev, chn, note,
                                        &synth_devs[dev]->alloc);
  synth_devs[dev]->alloc.map[voice] = key;
  synth_devs[dev]->alloc.alloc_times[voice] =
    synth_devs[dev]->alloc.timestamp++;
  return voice;
}
 
static void
seq_chn_voice_event (unsigned char *event_rec)
{
  unsigned char   dev = event_rec[1];
  unsigned char   cmd = event_rec[2];
  unsigned char   chn = event_rec[3];
  unsigned char   note = event_rec[4];
  unsigned char   parm = event_rec[5];
  int             voice = -1;
 
  if ((int) dev > max_synthdev)
    return;
  if (!(synth_open_mask & (1 << dev)))
    return;
  if (!synth_devs[dev])
    return;
 
  if (seq_mode == SEQ_2)
    {
      if (synth_devs[dev]->alloc_voice)
        voice = find_voice (dev, chn, note);
 
      if (cmd == MIDI_NOTEON && parm == 0)
        {
          cmd = MIDI_NOTEOFF;
          parm = 64;
        }
    }
 
  switch (cmd)
    {
    case MIDI_NOTEON:
      if (note > 127 && note != 255)    /* Not a seq2 feature */
        return;
 
      if (voice == -1 && seq_mode == SEQ_2 && synth_devs[dev]->alloc_voice)
        {                       /* Internal synthesizer (FM, GUS, etc) */
          voice = alloc_voice (dev, chn, note);
        }
 
      if (voice == -1)
        voice = chn;
 
      if (seq_mode == SEQ_2 && (int) dev < num_synths)
        {
          /*
             * The MIDI channel 10 is a percussive channel. Use the note
             * number to select the proper patch (128 to 255) to play.
           */
 
          if (chn == 9)
            {
              synth_devs[dev]->set_instr (dev, voice, 128 + note);
              synth_devs[dev]->chn_info[chn].pgm_num = 128 + note;
              note = 60;        /* Middle C */
 
            }
        }
 
      if (seq_mode == SEQ_2)
        {
          synth_devs[dev]->setup_voice (dev, voice, chn);
        }
 
      synth_devs[dev]->start_note (dev, voice, note, parm);
      break;
 
    case MIDI_NOTEOFF:
      if (voice == -1)
        voice = chn;
      synth_devs[dev]->kill_note (dev, voice, note, parm);
      break;
 
    case MIDI_KEY_PRESSURE:
      if (voice == -1)
        voice = chn;
      synth_devs[dev]->aftertouch (dev, voice, parm);
      break;
 
    default:;
    }
}
 
static void
seq_chn_common_event (unsigned char *event_rec)
{
  unsigned char   dev = event_rec[1];
  unsigned char   cmd = event_rec[2];
  unsigned char   chn = event_rec[3];
  unsigned char   p1 = event_rec[4];
 
  /* unsigned char   p2 = event_rec[5]; */
  unsigned short  w14 = *(short *) &event_rec[6];
 
  if ((int) dev > max_synthdev)
    return;
  if (!(synth_open_mask & (1 << dev)))
    return;
  if (!synth_devs[dev])
    return;
 
  switch (cmd)
    {
    case MIDI_PGM_CHANGE:
      if (seq_mode == SEQ_2)
        {
          synth_devs[dev]->chn_info[chn].pgm_num = p1;
          if ((int) dev >= num_synths)
            synth_devs[dev]->set_instr (dev, chn, p1);
        }
      else
        synth_devs[dev]->set_instr (dev, chn, p1);
 
      break;
 
    case MIDI_CTL_CHANGE:
      if (seq_mode == SEQ_2)
        {
          if (chn > 15 || p1 > 127)
            break;
 
          synth_devs[dev]->chn_info[chn].controllers[p1] = w14 & 0x7f;
 
          if (p1 < 32)          /* Setting MSB should clear LSB to 0 */
            synth_devs[dev]->chn_info[chn].controllers[p1 + 32] = 0;
 
          if ((int) dev < num_synths)
            {
              int             val = w14 & 0x7f;
              int             i, key;
 
              if (p1 < 64)      /* Combine MSB and LSB */
                {
                  val = ((synth_devs[dev]->
                          chn_info[chn].controllers[p1 & ~32] & 0x7f) << 7)
                    | (synth_devs[dev]->
                       chn_info[chn].controllers[p1 | 32] & 0x7f);
                  p1 &= ~32;
                }
 
              /* Handle all playing notes on this channel */
 
              key = ((int) chn << 8);
 
              for (i = 0; i < synth_devs[dev]->alloc.max_voice; i++)
                if ((synth_devs[dev]->alloc.map[i] & 0xff00) == key)
                  synth_devs[dev]->controller (dev, i, p1, val);
            }
          else
            synth_devs[dev]->controller (dev, chn, p1, w14);
        }
      else                      /* Mode 1 */
        synth_devs[dev]->controller (dev, chn, p1, w14);
      break;
 
    case MIDI_PITCH_BEND:
      if (seq_mode == SEQ_2)
        {
          synth_devs[dev]->chn_info[chn].bender_value = w14;
 
          if ((int) dev < num_synths)
            {                   /* Handle all playing notes on this channel */
              int             i, key;
 
              key = (chn << 8);
 
              for (i = 0; i < synth_devs[dev]->alloc.max_voice; i++)
                if ((synth_devs[dev]->alloc.map[i] & 0xff00) == key)
                  synth_devs[dev]->bender (dev, i, w14);
            }
          else
            synth_devs[dev]->bender (dev, chn, w14);
        }
      else                      /* MODE 1 */
        synth_devs[dev]->bender (dev, chn, w14);
      break;
 
    default:;
    }
}
 
static int
seq_timing_event (unsigned char *event_rec)
{
  unsigned char   cmd = event_rec[1];
  unsigned int    parm = *(int *) &event_rec[4];
 
  if (seq_mode == SEQ_2)
    {
      int             ret;
 
      if ((ret = tmr->event (tmr_no, event_rec)) == TIMER_ARMED)
        {
          if ((SEQ_MAX_QUEUE - qlen) >= output_threshold)
            {
              unsigned long   flags;
 
              save_flags (flags);
              cli ();
              if ((seq_sleep_flag.flags & WK_SLEEP))
                {
                  {
                    seq_sleep_flag.flags = WK_WAKEUP;
                    module_wake_up (&seq_sleeper);
                  };
                }
              restore_flags (flags);
            }
        }
      return ret;
    }
 
  switch (cmd)
    {
    case TMR_WAIT_REL:
      parm += prev_event_time;
 
      /*
         * NOTE!  No break here. Execution of TMR_WAIT_REL continues in the
         * next case (TMR_WAIT_ABS)
       */
 
    case TMR_WAIT_ABS:
      if (parm > 0)
        {
          long            time;
 
          seq_playing = 1;
          time = parm;
          prev_event_time = time;
 
          request_sound_timer (time);
 
          if ((SEQ_MAX_QUEUE - qlen) >= output_threshold)
            {
              unsigned long   flags;
 
              save_flags (flags);
              cli ();
              if ((seq_sleep_flag.flags & WK_SLEEP))
                {
                  {
                    seq_sleep_flag.flags = WK_WAKEUP;
                    module_wake_up (&seq_sleeper);
                  };
                }
              restore_flags (flags);
            }
 
          return TIMER_ARMED;
        }
      break;
 
    case TMR_START:
      seq_time = jiffies;
      prev_input_time = 0;
      prev_event_time = 0;
      break;
 
    case TMR_STOP:
      break;
 
    case TMR_CONTINUE:
      break;
 
    case TMR_TEMPO:
      break;
 
    case TMR_ECHO:
      if (seq_mode == SEQ_2)
        seq_copy_to_input (event_rec, 8);
      else
        {
          parm = (parm << 8 | SEQ_ECHO);
          seq_copy_to_input ((unsigned char *) &parm, 4);
        }
      break;
 
    default:;
    }
 
  return TIMER_NOT_ARMED;
}
 
static void
seq_local_event (unsigned char *event_rec)
{
  unsigned char   cmd = event_rec[1];
  unsigned int    parm = *((unsigned int *) &event_rec[4]);
 
  switch (cmd)
    {
    case LOCL_STARTAUDIO:
#ifdef CONFIG_AUDIO
      DMAbuf_start_devices (parm);
#endif
      break;
 
    default:;
    }
}
 
static void
seq_sysex_message (unsigned char *event_rec)
{
  int             dev = event_rec[1];
  int             i, l = 0;
  unsigned char  *buf = &event_rec[2];
 
  if ((int) dev > max_synthdev)
    return;
  if (!(synth_open_mask & (1 << dev)))
    return;
  if (!synth_devs[dev])
    return;
  if (!synth_devs[dev]->send_sysex)
    return;
 
  l = 0;
  for (i = 0; i < 6 && buf[i] != 0xff; i++)
    l = i + 1;
 
  if (l > 0)
    synth_devs[dev]->send_sysex (dev, buf, l);
}
 
static int
play_event (unsigned char *q)
{
  /*
     * NOTE! This routine returns
     *   0 = normal event played.
     *   1 = Timer armed. Suspend playback until timer callback.
     *   2 = MIDI output buffer full. Restore queue and suspend until timer
   */
  unsigned int   *delay;
 
  switch (q[0])
    {
    case SEQ_NOTEOFF:
      if (synth_open_mask & (1 << 0))
        if (synth_devs[0])
          synth_devs[0]->kill_note (0, q[1], 255, q[3]);
      break;
 
    case SEQ_NOTEON:
      if (q[4] < 128 || q[4] == 255)
        if (synth_open_mask & (1 << 0))
          if (synth_devs[0])
            synth_devs[0]->start_note (0, q[1], q[2], q[3]);
      break;
 
    case SEQ_WAIT:
      delay = (unsigned int *) q;       /*
                                         * Bytes 1 to 3 are containing the *
                                         * delay in 'ticks'
                                         */
      *delay = (*delay >> 8) & 0xffffff;
 
      if (*delay > 0)
        {
          long            time;
 
          seq_playing = 1;
          time = *delay;
          prev_event_time = time;
 
          request_sound_timer (time);
 
          if ((SEQ_MAX_QUEUE - qlen) >= output_threshold)
            {
              unsigned long   flags;
 
              save_flags (flags);
              cli ();
              if ((seq_sleep_flag.flags & WK_SLEEP))
                {
                  {
                    seq_sleep_flag.flags = WK_WAKEUP;
                    module_wake_up (&seq_sleeper);
                  };
                }
              restore_flags (flags);
            }
          /*
             * The timer is now active and will reinvoke this function
             * after the timer expires. Return to the caller now.
           */
          return 1;
        }
      break;
 
    case SEQ_PGMCHANGE:
      if (synth_open_mask & (1 << 0))
        if (synth_devs[0])
          synth_devs[0]->set_instr (0, q[1], q[2]);
      break;
 
    case SEQ_SYNCTIMER: /*
                                   * Reset timer
                                 */
      seq_time = jiffies;
      prev_input_time = 0;
      prev_event_time = 0;
      break;
 
    case SEQ_MIDIPUTC:          /*
                                 * Put a midi character
                                 */
      if (midi_opened[q[2]])
        {
          int             dev;
 
          dev = q[2];
 
          if (dev < 0 || dev >= num_midis)
            break;
 
          if (!midi_devs[dev]->putc (dev, q[1]))
            {
              /*
                 * Output FIFO is full. Wait one timer cycle and try again.
               */
 
              seq_playing = 1;
              request_sound_timer (-1);
              return 2;
            }
          else
            midi_written[dev] = 1;
        }
      break;
 
    case SEQ_ECHO:
      seq_copy_to_input (q, 4); /*
                                 * Echo back to the process
                                 */
      break;
 
    case SEQ_PRIVATE:
      if ((int) q[1] < max_synthdev)
        synth_devs[q[1]]->hw_control (q[1], q);
      break;
 
    case SEQ_EXTENDED:
      extended_event (q);
      break;
 
    case EV_CHN_VOICE:
      seq_chn_voice_event (q);
      break;
 
    case EV_CHN_COMMON:
      seq_chn_common_event (q);
      break;
 
    case EV_TIMING:
      if (seq_timing_event (q) == TIMER_ARMED)
        {
          return 1;
        }
      break;
 
    case EV_SEQ_LOCAL:
      seq_local_event (q);
      break;
 
    case EV_SYSEX:
      seq_sysex_message (q);
      break;
 
    default:;
    }
 
  return 0;
}
 
static void
seq_startplay (void)
{
  unsigned long   flags;
  int             this_one, action;
 
  while (qlen > 0)
    {
 
      save_flags (flags);
      cli ();
      qhead = ((this_one = qhead) + 1) % SEQ_MAX_QUEUE;
      qlen--;
      restore_flags (flags);
 
      seq_playing = 1;
 
      if ((action = play_event (&queue[this_one * EV_SZ])))
        {                       /* Suspend playback. Next timer routine invokes this routine again */
          if (action == 2)
            {
              qlen++;
              qhead = this_one;
            }
          return;
        }
 
    }
 
  seq_playing = 0;
 
  if ((SEQ_MAX_QUEUE - qlen) >= output_threshold)
    {
      unsigned long   flags;
 
      save_flags (flags);
      cli ();
      if ((seq_sleep_flag.flags & WK_SLEEP))
        {
          {
            seq_sleep_flag.flags = WK_WAKEUP;
            module_wake_up (&seq_sleeper);
          };
        }
      restore_flags (flags);
    }
}
 
static void
reset_controllers (int dev, unsigned char *controller, int update_dev)
{
 
  int             i;
 
  for (i = 0; i < 128; i++)
    controller[i] = ctrl_def_values[i];
}
 
static void
setup_mode2 (void)
{
  int             dev;
 
  max_synthdev = num_synths;
 
  for (dev = 0; dev < num_midis; dev++)
    if (midi_devs[dev]->converter != NULL)
      {
        synth_devs[max_synthdev++] =
          midi_devs[dev]->converter;
      }
 
  for (dev = 0; dev < max_synthdev; dev++)
    {
      int             chn;
 
      for (chn = 0; chn < 16; chn++)
        {
          synth_devs[dev]->chn_info[chn].pgm_num = 0;
          reset_controllers (dev,
                             synth_devs[dev]->chn_info[chn].controllers,
                             0);
          synth_devs[dev]->chn_info[chn].bender_value = (1 << 7);       /* Neutral */
        }
    }
 
  max_mididev = 0;
  seq_mode = SEQ_2;
}
 
int
sequencer_open (int dev, struct fileinfo *file)
{
  int             retval, mode, i;
  int             level, tmp;
  unsigned long   flags;
 
  level = ((dev & 0x0f) == SND_DEV_SEQ2) ? 2 : 1;
 
  dev = dev >> 4;
  mode = file->mode & O_ACCMODE;
 
  DEB (printk ("sequencer_open(dev=%d)\n", dev));
 
  if (!sequencer_ok)
    {
      printk ("Soundcard: Sequencer not initialized\n");
      return -(ENXIO);
    }
 
  if (dev)                      /* Patch manager device */
    {
      printk ("Patch manager interface is currently broken. Sorry\n");
      return -(ENXIO);
    }
 
  save_flags (flags);
  cli ();
  if (sequencer_busy)
    {
      printk ("Sequencer busy\n");
      restore_flags (flags);
      return -(EBUSY);
    }
  sequencer_busy = 1;
  restore_flags (flags);
 
  max_mididev = num_midis;
  max_synthdev = num_synths;
  pre_event_timeout = 0;
  seq_mode = SEQ_1;
 
  if (pending_timer != -1)
    {
      tmr_no = pending_timer;
      pending_timer = -1;
    }
 
  if (tmr_no == -1)             /* Not selected yet */
    {
      int             i, best;
 
      best = -1;
      for (i = 0; i < num_sound_timers; i++)
        if (sound_timer_devs[i]->priority > best)
          {
            tmr_no = i;
            best = sound_timer_devs[i]->priority;
          }
 
      if (tmr_no == -1)         /* Should not be */
        tmr_no = 0;
    }
 
  tmr = sound_timer_devs[tmr_no];
 
  if (level == 2)
    {
      if (tmr == NULL)
        {
          printk ("sequencer: No timer for level 2\n");
          sequencer_busy = 0;
          return -(ENXIO);
        }
      setup_mode2 ();
    }
 
  if (seq_mode == SEQ_1 && (mode == OPEN_READ || mode == OPEN_READWRITE))
    if (!max_mididev)
      {
        printk ("Sequencer: No Midi devices. Input not possible\n");
        sequencer_busy = 0;
        return -(ENXIO);
      }
 
  if (!max_synthdev && !max_mididev)
    {
      sequencer_busy = 0;
      return -(ENXIO);
    }
 
  synth_open_mask = 0;
 
  for (i = 0; i < max_mididev; i++)
    {
      midi_opened[i] = 0;
      midi_written[i] = 0;
    }
 
  /*
   * if (mode == OPEN_WRITE || mode == OPEN_READWRITE)
   */
  for (i = 0; i < max_synthdev; i++)     /*
                                         * Open synth devices
                                         */
    if ((tmp = synth_devs[i]->open (i, mode)) < 0)
      {
        printk ("Sequencer: Warning! Cannot open synth device #%d (%d)\n", i, tmp);
        if (synth_devs[i]->midi_dev)
          printk ("(Maps to MIDI dev #%d)\n", synth_devs[i]->midi_dev);
      }
    else
      {
        synth_open_mask |= (1 << i);
        if (synth_devs[i]->midi_dev)    /*
                                         * Is a midi interface
                                         */
          midi_opened[synth_devs[i]->midi_dev] = 1;
      }
 
  seq_time = jiffies;
  prev_input_time = 0;
  prev_event_time = 0;
 
  if (seq_mode == SEQ_1 && (mode == OPEN_READ || mode == OPEN_READWRITE))
    {                           /*
                                 * Initialize midi input devices
                                 */
      for (i = 0; i < max_mididev; i++)
        if (!midi_opened[i])
          {
            if ((retval = midi_devs[i]->open (i, mode,
                         sequencer_midi_input, sequencer_midi_output)) >= 0)
              midi_opened[i] = 1;
          }
    }
 
  if (seq_mode == SEQ_2)
    {
      tmr->open (tmr_no, seq_mode);
    }
 
  seq_sleep_flag.flags = WK_NONE;
  midi_sleep_flag.flags = WK_NONE;
  output_threshold = SEQ_MAX_QUEUE / 2;
 
  for (i = 0; i < num_synths; i++)
    if (pmgr_present[i])
      pmgr_inform (i, PM_E_OPENED, 0, 0, 0, 0);
 
  return 0;
}
 
void
seq_drain_midi_queues (void)
{
  int             i, n;
 
  /*
   * Give the Midi drivers time to drain their output queues
   */
 
  n = 1;
 
  while (!current_got_fatal_signal () && n)
    {
      n = 0;
 
      for (i = 0; i < max_mididev; i++)
        if (midi_opened[i] && midi_written[i])
          if (midi_devs[i]->buffer_status != NULL)
            if (midi_devs[i]->buffer_status (i))
              n++;
 
      /*
       * Let's have a delay
       */
      if (n)
        {
 
          {
            unsigned long   tlimit;
 
            if (HZ / 10)
              current_set_timeout (tlimit = jiffies + (HZ / 10));
            else
              tlimit = (unsigned long) -1;
            seq_sleep_flag.flags = WK_SLEEP;
            module_interruptible_sleep_on (&seq_sleeper);
            if (!(seq_sleep_flag.flags & WK_WAKEUP))
              {
                if (jiffies >= tlimit)
                  seq_sleep_flag.flags |= WK_TIMEOUT;
              }
            seq_sleep_flag.flags &= ~WK_SLEEP;
          };
        }
    }
}
 
void
sequencer_release (int dev, struct fileinfo *file)
{
  int             i;
  int             mode = file->mode & O_ACCMODE;
 
  dev = dev >> 4;
 
  DEB (printk ("sequencer_release(dev=%d)\n", dev));
 
  if (dev)                      /*
                                 * Patch manager device
                                 */
    {
      dev--;
      pmgr_release (dev);
      pmgr_present[dev] = 0;
      return;
    }
 
  /*
   * * Wait until the queue is empty (if we don't have nonblock)
   */
 
  if (mode != OPEN_READ && !(file->flags & (O_NONBLOCK) ?
                             1 : 0))
    while (!current_got_fatal_signal () && qlen)
      {
        seq_sync ();
      }
 
  if (mode != OPEN_READ)
    seq_drain_midi_queues ();   /*
                                 * Ensure the output queues are empty
                                 */
  seq_reset ();
  if (mode != OPEN_READ)
    seq_drain_midi_queues ();   /*
                                 * Flush the all notes off messages
                                 */
 
  for (i = 0; i < max_synthdev; i++)
    if (synth_open_mask & (1 << i))     /*
                                         * Actually opened
                                         */
      if (synth_devs[i])
        {
          synth_devs[i]->close (i);
 
          if (synth_devs[i]->midi_dev)
            midi_opened[synth_devs[i]->midi_dev] = 0;
        }
 
  for (i = 0; i < num_synths; i++)
    if (pmgr_present[i])
      pmgr_inform (i, PM_E_CLOSED, 0, 0, 0, 0);
 
  for (i = 0; i < max_mididev; i++)
    if (midi_opened[i])
      midi_devs[i]->close (i);
 
  if (seq_mode == SEQ_2)
    tmr->close (tmr_no);
 
  sequencer_busy = 0;
}
 
static int
seq_sync (void)
{
  unsigned long   flags;
 
  if (qlen && !seq_playing && !current_got_fatal_signal ())
    seq_startplay ();
 
  save_flags (flags);
  cli ();
  if (qlen && !(seq_sleep_flag.flags & WK_SLEEP))
    {
 
      {
        unsigned long   tlimit;
 
        if (HZ)
          current_set_timeout (tlimit = jiffies + (HZ));
        else
          tlimit = (unsigned long) -1;
        seq_sleep_flag.flags = WK_SLEEP;
        module_interruptible_sleep_on (&seq_sleeper);
        if (!(seq_sleep_flag.flags & WK_WAKEUP))
          {
            if (jiffies >= tlimit)
              seq_sleep_flag.flags |= WK_TIMEOUT;
          }
        seq_sleep_flag.flags &= ~WK_SLEEP;
      };
    }
  restore_flags (flags);
 
  return qlen;
}
 
static void
midi_outc (int dev, unsigned char data)
{
  /*
   * NOTE! Calls sleep(). Don't call this from interrupt.
   */
 
  int             n;
  unsigned long   flags;
 
  /*
   * This routine sends one byte to the Midi channel.
   * If the output FIFO is full, it waits until there
   * is space in the queue
   */
 
  n = 3 * HZ;                   /* Timeout */
 
  save_flags (flags);
  cli ();
  while (n && !midi_devs[dev]->putc (dev, data))
    {
 
      {
        unsigned long   tlimit;
 
        if (4)
          current_set_timeout (tlimit = jiffies + (4));
        else
          tlimit = (unsigned long) -1;
        seq_sleep_flag.flags = WK_SLEEP;
        module_interruptible_sleep_on (&seq_sleeper);
        if (!(seq_sleep_flag.flags & WK_WAKEUP))
          {
            if (jiffies >= tlimit)
              seq_sleep_flag.flags |= WK_TIMEOUT;
          }
        seq_sleep_flag.flags &= ~WK_SLEEP;
      };
      n--;
    }
  restore_flags (flags);
}
 
static void
seq_reset (void)
{
  /*
   * NOTE! Calls sleep(). Don't call this from interrupt.
   */
 
  int             i;
  int             chn;
  unsigned long   flags;
 
  sound_stop_timer ();
  seq_time = jiffies;
  prev_input_time = 0;
  prev_event_time = 0;
 
  qlen = qhead = qtail = 0;
  iqlen = iqhead = iqtail = 0;
 
  for (i = 0; i < max_synthdev; i++)
    if (synth_open_mask & (1 << i))
      if (synth_devs[i])
        synth_devs[i]->reset (i);
 
  if (seq_mode == SEQ_2)
    {
 
      for (chn = 0; chn < 16; chn++)
        for (i = 0; i < max_synthdev; i++)
          if (synth_open_mask & (1 << i))
            if (synth_devs[i])
              {
                synth_devs[i]->controller (i, chn, 123, 0);      /* All notes off */
                synth_devs[i]->controller (i, chn, 121, 0);      /* Reset all ctl */
                synth_devs[i]->bender (i, chn, 1 << 13);        /* Bender off */
              }
 
    }
  else
    /* seq_mode == SEQ_1 */
    {
      for (i = 0; i < max_mididev; i++)
        if (midi_written[i])    /*
                                 * Midi used. Some notes may still be playing
                                 */
          {
            /*
               *      Sending just a ACTIVE SENSING message should be enough to stop all
               *      playing notes. Since there are devices not recognizing the
               *      active sensing, we have to send some all notes off messages also.
             */
            midi_outc (i, 0xfe);
 
            for (chn = 0; chn < 16; chn++)
              {
                midi_outc (i,
                           (unsigned char) (0xb0 + (chn & 0x0f)));      /* control change */
                midi_outc (i, 0x7b);    /* All notes off */
                midi_outc (i, 0);        /* Dummy parameter */
              }
 
            midi_devs[i]->close (i);
 
            midi_written[i] = 0;
            midi_opened[i] = 0;
          }
    }
 
  seq_playing = 0;
 
  save_flags (flags);
  cli ();
  if ((seq_sleep_flag.flags & WK_SLEEP))
    {
      /*      printk ("Sequencer Warning: Unexpected sleeping process - Waking up\n"); */
      {
        seq_sleep_flag.flags = WK_WAKEUP;
        module_wake_up (&seq_sleeper);
      };
    }
  restore_flags (flags);
 
}
 
static void
seq_panic (void)
{
  /*
     * This routine is called by the application in case the user
     * wants to reset the system to the default state.
   */
 
  seq_reset ();
 
  /*
     * Since some of the devices don't recognize the active sensing and
     * all notes off messages, we have to shut all notes manually.
     *
     *      TO BE IMPLEMENTED LATER
   */
 
  /*
     * Also return the controllers to their default states
   */
}
 
int
sequencer_ioctl (int dev, struct fileinfo *file,
                 unsigned int cmd, caddr_t arg)
{
  int             midi_dev, orig_dev;
  int             mode = file->mode & O_ACCMODE;
 
  orig_dev = dev = dev >> 4;
 
  switch (cmd)
    {
    case SNDCTL_TMR_TIMEBASE:
    case SNDCTL_TMR_TEMPO:
    case SNDCTL_TMR_START:
    case SNDCTL_TMR_STOP:
    case SNDCTL_TMR_CONTINUE:
    case SNDCTL_TMR_METRONOME:
    case SNDCTL_TMR_SOURCE:
      if (dev)                  /* Patch manager */
        return -(EIO);
 
      if (seq_mode != SEQ_2)
        return -(EINVAL);
      return tmr->ioctl (tmr_no, cmd, arg);
      break;
 
    case SNDCTL_TMR_SELECT:
      if (dev)                  /* Patch manager */
        return -(EIO);
 
      if (seq_mode != SEQ_2)
        return -(EINVAL);
      pending_timer = get_user ((int *) arg);
 
      if (pending_timer < 0 || pending_timer >= num_sound_timers)
        {
          pending_timer = -1;
          return -(EINVAL);
        }
 
      return snd_ioctl_return ((int *) arg, pending_timer);
      break;
 
    case SNDCTL_SEQ_PANIC:
      seq_panic ();
      break;
 
    case SNDCTL_SEQ_SYNC:
      if (dev)                  /*
                                 * Patch manager
                                 */
        return -(EIO);
 
      if (mode == OPEN_READ)
        return 0;
      while (qlen && !current_got_fatal_signal ())
        seq_sync ();
      if (qlen)
        return -(EINTR);
      else
        return 0;
      break;
 
    case SNDCTL_SEQ_RESET:
      if (dev)                  /*
                                 * Patch manager
                                 */
        return -(EIO);
 
      seq_reset ();
      return 0;
      break;
 
    case SNDCTL_SEQ_TESTMIDI:
      if (dev)                  /*
                                 * Patch manager
                                 */
        return -(EIO);
 
      midi_dev = get_user ((int *) arg);
      if (midi_dev < 0 || midi_dev >= max_mididev)
        return -(ENXIO);
 
      if (!midi_opened[midi_dev])
        {
          int             err, mode;
 
          mode = file->mode & O_ACCMODE;
          if ((err = midi_devs[midi_dev]->open (midi_dev, mode,
                                                sequencer_midi_input,
                                                sequencer_midi_output)) < 0)
            return err;
        }
 
      midi_opened[midi_dev] = 1;
 
      return 0;
      break;
 
    case SNDCTL_SEQ_GETINCOUNT:
      if (dev)                  /*
                                 * Patch manager
                                 */
        return -(EIO);
 
      if (mode == OPEN_WRITE)
        return 0;
      return snd_ioctl_return ((int *) arg, iqlen);
      break;
 
    case SNDCTL_SEQ_GETOUTCOUNT:
 
      if (mode == OPEN_READ)
        return 0;
      return snd_ioctl_return ((int *) arg, SEQ_MAX_QUEUE - qlen);
      break;
 
    case SNDCTL_SEQ_CTRLRATE:
      if (dev)                  /* Patch manager */
        return -(EIO);
 
      /*
       * If *arg == 0, just return the current rate
       */
      if (seq_mode == SEQ_2)
        return tmr->ioctl (tmr_no, cmd, arg);
 
      if (get_user ((int *) arg) != 0)
        return -(EINVAL);
 
      return snd_ioctl_return ((int *) arg, HZ);
      break;
 
    case SNDCTL_SEQ_RESETSAMPLES:
      {
        int             err;
 
        dev = get_user ((int *) arg);
        if (dev < 0 || dev >= num_synths)
          {
            return -(ENXIO);
          }
 
        if (!(synth_open_mask & (1 << dev)) && !orig_dev)
          {
            return -(EBUSY);
          }
 
        if (!orig_dev && pmgr_present[dev])
          pmgr_inform (dev, PM_E_PATCH_RESET, 0, 0, 0, 0);
 
        err = synth_devs[dev]->ioctl (dev, cmd, arg);
        return err;
      }
      break;
 
    case SNDCTL_SEQ_NRSYNTHS:
      return snd_ioctl_return ((int *) arg, max_synthdev);
      break;
 
    case SNDCTL_SEQ_NRMIDIS:
      return snd_ioctl_return ((int *) arg, max_mididev);
      break;
 
    case SNDCTL_SYNTH_MEMAVL:
      {
        int             dev = get_user ((int *) arg);
 
        if (dev < 0 || dev >= num_synths)
          return -(ENXIO);
 
        if (!(synth_open_mask & (1 << dev)) && !orig_dev)
          return -(EBUSY);
 
        return snd_ioctl_return ((int *) arg, synth_devs[dev]->ioctl (dev, cmd, arg));
      }
      break;
 
    case SNDCTL_FM_4OP_ENABLE:
      {
        int             dev = get_user ((int *) arg);
 
        if (dev < 0 || dev >= num_synths)
          return -(ENXIO);
 
        if (!(synth_open_mask & (1 << dev)))
          return -(ENXIO);
 
        synth_devs[dev]->ioctl (dev, cmd, arg);
        return 0;
      }
      break;
 
    case SNDCTL_SYNTH_INFO:
      {
        struct synth_info inf;
        int             dev;
 
        memcpy_fromfs ((char *) &inf, &((char *) arg)[0], sizeof (inf));
        dev = inf.device;
 
        if (dev < 0 || dev >= max_synthdev)
          return -(ENXIO);
 
        if (!(synth_open_mask & (1 << dev)) && !orig_dev)
          return -(EBUSY);
 
        return synth_devs[dev]->ioctl (dev, cmd, arg);
      }
      break;
 
    case SNDCTL_SEQ_OUTOFBAND:
      {
        struct seq_event_rec event_rec;
        unsigned long   flags;
 
        memcpy_fromfs ((char *) &event_rec, &((char *) arg)[0], sizeof (event_rec));
 
        save_flags (flags);
        cli ();
        play_event (event_rec.arr);
        restore_flags (flags);
 
        return 0;
      }
      break;
 
    case SNDCTL_MIDI_INFO:
      {
        struct midi_info inf;
        int             dev;
 
        memcpy_fromfs ((char *) &inf, &((char *) arg)[0], sizeof (inf));
        dev = inf.device;
 
        if (dev < 0 || dev >= max_mididev)
          return -(ENXIO);
 
        memcpy_tofs (&((char *) arg)[0], (char *) &(midi_devs[dev]->info), sizeof (inf));
        return 0;
      }
      break;
 
    case SNDCTL_PMGR_IFACE:
      {
        struct patmgr_info *inf;
        int             dev, err;
 
        if ((inf = (struct patmgr_info *) vmalloc (sizeof (*inf))) == NULL)
          {
            printk ("patmgr: Can't allocate memory for a message\n");
            return -(EIO);
          }
 
        memcpy_fromfs ((char *) inf, &((char *) arg)[0], sizeof (*inf));
        dev = inf->device;
 
        if (dev < 0 || dev >= num_synths)
          {
            vfree (inf);
            return -(ENXIO);
          }
 
        if (!synth_devs[dev]->pmgr_interface)
          {
            vfree (inf);
            return -(ENXIO);
          }
 
        if ((err = synth_devs[dev]->pmgr_interface (dev, inf)) == -1)
          {
            vfree (inf);
            return err;
          }
 
        memcpy_tofs (&((char *) arg)[0], (char *) inf, sizeof (*inf));
        vfree (inf);
        return 0;
      }
      break;
 
    case SNDCTL_PMGR_ACCESS:
      {
        struct patmgr_info *inf;
        int             dev, err;
 
        if ((inf = (struct patmgr_info *) vmalloc (sizeof (*inf))) == NULL)
          {
            printk ("patmgr: Can't allocate memory for a message\n");
            return -(EIO);
          }
 
        memcpy_fromfs ((char *) inf, &((char *) arg)[0], sizeof (*inf));
        dev = inf->device;
 
        if (dev < 0 || dev >= num_synths)
          {
            vfree (inf);
            return -(ENXIO);
          }
 
        if (!pmgr_present[dev])
          {
            vfree (inf);
            return -(ESRCH);
          }
 
        if ((err = pmgr_access (dev, inf)) < 0)
          {
            vfree (inf);
            return err;
          }
 
        memcpy_tofs (&((char *) arg)[0], (char *) inf, sizeof (*inf));
        vfree (inf);
        return 0;
      }
      break;
 
    case SNDCTL_SEQ_THRESHOLD:
      {
        int             tmp = get_user ((int *) arg);
 
        if (dev)                /*
                                 * Patch manager
                                 */
          return -(EIO);
 
        if (tmp < 1)
          tmp = 1;
        if (tmp >= SEQ_MAX_QUEUE)
          tmp = SEQ_MAX_QUEUE - 1;
        output_threshold = tmp;
        return 0;
      }
      break;
 
    case SNDCTL_MIDI_PRETIME:
      {
        int             val = get_user ((int *) arg);
 
        if (val < 0)
          val = 0;
 
        val = (HZ * val) / 10;
        pre_event_timeout = val;
        return snd_ioctl_return ((int *) arg, val);
      }
      break;
 
    default:
      if (dev)                  /*
                                 * Patch manager
                                 */
        return -(EIO);
 
      if (mode == OPEN_READ)
        return -(EIO);
 
      if (!synth_devs[0])
        return -(ENXIO);
      if (!(synth_open_mask & (1 << 0)))
        return -(ENXIO);
      return synth_devs[0]->ioctl (0, cmd, arg);
      break;
    }
 
  return -(EINVAL);
}
 
int
sequencer_select (int dev, struct fileinfo *file, int sel_type, select_table_handle * wait)
{
  unsigned long   flags;
 
  dev = dev >> 4;
 
  switch (sel_type)
    {
    case SEL_IN:
      save_flags (flags);
      cli ();
      if (!iqlen)
        {
 
          midi_sleep_flag.flags = WK_SLEEP;
          module_select_wait (&midi_sleeper, wait);
          restore_flags (flags);
          return 0;
        }
      restore_flags (flags);
      return 1;
      break;
 
    case SEL_OUT:
      save_flags (flags);
      cli ();
      if ((SEQ_MAX_QUEUE - qlen) < output_threshold)
        {
 
          seq_sleep_flag.flags = WK_SLEEP;
          module_select_wait (&seq_sleeper, wait);
          restore_flags (flags);
          return 0;
        }
      restore_flags (flags);
      return 1;
      break;
 
    case SEL_EX:
      return 0;
    }
 
  return 0;
}
 
 
void
sequencer_timer (unsigned long dummy)
{
  seq_startplay ();
}
 
int
note_to_freq (int note_num)
{
 
  /*
   * This routine converts a midi note to a frequency (multiplied by 1000)
   */
 
  int             note, octave, note_freq;
  int             notes[] =
  {
    261632, 277189, 293671, 311132, 329632, 349232,
    369998, 391998, 415306, 440000, 466162, 493880
  };
 
#define BASE_OCTAVE     5
 
  octave = note_num / 12;
  note = note_num % 12;
 
  note_freq = notes[note];
 
  if (octave < BASE_OCTAVE)
    note_freq >>= (BASE_OCTAVE - octave);
  else if (octave > BASE_OCTAVE)
    note_freq <<= (octave - BASE_OCTAVE);
 
  /*
   * note_freq >>= 1;
   */
 
  return note_freq;
}
 
unsigned long
compute_finetune (unsigned long base_freq, int bend, int range)
{
  unsigned long   amount;
  int             negative, semitones, cents, multiplier = 1;
 
  if (!bend)
    return base_freq;
  if (!range)
    return base_freq;
 
  if (!base_freq)
    return base_freq;
 
  if (range >= 8192)
    range = 8192;
 
  bend = bend * range / 8192;
  if (!bend)
    return base_freq;
 
  negative = bend < 0 ? 1 : 0;
 
  if (bend < 0)
    bend *= -1;
  if (bend > range)
    bend = range;
 
  /*
     if (bend > 2399)
     bend = 2399;
   */
  while (bend > 2399)
    {
      multiplier *= 4;
      bend -= 2400;
    }
 
  semitones = bend / 100;
  cents = bend % 100;
 
  amount = (int) (semitone_tuning[semitones] * multiplier * cent_tuning[cents])
    / 10000;
 
  if (negative)
    return (base_freq * 10000) / amount;        /* Bend down */
  else
    return (base_freq * amount) / 10000;        /* Bend up */
}
 
 
void
sequencer_init (void)
{
 
 
  queue = (unsigned char *) (sound_mem_blocks[sound_nblocks] = vmalloc (SEQ_MAX_QUEUE * EV_SZ));
  if (sound_nblocks < 1024)
    sound_nblocks++;;
  if (queue == NULL)
    {
      printk ("Sound: Can't allocate memory for sequencer output queue\n");
      return;
    }
 
 
  iqueue = (unsigned char *) (sound_mem_blocks[sound_nblocks] = vmalloc (SEQ_MAX_QUEUE * IEV_SZ));
  if (sound_nblocks < 1024)
    sound_nblocks++;;
  if (iqueue == NULL)
    {
      printk ("Sound: Can't allocate memory for sequencer input queue\n");
      return;
    }
 
  sequencer_ok = 1;
}
 
#endif
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[/] [or1k/] [trunk/] [rc203soc/] [sw/] [uClinux/] [drivers/] [sound/] [sequencer.c] - Blame information for rev 1772

Line No.	Rev	Author	Line
1	1626	jcastillo	`/*`
2			`* sound/sequencer.c`
3			`*`
4			`* The sequencer personality manager.`
5			`*/`
6			`/*`
7			`* Copyright (C) by Hannu Savolainen 1993-1996`
8			`*`
9			`* USS/Lite for Linux is distributed under the GNU GENERAL PUBLIC LICENSE (GPL)`
10			`* Version 2 (June 1991). See the "COPYING" file distributed with this software`
11			`* for more info.`
12			`*/`
13			`#include <linux/config.h>`
14
15
16			`#define SEQUENCER_C`
17			`#include "sound_config.h"`
18
19			`#ifdef CONFIG_SEQUENCER`
20
21			`#include "midi_ctrl.h"`
22
23			`static int sequencer_ok = 0;`
24			`static struct sound_timer_operations *tmr;`
25			`static int tmr_no = -1; /* Currently selected timer */`
26			`static int pending_timer = -1; /* For timer change operation */`
27
28			`/*`
29			`* Local counts for number of synth and MIDI devices. These are initialized`
30			`* by the sequencer_open.`
31			`*/`
32			`static int max_mididev = 0;`
33			`static int max_synthdev = 0;`
34
35			`/*`
36			`* The seq_mode gives the operating mode of the sequencer:`
37			`* 1 = level1 (the default)`
38			`* 2 = level2 (extended capabilities)`
39			`*/`
40