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/* Project: HARTIK 3.0 Sound Library */
/* Description: Hard Real TIme Kernel for 8086 compatible */
/* Author: Luca Abeni */
/* Date: 5/12/1997 */
/* File: Sound.C */
/* Revision: 3.0 */
/* added by Paolo */
#define SOUND_WCET 200
/* Sound generic interface */
#include <kernel/kern.h>
#include "blaster.h"
#include <drivers/sound.h>
#include <drivers/dma.h>
//extern struct proc_des proc_table[MAX_PROC];
extern struct sb_device sb_dev
;
extern TASK proc_play
();
extern TASK proc_sample
();
extern TASK sb_proc
();
extern void sb_handler
(int n
);
extern struct sound_buffer buff_des
;
struct rawfuncs f_des
;
struct dma_buff dma_des
;
/*int sound_exc(int err)
{
switch (err) {
case SOUND_CARD_NOT_FOUND:
cprintf("SOUND PANIC --> Sound card not found.\n");
return 0;
case SOUND_RAWFUN_NOT_SET:
cprintf("Self-buffering OP error --> User function not set.\n");
return 0;
case SOUND_TICK_TOO_LARGE:
cprintf("PIO mode OP error --> sys_tick too large.\n");
return 0;
case SOUND_ASYNCH_WAIT:
cprintf("Asynchronous OP error --> Wait on asynch operation.\n");
return 1;
default :
return 1;
}
} */
/* Set the user's functions for self buffering */
void sound_setfun
(int (*infun
)(void *rawbuff
), int (*outfun
)(void *rawbuff
))
{
/* Should be NULL here! Luca: used -1 instead NULL */
if (infun
!= NULL
) {
f_des.
infun = infun
;
f_des.
infunpresent = 1;
}
if(outfun
!= NULL
) {
f_des.
outfun = outfun
;
f_des.
outfunpresent = 1;
}
}
/*
This function is called by the sound card driver function when the card
generate an interrupt during a self buffering input operation. The user's
self buffering function is called by this function
*/
int selfinfun
(struct dma_buff
*b
)
{
int res
;
res
= f_des.
infun(&b
->dma_buff
[(b
->dma_bufflen
>> 1) * b
->page
]);
b
->page
= !b
->page
;
return res
;
}
/*
This function is called by the sound card driver function when the card
generate an interrupt during a self buffering output operation. The user's
self buffering function is called by this function
*/
int selfoutfun
(struct dma_buff
*b
)
{
int res
;
res
= f_des.
outfun(&b
->dma_buff
[(b
->dma_bufflen
>> 1) * b
->page
]);
b
->page
= !b
->page
;
return res
;
}
/*
Play a sample: this function calls the adeguate low-level playing function
with the correct parameters
the task model in the last parameter is used for the sb_player task.
it must be a periodic task with a correct period. if not specified (NULL),
a soft task is used instead.
it returns 0 if all ok,
EINVAL if the outfun isn't specified
ESRCH if the sb_player can not be created
*/
int sound_play
(BYTE
*buff
, DWORD sps
, DWORD len
, BYTE t
, TASK_MODEL
*m
)
{
double rate
;
PID p_pl
;
// WORD s1, p;
/* Self Buffering?*/
if (t
& MYFUN
) {
/*Yes */
if (f_des.
outfunpresent != 0) {
buff_des.
fun = selfoutfun
;
}
else
return EINVAL
;
}
else {
/* No: set the standard double-buffering output function (module dma.c) */
buff_des.
fun = outfun
;
}
/* set the operation parameters...*/
buff_des.
synch = !(t
& SYNCH
);
dma_des.
len = len
;
dma_des.
p = buff
;
if (t
& DMA_OP
) {
/* DMA op */
sb_setrate
(sps
, OUT
);
/*
if (t & DYNBUFF) {
s1 = (sps / 1000) * ((t & PCM16) ? 2 : 1);
p = ((dma_des.dma_bufflen >> 1) * 1000 ) / (sound_tick * s1);
if(p < 1) {
sb_dev.pwarning = 1;
p = 1;
} else sb_dev.pwarning = 0;
/ * Adjust the driver task's minimum interarrival time */ /*
kern_cli();
proc_table[p_sb].period = p;
proc_table[p_sb].drel = p;
kern_sti();
sb_dev.period = p;
} */
if (!(t
& NOBUFF
)) {
if (t
& PCM16
) sb_dma16buffop
(OUT
);
else sb_dmabuffop
(OUT
);
} else {
/* Double buffering operation */
buff_des.
fun = dummyfun2
;
if (t
& PCM16
) sb_dma16op
(OUT
);
else sb_dmaop
(OUT
);
}
} else {
/* Non DMA op: create the playing process */
SOFT_TASK_MODEL m_soft
;
if (!m
) {
rate
= (999999 / sps
) + 1;
soft_task_default_model
(m_soft
);
soft_task_def_system
(m_soft
);
soft_task_def_nokill
(m_soft
);
soft_task_def_period
(m_soft
,rate
);
soft_task_def_met
(m_soft
,rate
);
soft_task_def_wcet
(m_soft
,SOUND_WCET
);
m
= (TASK_MODEL
*)&m_soft
;
}
p_pl
= task_create
("sb_Player",proc_play
, &m
, NULL
);
if (p_pl
== NIL
) {
cprintf
("Sound.c: Cannot create sb_Player\n");
exit(1);
return ESRCH
;
}
task_activate
(p_pl
);
}
return 0;
}
/*
Sample: this function calls the adeguate low-level sampling function
with the correct parameters. It is similar to sound_play (see it for the
comments
the task model in the last parameter is used for the sb_player task.
it must be a periodic task with a correct period. if not specified (NULL),
a soft task is used instead.
it returns 0 if all ok,
EINVAL if the outfun isn't specified
ESRCH if the sb_player can not be created
*/
int sound_sample
(BYTE
*buff
, DWORD sps
, DWORD len
, BYTE t
, TASK_MODEL
*m
)
{
double rate
;
PID p_sample
;
// WORD s1, p;
// MODEL m = BASE_MODEL;
if (t
& MYFUN
) {
if (f_des.
infunpresent != 0) {
buff_des.
fun = selfinfun
;
}
else
return EINVAL
;
}
else
buff_des.
fun = infun
;
buff_des.
synch = !(t
& SYNCH
);
dma_des.
len = len
;
dma_des.
p = buff
;
if (t
& DMA_OP
) {
sb_setrate
(sps
, IN
);
/*
if (t & DYNBUFF) {
p_sb = task_pid("sb_EndDMA");
s1 = (sps / 100) * ((t & PCM16) ? 2 : 1);
p = ((dma_des.dma_bufflen >> 1) * 1000 ) / (sound_tick * s1);
if(p < 1) {
sb_dev.pwarning = 1;
p = 1;
} else sb_dev.pwarning = 0;
kern_cli();
proc_table[p_sb].period = p;
proc_table[p_sb].drel = p;
kern_sti();
sb_dev.period = p;
} */
if (!(t
& NOBUFF
)) {
if (t
& PCM16
) sb_dma16buffop
(IN
);
else sb_dmabuffop
(IN
);
} else {
buff_des.
fun = dummyfun2
;
if (t
& PCM16
) sb_dma16op
(IN
);
else sb_dmaop
(IN
);
}
} else {
/* Non DMA op: create the playing process */
SOFT_TASK_MODEL m_soft
;
if (!m
) {
rate
= (999999 / sps
) + 1;
soft_task_default_model
(m_soft
);
soft_task_def_system
(m_soft
);
soft_task_def_nokill
(m_soft
);
soft_task_def_period
(m_soft
,rate
);
soft_task_def_met
(m_soft
,rate
);
soft_task_def_wcet
(m_soft
,SOUND_WCET
);
m
= (TASK_MODEL
*)&m_soft
;
}
p_sample
= task_create
("sb_Sampler",proc_sample
, &m
, NULL
);
if (p_sample
== NIL
) {
cprintf
("Sound.c: Cannot create sb_Sampler\n");
exit(1);
return ESRCH
;
}
task_activate
(p_sample
);
}
return 0;
}
/*
Wait for the end of a synchronous sound op: it is implemented with a
simple semaphore
It returns 0 if all ok,
-1 if no sinchronous operation was called before
*/
int sound_wait
(void)
{
if (buff_des.
synch) {
sem_wait
(&buff_des.
synchr);
buff_des.
synch = 0;
return 0;
}
else
return -1;
}
/* returns 0 if all ok,
ENOSPC if a problem occurs when creating the semaphores structures
ESRCH if the Enddma task cn not be created
*/
int sound_init
(WORD rawbuffsize
, TASK_MODEL
*m
)
{
PID p_sb
;
int period
;
SOFT_TASK_MODEL m_soft
;
/* Semaphore for synchronous ops */
if (sem_init
(&buff_des.
synchr,0,0))
return ENOSPC
;
/* Init the card */
sb_init
();
sbmixer_reset
();
sbmixer_setinput
(0x01, ENABLE
);
sbmixer_setoutput
(0x01, DISABLE
);
sbmixer_setmiclev
(0x1F);
sbmixer_setAGC
(ENABLE
);
sbmixer_setingainlev
(0);
f_des.
infun = 0;
f_des.
infunpresent = 0;
f_des.
outfun = 0;
f_des.
outfunpresent = 0;
/* init the buffers for DMA ops */
dma_getalignbuff
(&dma_des
, rawbuffsize
);
buff_des.
sound_dma = &dma_des
;
if (!m
) {
period
= (rawbuffsize
* 1000000) / 48000;
kern_printf
("period=%d\n",period
);
soft_task_default_model
(m_soft
);
soft_task_def_system
(m_soft
);
soft_task_def_nokill
(m_soft
);
soft_task_def_period
(m_soft
,period
);
soft_task_def_met
(m_soft
,SOUND_WCET
);
soft_task_def_wcet
(m_soft
,SOUND_WCET
);
soft_task_def_aperiodic
(m_soft
);
m
= (TASK_MODEL
*)&m_soft
;
}
/* create the driver process and set it and the Fast Handler */
p_sb
= task_create
("sb_EndDMA", sb_proc
, m
, NULL
);
if (p_sb
== NIL
) {
cprintf
("Sound.c: Cannot create sb_EndDMA\n");
cprintf
("errno=%d\n",errno
);
exit(1);
return ESRCH
;
}
//sb_dev.period = period;
handler_set
(sb_dev.
IntLine, sb_handler
, FALSE
, p_sb
, NULL
);
return 0;
}
/* Obvious... */
void sound_info
(void)
{
cprintf
("Hartik Sound lib [V 3.2]:\n");
cprintf
("Sound Blaster 16 or clone found:\n");
sb_show
();
}
/*
This function is called by the driver process on the last transfert of an
operation
*/
int dummyfun1
(struct dma_buff
*d
)
{
buff_des.
fun = dummyfun2
;
return 0;
}
/*
This function is called by the driver process when the next transfert
will be the last of the current operation
*/
int dummyfun2
(struct dma_buff
*d
)
{
if (buff_des.
synch) sem_post
(&buff_des.
synchr);
sb_stopdsp
(8);
sb_stopdsp
(16);
dma_stop
(sb_dev.
DMA8Channel);
dma16_stop
(sb_dev.
DMA16Channel);
return 0;
}
/* Obvious... */
void sound_stop
(void)
{
if (!buff_des.
synch) {
sb_stopdsp
(8);
sb_stopdsp
(16);
dma_stop
(sb_dev.
DMA8Channel);
dma16_stop
(sb_dev.
DMA16Channel);
}
}