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Kirill Smelkov
linux
Commits
56b06e0b
Commit
56b06e0b
authored
Jul 11, 2003
by
Alan Cox
Committed by
Steve French
Jul 11, 2003
Browse files
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[PATCH] Add the au1000 driver
This is used by some MIPS systems
parent
23a66b72
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sound/oss/au1000.c
sound/oss/au1000.c
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56b06e0b
/*
* au1000.c -- Sound driver for Alchemy Au1000 MIPS Internet Edge
* Processor.
*
* Copyright 2001 MontaVista Software Inc.
* Author: MontaVista Software, Inc.
* stevel@mvista.com or source@mvista.com
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation; either version 2 of the License, or (at your
* option) any later version.
*
* THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN
* NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
* USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
* ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 675 Mass Ave, Cambridge, MA 02139, USA.
*
*
* Module command line parameters:
*
* Supported devices:
* /dev/dsp standard OSS /dev/dsp device
* /dev/mixer standard OSS /dev/mixer device
*
* Notes:
*
* 1. Much of the OSS buffer allocation, ioctl's, and mmap'ing are
* taken, slightly modified or not at all, from the ES1371 driver,
* so refer to the credits in es1371.c for those. The rest of the
* code (probe, open, read, write, the ISR, etc.) is new.
*
* Revision history
* 06.27.2001 Initial version
* 03.20.2002 Added mutex locks around read/write methods, to prevent
* simultaneous access on SMP or preemptible kernels. Also
* removed the counter/pointer fragment aligning at the end
* of read/write methods [stevel].
* 03.21.2002 Add support for coherent DMA on the audio read/write DMA
* channels [stevel].
*
*/
#include <linux/version.h>
#include <linux/module.h>
#include <linux/string.h>
#include <linux/ioport.h>
#include <linux/sched.h>
#include <linux/delay.h>
#include <linux/sound.h>
#include <linux/slab.h>
#include <linux/soundcard.h>
#include <linux/init.h>
#include <linux/poll.h>
#include <linux/pci.h>
#include <linux/bitops.h>
#include <linux/proc_fs.h>
#include <linux/spinlock.h>
#include <linux/smp_lock.h>
#include <linux/ac97_codec.h>
#include <linux/wrapper.h>
#include <asm/io.h>
#include <asm/uaccess.h>
#include <asm/hardirq.h>
#include <asm/au1000.h>
#include <asm/au1000_dma.h>
/* --------------------------------------------------------------------- */
#undef OSS_DOCUMENTED_MIXER_SEMANTICS
#define AU1000_DEBUG
#undef AU1000_VERBOSE_DEBUG
#define USE_COHERENT_DMA
#define AU1000_MODULE_NAME "Au1000 audio"
#define PFX AU1000_MODULE_NAME
#ifdef AU1000_DEBUG
#define dbg(format, arg...) printk(KERN_DEBUG PFX ": " format "\n" , ## arg)
#else
#define dbg(format, arg...) do {} while (0)
#endif
#define err(format, arg...) printk(KERN_ERR PFX ": " format "\n" , ## arg)
#define info(format, arg...) printk(KERN_INFO PFX ": " format "\n" , ## arg)
#define warn(format, arg...) printk(KERN_WARNING PFX ": " format "\n" , ## arg)
/* misc stuff */
#define POLL_COUNT 0x5000
#define AC97_EXT_DACS (AC97_EXTID_SDAC | AC97_EXTID_CDAC | AC97_EXTID_LDAC)
/* Boot options */
static
int
vra
=
0
;
// 0 = no VRA, 1 = use VRA if codec supports it
MODULE_PARM
(
vra
,
"i"
);
MODULE_PARM_DESC
(
vra
,
"if 1 use VRA if codec supports it"
);
/* --------------------------------------------------------------------- */
struct
au1000_state
{
/* soundcore stuff */
int
dev_audio
;
#ifdef AU1000_DEBUG
/* debug /proc entry */
struct
proc_dir_entry
*
ps
;
struct
proc_dir_entry
*
ac97_ps
;
#endif
/* AU1000_DEBUG */
struct
ac97_codec
*
codec
;
unsigned
codec_base_caps
;
// AC'97 reg 00h, "Reset Register"
unsigned
codec_ext_caps
;
// AC'97 reg 28h, "Extended Audio ID"
int
no_vra
;
// do not use VRA
spinlock_t
lock
;
struct
semaphore
open_sem
;
struct
semaphore
sem
;
mode_t
open_mode
;
wait_queue_head_t
open_wait
;
struct
dmabuf
{
unsigned
int
dmanr
;
// DMA Channel number
unsigned
sample_rate
;
// Hz
unsigned
src_factor
;
// SRC interp/decimation (no vra)
unsigned
sample_size
;
// 8 or 16
int
num_channels
;
// 1 = mono, 2 = stereo, 4, 6
int
dma_bytes_per_sample
;
// DMA bytes per audio sample frame
int
user_bytes_per_sample
;
// User bytes per audio sample frame
int
cnt_factor
;
// user-to-DMA bytes per audio
// sample frame
void
*
rawbuf
;
dma_addr_t
dmaaddr
;
unsigned
buforder
;
unsigned
numfrag
;
// # of DMA fragments in DMA buffer
unsigned
fragshift
;
void
*
nextIn
;
// ptr to next-in to DMA buffer
void
*
nextOut
;
// ptr to next-out from DMA buffer
int
count
;
// current byte count in DMA buffer
unsigned
total_bytes
;
// total bytes written or read
unsigned
error
;
// over/underrun
wait_queue_head_t
wait
;
/* redundant, but makes calculations easier */
unsigned
fragsize
;
// user perception of fragment size
unsigned
dma_fragsize
;
// DMA (real) fragment size
unsigned
dmasize
;
// Total DMA buffer size
// (mult. of DMA fragsize)
/* OSS stuff */
unsigned
mapped
:
1
;
unsigned
ready
:
1
;
unsigned
stopped
:
1
;
unsigned
ossfragshift
;
int
ossmaxfrags
;
unsigned
subdivision
;
}
dma_dac
,
dma_adc
;
}
au1000_state
;
/* --------------------------------------------------------------------- */
static
inline
unsigned
ld2
(
unsigned
int
x
)
{
unsigned
r
=
0
;
if
(
x
>=
0x10000
)
{
x
>>=
16
;
r
+=
16
;
}
if
(
x
>=
0x100
)
{
x
>>=
8
;
r
+=
8
;
}
if
(
x
>=
0x10
)
{
x
>>=
4
;
r
+=
4
;
}
if
(
x
>=
4
)
{
x
>>=
2
;
r
+=
2
;
}
if
(
x
>=
2
)
r
++
;
return
r
;
}
#ifdef USE_COHERENT_DMA
static
inline
void
*
dma_alloc
(
size_t
size
,
dma_addr_t
*
dma_handle
)
{
void
*
ret
=
(
void
*
)
__get_free_pages
(
GFP_ATOMIC
|
GFP_DMA
,
get_order
(
size
));
if
(
ret
!=
NULL
)
{
memset
(
ret
,
0
,
size
);
*
dma_handle
=
virt_to_phys
(
ret
);
}
return
ret
;
}
static
inline
void
dma_free
(
size_t
size
,
void
*
va
,
dma_addr_t
dma_handle
)
{
free_pages
((
unsigned
long
)
va
,
get_order
(
size
));
}
#else
static
inline
void
*
dma_alloc
(
size_t
size
,
dma_addr_t
*
dma_handle
)
{
return
pci_alloc_consistent
(
NULL
,
size
,
dma_handle
);
}
static
inline
void
dma_free
(
size_t
size
,
void
*
va
,
dma_addr_t
dma_handle
)
{
pci_free_consistent
(
NULL
,
size
,
va
,
dma_handle
);
}
#endif
/* --------------------------------------------------------------------- */
static
void
au1000_delay
(
int
msec
)
{
unsigned
long
tmo
;
signed
long
tmo2
;
if
(
in_interrupt
())
return
;
tmo
=
jiffies
+
(
msec
*
HZ
)
/
1000
;
for
(;;)
{
tmo2
=
tmo
-
jiffies
;
if
(
tmo2
<=
0
)
break
;
schedule_timeout
(
tmo2
);
}
}
/* --------------------------------------------------------------------- */
static
u16
rdcodec
(
struct
ac97_codec
*
codec
,
u8
addr
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
codec
->
private_data
;
unsigned
long
flags
;
u32
cmd
;
u16
data
;
int
i
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
for
(
i
=
0
;
i
<
POLL_COUNT
;
i
++
)
if
(
!
(
au_readl
(
AC97C_STATUS
)
&
AC97C_CP
))
break
;
if
(
i
==
POLL_COUNT
)
err
(
"rdcodec: codec cmd pending expired!"
);
cmd
=
(
u32
)
addr
&
AC97C_INDEX_MASK
;
cmd
|=
AC97C_READ
;
// read command
au_writel
(
cmd
,
AC97C_CMD
);
/* now wait for the data */
for
(
i
=
0
;
i
<
POLL_COUNT
;
i
++
)
if
(
!
(
au_readl
(
AC97C_STATUS
)
&
AC97C_CP
))
break
;
if
(
i
==
POLL_COUNT
)
{
err
(
"rdcodec: read poll expired!"
);
return
0
;
}
data
=
au_readl
(
AC97C_CMD
)
&
0xffff
;
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
return
data
;
}
static
void
wrcodec
(
struct
ac97_codec
*
codec
,
u8
addr
,
u16
data
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
codec
->
private_data
;
unsigned
long
flags
;
u32
cmd
;
int
i
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
for
(
i
=
0
;
i
<
POLL_COUNT
;
i
++
)
if
(
!
(
au_readl
(
AC97C_STATUS
)
&
AC97C_CP
))
break
;
if
(
i
==
POLL_COUNT
)
err
(
"wrcodec: codec cmd pending expired!"
);
cmd
=
(
u32
)
addr
&
AC97C_INDEX_MASK
;
cmd
&=
~
AC97C_READ
;
// write command
cmd
|=
((
u32
)
data
<<
AC97C_WD_BIT
);
// OR in the data word
au_writel
(
cmd
,
AC97C_CMD
);
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
}
static
void
waitcodec
(
struct
ac97_codec
*
codec
)
{
u16
temp
;
int
i
;
/* codec_wait is used to wait for a ready state after
an AC97C_RESET. */
au1000_delay
(
10
);
// first poll the CODEC_READY tag bit
for
(
i
=
0
;
i
<
POLL_COUNT
;
i
++
)
if
(
au_readl
(
AC97C_STATUS
)
&
AC97C_READY
)
break
;
if
(
i
==
POLL_COUNT
)
{
err
(
"waitcodec: CODEC_READY poll expired!"
);
return
;
}
// get AC'97 powerdown control/status register
temp
=
rdcodec
(
codec
,
AC97_POWER_CONTROL
);
// If anything is powered down, power'em up
if
(
temp
&
0x7f00
)
{
// Power on
wrcodec
(
codec
,
AC97_POWER_CONTROL
,
0
);
au1000_delay
(
100
);
// Reread
temp
=
rdcodec
(
codec
,
AC97_POWER_CONTROL
);
}
// Check if Codec REF,ANL,DAC,ADC ready
if
((
temp
&
0x7f0f
)
!=
0x000f
)
err
(
"codec reg 26 status (0x%x) not ready!!"
,
temp
);
}
/* --------------------------------------------------------------------- */
/* stop the ADC before calling */
static
void
set_adc_rate
(
struct
au1000_state
*
s
,
unsigned
rate
)
{
struct
dmabuf
*
adc
=
&
s
->
dma_adc
;
struct
dmabuf
*
dac
=
&
s
->
dma_dac
;
unsigned
adc_rate
,
dac_rate
;
u16
ac97_extstat
;
if
(
s
->
no_vra
)
{
// calc SRC factor
adc
->
src_factor
=
((
96000
/
rate
)
+
1
)
>>
1
;
adc
->
sample_rate
=
48000
/
adc
->
src_factor
;
return
;
}
adc
->
src_factor
=
1
;
ac97_extstat
=
rdcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
);
rate
=
rate
>
48000
?
48000
:
rate
;
// enable VRA
wrcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
,
ac97_extstat
|
AC97_EXTSTAT_VRA
);
// now write the sample rate
wrcodec
(
s
->
codec
,
AC97_PCM_LR_ADC_RATE
,
(
u16
)
rate
);
// read it back for actual supported rate
adc_rate
=
rdcodec
(
s
->
codec
,
AC97_PCM_LR_ADC_RATE
);
#ifdef AU1000_VERBOSE_DEBUG
dbg
(
__FUNCTION__
": set to %d Hz"
,
adc_rate
);
#endif
// some codec's don't allow unequal DAC and ADC rates, in which case
// writing one rate reg actually changes both.
dac_rate
=
rdcodec
(
s
->
codec
,
AC97_PCM_FRONT_DAC_RATE
);
if
(
dac
->
num_channels
>
2
)
wrcodec
(
s
->
codec
,
AC97_PCM_SURR_DAC_RATE
,
dac_rate
);
if
(
dac
->
num_channels
>
4
)
wrcodec
(
s
->
codec
,
AC97_PCM_LFE_DAC_RATE
,
dac_rate
);
adc
->
sample_rate
=
adc_rate
;
dac
->
sample_rate
=
dac_rate
;
}
/* stop the DAC before calling */
static
void
set_dac_rate
(
struct
au1000_state
*
s
,
unsigned
rate
)
{
struct
dmabuf
*
dac
=
&
s
->
dma_dac
;
struct
dmabuf
*
adc
=
&
s
->
dma_adc
;
unsigned
adc_rate
,
dac_rate
;
u16
ac97_extstat
;
if
(
s
->
no_vra
)
{
// calc SRC factor
dac
->
src_factor
=
((
96000
/
rate
)
+
1
)
>>
1
;
dac
->
sample_rate
=
48000
/
dac
->
src_factor
;
return
;
}
dac
->
src_factor
=
1
;
ac97_extstat
=
rdcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
);
rate
=
rate
>
48000
?
48000
:
rate
;
// enable VRA
wrcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
,
ac97_extstat
|
AC97_EXTSTAT_VRA
);
// now write the sample rate
wrcodec
(
s
->
codec
,
AC97_PCM_FRONT_DAC_RATE
,
(
u16
)
rate
);
// I don't support different sample rates for multichannel,
// so make these channels the same.
if
(
dac
->
num_channels
>
2
)
wrcodec
(
s
->
codec
,
AC97_PCM_SURR_DAC_RATE
,
(
u16
)
rate
);
if
(
dac
->
num_channels
>
4
)
wrcodec
(
s
->
codec
,
AC97_PCM_LFE_DAC_RATE
,
(
u16
)
rate
);
// read it back for actual supported rate
dac_rate
=
rdcodec
(
s
->
codec
,
AC97_PCM_FRONT_DAC_RATE
);
#ifdef AU1000_VERBOSE_DEBUG
dbg
(
__FUNCTION__
": set to %d Hz"
,
dac_rate
);
#endif
// some codec's don't allow unequal DAC and ADC rates, in which case
// writing one rate reg actually changes both.
adc_rate
=
rdcodec
(
s
->
codec
,
AC97_PCM_LR_ADC_RATE
);
dac
->
sample_rate
=
dac_rate
;
adc
->
sample_rate
=
adc_rate
;
}
static
void
stop_dac
(
struct
au1000_state
*
s
)
{
struct
dmabuf
*
db
=
&
s
->
dma_dac
;
unsigned
long
flags
;
if
(
db
->
stopped
)
return
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
disable_dma
(
db
->
dmanr
);
db
->
stopped
=
1
;
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
}
static
void
stop_adc
(
struct
au1000_state
*
s
)
{
struct
dmabuf
*
db
=
&
s
->
dma_adc
;
unsigned
long
flags
;
if
(
db
->
stopped
)
return
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
disable_dma
(
db
->
dmanr
);
db
->
stopped
=
1
;
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
}
static
void
set_xmit_slots
(
int
num_channels
)
{
u32
ac97_config
=
au_readl
(
AC97C_CONFIG
)
&
~
AC97C_XMIT_SLOTS_MASK
;
switch
(
num_channels
)
{
case
1
:
// mono
case
2
:
// stereo, slots 3,4
ac97_config
|=
(
0x3
<<
AC97C_XMIT_SLOTS_BIT
);
break
;
case
4
:
// stereo with surround, slots 3,4,7,8
ac97_config
|=
(
0x33
<<
AC97C_XMIT_SLOTS_BIT
);
break
;
case
6
:
// stereo with surround and center/LFE, slots 3,4,6,7,8,9
ac97_config
|=
(
0x7b
<<
AC97C_XMIT_SLOTS_BIT
);
break
;
}
au_writel
(
ac97_config
,
AC97C_CONFIG
);
}
static
void
set_recv_slots
(
int
num_channels
)
{
u32
ac97_config
=
au_readl
(
AC97C_CONFIG
)
&
~
AC97C_RECV_SLOTS_MASK
;
/*
* Always enable slots 3 and 4 (stereo). Slot 6 is
* optional Mic ADC, which I don't support yet.
*/
ac97_config
|=
(
0x3
<<
AC97C_RECV_SLOTS_BIT
);
au_writel
(
ac97_config
,
AC97C_CONFIG
);
}
static
void
start_dac
(
struct
au1000_state
*
s
)
{
struct
dmabuf
*
db
=
&
s
->
dma_dac
;
unsigned
long
flags
;
unsigned
long
buf1
,
buf2
;
if
(
!
db
->
stopped
)
return
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
au_readl
(
AC97C_STATUS
);
// read status to clear sticky bits
// reset Buffer 1 and 2 pointers to nextOut and nextOut+dma_fragsize
buf1
=
virt_to_phys
(
db
->
nextOut
);
buf2
=
buf1
+
db
->
dma_fragsize
;
if
(
buf2
>=
db
->
dmaaddr
+
db
->
dmasize
)
buf2
-=
db
->
dmasize
;
set_xmit_slots
(
db
->
num_channels
);
init_dma
(
db
->
dmanr
);
if
(
get_dma_active_buffer
(
db
->
dmanr
)
==
0
)
{
clear_dma_done0
(
db
->
dmanr
);
// clear DMA done bit
set_dma_addr0
(
db
->
dmanr
,
buf1
);
set_dma_addr1
(
db
->
dmanr
,
buf2
);
}
else
{
clear_dma_done1
(
db
->
dmanr
);
// clear DMA done bit
set_dma_addr1
(
db
->
dmanr
,
buf1
);
set_dma_addr0
(
db
->
dmanr
,
buf2
);
}
set_dma_count
(
db
->
dmanr
,
db
->
dma_fragsize
>>
1
);
enable_dma_buffers
(
db
->
dmanr
);
start_dma
(
db
->
dmanr
);
#ifdef AU1000_VERBOSE_DEBUG
dump_au1000_dma_channel
(
db
->
dmanr
);
#endif
db
->
stopped
=
0
;
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
}
static
void
start_adc
(
struct
au1000_state
*
s
)
{
struct
dmabuf
*
db
=
&
s
->
dma_adc
;
unsigned
long
flags
;
unsigned
long
buf1
,
buf2
;
if
(
!
db
->
stopped
)
return
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
au_readl
(
AC97C_STATUS
);
// read status to clear sticky bits
// reset Buffer 1 and 2 pointers to nextIn and nextIn+dma_fragsize
buf1
=
virt_to_phys
(
db
->
nextIn
);
buf2
=
buf1
+
db
->
dma_fragsize
;
if
(
buf2
>=
db
->
dmaaddr
+
db
->
dmasize
)
buf2
-=
db
->
dmasize
;
set_recv_slots
(
db
->
num_channels
);
init_dma
(
db
->
dmanr
);
if
(
get_dma_active_buffer
(
db
->
dmanr
)
==
0
)
{
clear_dma_done0
(
db
->
dmanr
);
// clear DMA done bit
set_dma_addr0
(
db
->
dmanr
,
buf1
);
set_dma_addr1
(
db
->
dmanr
,
buf2
);
}
else
{
clear_dma_done1
(
db
->
dmanr
);
// clear DMA done bit
set_dma_addr1
(
db
->
dmanr
,
buf1
);
set_dma_addr0
(
db
->
dmanr
,
buf2
);
}
set_dma_count
(
db
->
dmanr
,
db
->
dma_fragsize
>>
1
);
enable_dma_buffers
(
db
->
dmanr
);
start_dma
(
db
->
dmanr
);
#ifdef AU1000_VERBOSE_DEBUG
dump_au1000_dma_channel
(
db
->
dmanr
);
#endif
db
->
stopped
=
0
;
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
}
/* --------------------------------------------------------------------- */
#define DMABUF_DEFAULTORDER (17-PAGE_SHIFT)
#define DMABUF_MINORDER 1
extern
inline
void
dealloc_dmabuf
(
struct
au1000_state
*
s
,
struct
dmabuf
*
db
)
{
struct
page
*
page
,
*
pend
;
if
(
db
->
rawbuf
)
{
/* undo marking the pages as reserved */
pend
=
virt_to_page
(
db
->
rawbuf
+
(
PAGE_SIZE
<<
db
->
buforder
)
-
1
);
for
(
page
=
virt_to_page
(
db
->
rawbuf
);
page
<=
pend
;
page
++
)
mem_map_unreserve
(
page
);
dma_free
(
PAGE_SIZE
<<
db
->
buforder
,
db
->
rawbuf
,
db
->
dmaaddr
);
}
db
->
rawbuf
=
db
->
nextIn
=
db
->
nextOut
=
NULL
;
db
->
mapped
=
db
->
ready
=
0
;
}
static
int
prog_dmabuf
(
struct
au1000_state
*
s
,
struct
dmabuf
*
db
)
{
int
order
;
unsigned
user_bytes_per_sec
;
unsigned
bufs
;
struct
page
*
page
,
*
pend
;
unsigned
rate
=
db
->
sample_rate
;
if
(
!
db
->
rawbuf
)
{
db
->
ready
=
db
->
mapped
=
0
;
for
(
order
=
DMABUF_DEFAULTORDER
;
order
>=
DMABUF_MINORDER
;
order
--
)
if
((
db
->
rawbuf
=
dma_alloc
(
PAGE_SIZE
<<
order
,
&
db
->
dmaaddr
)))
break
;
if
(
!
db
->
rawbuf
)
return
-
ENOMEM
;
db
->
buforder
=
order
;
/* now mark the pages as reserved;
otherwise remap_page_range doesn't do what we want */
pend
=
virt_to_page
(
db
->
rawbuf
+
(
PAGE_SIZE
<<
db
->
buforder
)
-
1
);
for
(
page
=
virt_to_page
(
db
->
rawbuf
);
page
<=
pend
;
page
++
)
mem_map_reserve
(
page
);
}
db
->
cnt_factor
=
1
;
if
(
db
->
sample_size
==
8
)
db
->
cnt_factor
*=
2
;
if
(
db
->
num_channels
==
1
)
db
->
cnt_factor
*=
2
;
db
->
cnt_factor
*=
db
->
src_factor
;
db
->
count
=
0
;
db
->
nextIn
=
db
->
nextOut
=
db
->
rawbuf
;
db
->
user_bytes_per_sample
=
(
db
->
sample_size
>>
3
)
*
db
->
num_channels
;
db
->
dma_bytes_per_sample
=
2
*
((
db
->
num_channels
==
1
)
?
2
:
db
->
num_channels
);
user_bytes_per_sec
=
rate
*
db
->
user_bytes_per_sample
;
bufs
=
PAGE_SIZE
<<
db
->
buforder
;
if
(
db
->
ossfragshift
)
{
if
((
1000
<<
db
->
ossfragshift
)
<
user_bytes_per_sec
)
db
->
fragshift
=
ld2
(
user_bytes_per_sec
/
1000
);
else
db
->
fragshift
=
db
->
ossfragshift
;
}
else
{
db
->
fragshift
=
ld2
(
user_bytes_per_sec
/
100
/
(
db
->
subdivision
?
db
->
subdivision
:
1
));
if
(
db
->
fragshift
<
3
)
db
->
fragshift
=
3
;
}
db
->
fragsize
=
1
<<
db
->
fragshift
;
db
->
dma_fragsize
=
db
->
fragsize
*
db
->
cnt_factor
;
db
->
numfrag
=
bufs
/
db
->
dma_fragsize
;
while
(
db
->
numfrag
<
4
&&
db
->
fragshift
>
3
)
{
db
->
fragshift
--
;
db
->
fragsize
=
1
<<
db
->
fragshift
;
db
->
dma_fragsize
=
db
->
fragsize
*
db
->
cnt_factor
;
db
->
numfrag
=
bufs
/
db
->
dma_fragsize
;
}
if
(
db
->
ossmaxfrags
>=
4
&&
db
->
ossmaxfrags
<
db
->
numfrag
)
db
->
numfrag
=
db
->
ossmaxfrags
;
db
->
dmasize
=
db
->
dma_fragsize
*
db
->
numfrag
;
memset
(
db
->
rawbuf
,
0
,
bufs
);
#ifdef AU1000_VERBOSE_DEBUG
dbg
(
"rate=%d, samplesize=%d, channels=%d"
,
rate
,
db
->
sample_size
,
db
->
num_channels
);
dbg
(
"fragsize=%d, cnt_factor=%d, dma_fragsize=%d"
,
db
->
fragsize
,
db
->
cnt_factor
,
db
->
dma_fragsize
);
dbg
(
"numfrag=%d, dmasize=%d"
,
db
->
numfrag
,
db
->
dmasize
);
#endif
db
->
ready
=
1
;
return
0
;
}
extern
inline
int
prog_dmabuf_adc
(
struct
au1000_state
*
s
)
{
stop_adc
(
s
);
return
prog_dmabuf
(
s
,
&
s
->
dma_adc
);
}
extern
inline
int
prog_dmabuf_dac
(
struct
au1000_state
*
s
)
{
stop_dac
(
s
);
return
prog_dmabuf
(
s
,
&
s
->
dma_dac
);
}
/* hold spinlock for the following */
static
void
dac_dma_interrupt
(
int
irq
,
void
*
dev_id
,
struct
pt_regs
*
regs
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
dev_id
;
struct
dmabuf
*
dac
=
&
s
->
dma_dac
;
unsigned
long
newptr
;
u32
ac97c_stat
,
buff_done
;
ac97c_stat
=
au_readl
(
AC97C_STATUS
);
#ifdef AU1000_VERBOSE_DEBUG
if
(
ac97c_stat
&
(
AC97C_XU
|
AC97C_XO
|
AC97C_TE
))
dbg
(
"AC97C status = 0x%08x"
,
ac97c_stat
);
#endif
if
((
buff_done
=
get_dma_buffer_done
(
dac
->
dmanr
))
==
0
)
{
/* fastpath out, to ease interrupt sharing */
return
;
}
spin_lock
(
&
s
->
lock
);
if
(
buff_done
!=
(
DMA_D0
|
DMA_D1
))
{
dac
->
nextOut
+=
dac
->
dma_fragsize
;
if
(
dac
->
nextOut
>=
dac
->
rawbuf
+
dac
->
dmasize
)
dac
->
nextOut
-=
dac
->
dmasize
;
/* update playback pointers */
newptr
=
virt_to_phys
(
dac
->
nextOut
)
+
dac
->
dma_fragsize
;
if
(
newptr
>=
dac
->
dmaaddr
+
dac
->
dmasize
)
newptr
-=
dac
->
dmasize
;
dac
->
count
-=
dac
->
dma_fragsize
;
dac
->
total_bytes
+=
dac
->
dma_fragsize
;
if
(
dac
->
count
<=
0
)
{
#ifdef AU1000_VERBOSE_DEBUG
dbg
(
"dac underrun"
);
#endif
spin_unlock
(
&
s
->
lock
);
stop_dac
(
s
);
spin_lock
(
&
s
->
lock
);
dac
->
count
=
0
;
dac
->
nextIn
=
dac
->
nextOut
;
}
else
if
(
buff_done
==
DMA_D0
)
{
clear_dma_done0
(
dac
->
dmanr
);
// clear DMA done bit
set_dma_count0
(
dac
->
dmanr
,
dac
->
dma_fragsize
>>
1
);
set_dma_addr0
(
dac
->
dmanr
,
newptr
);
enable_dma_buffer0
(
dac
->
dmanr
);
// reenable
}
else
{
clear_dma_done1
(
dac
->
dmanr
);
// clear DMA done bit
set_dma_count1
(
dac
->
dmanr
,
dac
->
dma_fragsize
>>
1
);
set_dma_addr1
(
dac
->
dmanr
,
newptr
);
enable_dma_buffer1
(
dac
->
dmanr
);
// reenable
}
}
else
{
// both done bits set, we missed an interrupt
spin_unlock
(
&
s
->
lock
);
stop_dac
(
s
);
spin_lock
(
&
s
->
lock
);
dac
->
nextOut
+=
2
*
dac
->
dma_fragsize
;
if
(
dac
->
nextOut
>=
dac
->
rawbuf
+
dac
->
dmasize
)
dac
->
nextOut
-=
dac
->
dmasize
;
dac
->
count
-=
2
*
dac
->
dma_fragsize
;
dac
->
total_bytes
+=
2
*
dac
->
dma_fragsize
;
if
(
dac
->
count
>
0
)
{
spin_unlock
(
&
s
->
lock
);
start_dac
(
s
);
spin_lock
(
&
s
->
lock
);
}
}
/* wake up anybody listening */
if
(
waitqueue_active
(
&
dac
->
wait
))
wake_up
(
&
dac
->
wait
);
spin_unlock
(
&
s
->
lock
);
}
static
void
adc_dma_interrupt
(
int
irq
,
void
*
dev_id
,
struct
pt_regs
*
regs
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
dev_id
;
struct
dmabuf
*
adc
=
&
s
->
dma_adc
;
unsigned
long
newptr
;
u32
ac97c_stat
,
buff_done
;
ac97c_stat
=
au_readl
(
AC97C_STATUS
);
#ifdef AU1000_VERBOSE_DEBUG
if
(
ac97c_stat
&
(
AC97C_RU
|
AC97C_RO
))
dbg
(
"AC97C status = 0x%08x"
,
ac97c_stat
);
#endif
if
((
buff_done
=
get_dma_buffer_done
(
adc
->
dmanr
))
==
0
)
{
/* fastpath out, to ease interrupt sharing */
return
;
}
spin_lock
(
&
s
->
lock
);
if
(
buff_done
!=
(
DMA_D0
|
DMA_D1
))
{
if
(
adc
->
count
+
adc
->
dma_fragsize
>
adc
->
dmasize
)
{
// Overrun. Stop ADC and log the error
spin_unlock
(
&
s
->
lock
);
stop_adc
(
s
);
adc
->
error
++
;
err
(
"adc overrun"
);
return
;
}
adc
->
nextIn
+=
adc
->
dma_fragsize
;
if
(
adc
->
nextIn
>=
adc
->
rawbuf
+
adc
->
dmasize
)
adc
->
nextIn
-=
adc
->
dmasize
;
/* update capture pointers */
newptr
=
virt_to_phys
(
adc
->
nextIn
)
+
adc
->
dma_fragsize
;
if
(
newptr
>=
adc
->
dmaaddr
+
adc
->
dmasize
)
newptr
-=
adc
->
dmasize
;
adc
->
count
+=
adc
->
dma_fragsize
;
adc
->
total_bytes
+=
adc
->
dma_fragsize
;
if
(
buff_done
==
DMA_D0
)
{
clear_dma_done0
(
adc
->
dmanr
);
// clear DMA done bit
set_dma_count0
(
adc
->
dmanr
,
adc
->
dma_fragsize
>>
1
);
set_dma_addr0
(
adc
->
dmanr
,
newptr
);
enable_dma_buffer0
(
adc
->
dmanr
);
// reenable
}
else
{
clear_dma_done1
(
adc
->
dmanr
);
// clear DMA done bit
set_dma_count1
(
adc
->
dmanr
,
adc
->
dma_fragsize
>>
1
);
set_dma_addr1
(
adc
->
dmanr
,
newptr
);
enable_dma_buffer1
(
adc
->
dmanr
);
// reenable
}
}
else
{
// both done bits set, we missed an interrupt
spin_unlock
(
&
s
->
lock
);
stop_adc
(
s
);
spin_lock
(
&
s
->
lock
);
if
(
adc
->
count
+
2
*
adc
->
dma_fragsize
>
adc
->
dmasize
)
{
// Overrun. Log the error
adc
->
error
++
;
err
(
"adc overrun"
);
spin_unlock
(
&
s
->
lock
);
return
;
}
adc
->
nextIn
+=
2
*
adc
->
dma_fragsize
;
if
(
adc
->
nextIn
>=
adc
->
rawbuf
+
adc
->
dmasize
)
adc
->
nextIn
-=
adc
->
dmasize
;
adc
->
count
+=
2
*
adc
->
dma_fragsize
;
adc
->
total_bytes
+=
2
*
adc
->
dma_fragsize
;
spin_unlock
(
&
s
->
lock
);
start_adc
(
s
);
spin_lock
(
&
s
->
lock
);
}
/* wake up anybody listening */
if
(
waitqueue_active
(
&
adc
->
wait
))
wake_up
(
&
adc
->
wait
);
spin_unlock
(
&
s
->
lock
);
}
/* --------------------------------------------------------------------- */
static
loff_t
au1000_llseek
(
struct
file
*
file
,
loff_t
offset
,
int
origin
)
{
return
-
ESPIPE
;
}
static
int
au1000_open_mixdev
(
struct
inode
*
inode
,
struct
file
*
file
)
{
file
->
private_data
=
&
au1000_state
;
return
0
;
}
static
int
au1000_release_mixdev
(
struct
inode
*
inode
,
struct
file
*
file
)
{
return
0
;
}
static
int
mixdev_ioctl
(
struct
ac97_codec
*
codec
,
unsigned
int
cmd
,
unsigned
long
arg
)
{
return
codec
->
mixer_ioctl
(
codec
,
cmd
,
arg
);
}
static
int
au1000_ioctl_mixdev
(
struct
inode
*
inode
,
struct
file
*
file
,
unsigned
int
cmd
,
unsigned
long
arg
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
file
->
private_data
;
struct
ac97_codec
*
codec
=
s
->
codec
;
return
mixdev_ioctl
(
codec
,
cmd
,
arg
);
}
static
/*const */
struct
file_operations
au1000_mixer_fops
=
{
owner:
THIS_MODULE
,
llseek:
au1000_llseek
,
ioctl:
au1000_ioctl_mixdev
,
open:
au1000_open_mixdev
,
release:
au1000_release_mixdev
,
};
/* --------------------------------------------------------------------- */
static
int
drain_dac
(
struct
au1000_state
*
s
,
int
nonblock
)
{
unsigned
long
flags
;
int
count
,
tmo
;
if
(
s
->
dma_dac
.
mapped
||
!
s
->
dma_dac
.
ready
||
s
->
dma_dac
.
stopped
)
return
0
;
for
(;;)
{
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
count
=
s
->
dma_dac
.
count
;
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
if
(
count
<=
0
)
break
;
if
(
signal_pending
(
current
))
break
;
if
(
nonblock
)
return
-
EBUSY
;
tmo
=
1000
*
count
/
(
s
->
no_vra
?
48000
:
s
->
dma_dac
.
sample_rate
);
tmo
/=
s
->
dma_dac
.
dma_bytes_per_sample
;
au1000_delay
(
tmo
);
}
if
(
signal_pending
(
current
))
return
-
ERESTARTSYS
;
return
0
;
}
/* --------------------------------------------------------------------- */
static
inline
u8
S16_TO_U8
(
s16
ch
)
{
return
(
u8
)
(
ch
>>
8
)
+
0x80
;
}
static
inline
s16
U8_TO_S16
(
u8
ch
)
{
return
(
s16
)
(
ch
-
0x80
)
<<
8
;
}
/*
* Translates user samples to dma buffer suitable for AC'97 DAC data:
* If mono, copy left channel to right channel in dma buffer.
* If 8 bit samples, cvt to 16-bit before writing to dma buffer.
* If interpolating (no VRA), duplicate every audio frame src_factor times.
*/
static
int
translate_from_user
(
struct
dmabuf
*
db
,
char
*
dmabuf
,
char
*
userbuf
,
int
dmacount
)
{
int
sample
,
i
;
int
interp_bytes_per_sample
;
int
num_samples
;
int
mono
=
(
db
->
num_channels
==
1
);
char
usersample
[
12
];
s16
ch
,
dmasample
[
6
];
if
(
db
->
sample_size
==
16
&&
!
mono
&&
db
->
src_factor
==
1
)
{
// no translation necessary, just copy
if
(
copy_from_user
(
dmabuf
,
userbuf
,
dmacount
))
return
-
EFAULT
;
return
dmacount
;
}
interp_bytes_per_sample
=
db
->
dma_bytes_per_sample
*
db
->
src_factor
;
num_samples
=
dmacount
/
interp_bytes_per_sample
;
for
(
sample
=
0
;
sample
<
num_samples
;
sample
++
)
{
if
(
copy_from_user
(
usersample
,
userbuf
,
db
->
user_bytes_per_sample
))
{
dbg
(
__FUNCTION__
": fault"
);
return
-
EFAULT
;
}
for
(
i
=
0
;
i
<
db
->
num_channels
;
i
++
)
{
if
(
db
->
sample_size
==
8
)
ch
=
U8_TO_S16
(
usersample
[
i
]);
else
ch
=
*
((
s16
*
)
(
&
usersample
[
i
*
2
]));
dmasample
[
i
]
=
ch
;
if
(
mono
)
dmasample
[
i
+
1
]
=
ch
;
// right channel
}
// duplicate every audio frame src_factor times
for
(
i
=
0
;
i
<
db
->
src_factor
;
i
++
)
memcpy
(
dmabuf
,
dmasample
,
db
->
dma_bytes_per_sample
);
userbuf
+=
db
->
user_bytes_per_sample
;
dmabuf
+=
interp_bytes_per_sample
;
}
return
num_samples
*
interp_bytes_per_sample
;
}
/*
* Translates AC'97 ADC samples to user buffer:
* If mono, send only left channel to user buffer.
* If 8 bit samples, cvt from 16 to 8 bit before writing to user buffer.
* If decimating (no VRA), skip over src_factor audio frames.
*/
static
int
translate_to_user
(
struct
dmabuf
*
db
,
char
*
userbuf
,
char
*
dmabuf
,
int
dmacount
)
{
int
sample
,
i
;
int
interp_bytes_per_sample
;
int
num_samples
;
int
mono
=
(
db
->
num_channels
==
1
);
char
usersample
[
12
];
if
(
db
->
sample_size
==
16
&&
!
mono
&&
db
->
src_factor
==
1
)
{
// no translation necessary, just copy
if
(
copy_to_user
(
userbuf
,
dmabuf
,
dmacount
))
return
-
EFAULT
;
return
dmacount
;
}
interp_bytes_per_sample
=
db
->
dma_bytes_per_sample
*
db
->
src_factor
;
num_samples
=
dmacount
/
interp_bytes_per_sample
;
for
(
sample
=
0
;
sample
<
num_samples
;
sample
++
)
{
for
(
i
=
0
;
i
<
db
->
num_channels
;
i
++
)
{
if
(
db
->
sample_size
==
8
)
usersample
[
i
]
=
S16_TO_U8
(
*
((
s16
*
)
(
&
dmabuf
[
i
*
2
])));
else
*
((
s16
*
)
(
&
usersample
[
i
*
2
]))
=
*
((
s16
*
)
(
&
dmabuf
[
i
*
2
]));
}
if
(
copy_to_user
(
userbuf
,
usersample
,
db
->
user_bytes_per_sample
))
{
dbg
(
__FUNCTION__
": fault"
);
return
-
EFAULT
;
}
userbuf
+=
db
->
user_bytes_per_sample
;
dmabuf
+=
interp_bytes_per_sample
;
}
return
num_samples
*
interp_bytes_per_sample
;
}
/*
* Copy audio data to/from user buffer from/to dma buffer, taking care
* that we wrap when reading/writing the dma buffer. Returns actual byte
* count written to or read from the dma buffer.
*/
static
int
copy_dmabuf_user
(
struct
dmabuf
*
db
,
char
*
userbuf
,
int
count
,
int
to_user
)
{
char
*
bufptr
=
to_user
?
db
->
nextOut
:
db
->
nextIn
;
char
*
bufend
=
db
->
rawbuf
+
db
->
dmasize
;
int
cnt
,
ret
;
if
(
bufptr
+
count
>
bufend
)
{
int
partial
=
(
int
)
(
bufend
-
bufptr
);
if
(
to_user
)
{
if
((
cnt
=
translate_to_user
(
db
,
userbuf
,
bufptr
,
partial
))
<
0
)
return
cnt
;
ret
=
cnt
;
if
((
cnt
=
translate_to_user
(
db
,
userbuf
+
partial
,
db
->
rawbuf
,
count
-
partial
))
<
0
)
return
cnt
;
ret
+=
cnt
;
}
else
{
if
((
cnt
=
translate_from_user
(
db
,
bufptr
,
userbuf
,
partial
))
<
0
)
return
cnt
;
ret
=
cnt
;
if
((
cnt
=
translate_from_user
(
db
,
db
->
rawbuf
,
userbuf
+
partial
,
count
-
partial
))
<
0
)
return
cnt
;
ret
+=
cnt
;
}
}
else
{
if
(
to_user
)
ret
=
translate_to_user
(
db
,
userbuf
,
bufptr
,
count
);
else
ret
=
translate_from_user
(
db
,
bufptr
,
userbuf
,
count
);
}
return
ret
;
}
static
ssize_t
au1000_read
(
struct
file
*
file
,
char
*
buffer
,
size_t
count
,
loff_t
*
ppos
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
file
->
private_data
;
struct
dmabuf
*
db
=
&
s
->
dma_adc
;
DECLARE_WAITQUEUE
(
wait
,
current
);
ssize_t
ret
;
unsigned
long
flags
;
int
cnt
,
usercnt
,
avail
;
if
(
ppos
!=
&
file
->
f_pos
)
return
-
ESPIPE
;
if
(
db
->
mapped
)
return
-
ENXIO
;
if
(
!
access_ok
(
VERIFY_WRITE
,
buffer
,
count
))
return
-
EFAULT
;
ret
=
0
;
count
*=
db
->
cnt_factor
;
down
(
&
s
->
sem
);
add_wait_queue
(
&
db
->
wait
,
&
wait
);
while
(
count
>
0
)
{
// wait for samples in ADC dma buffer
do
{
if
(
db
->
stopped
)
start_adc
(
s
);
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
avail
=
db
->
count
;
if
(
avail
<=
0
)
__set_current_state
(
TASK_INTERRUPTIBLE
);
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
if
(
avail
<=
0
)
{
if
(
file
->
f_flags
&
O_NONBLOCK
)
{
if
(
!
ret
)
ret
=
-
EAGAIN
;
goto
out
;
}
up
(
&
s
->
sem
);
schedule
();
if
(
signal_pending
(
current
))
{
if
(
!
ret
)
ret
=
-
ERESTARTSYS
;
goto
out2
;
}
down
(
&
s
->
sem
);
}
}
while
(
avail
<=
0
);
// copy from nextOut to user
if
((
cnt
=
copy_dmabuf_user
(
db
,
buffer
,
count
>
avail
?
avail
:
count
,
1
))
<
0
)
{
if
(
!
ret
)
ret
=
-
EFAULT
;
goto
out
;
}
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
db
->
count
-=
cnt
;
db
->
nextOut
+=
cnt
;
if
(
db
->
nextOut
>=
db
->
rawbuf
+
db
->
dmasize
)
db
->
nextOut
-=
db
->
dmasize
;
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
count
-=
cnt
;
usercnt
=
cnt
/
db
->
cnt_factor
;
buffer
+=
usercnt
;
ret
+=
usercnt
;
}
// while (count > 0)
out:
up
(
&
s
->
sem
);
out2:
remove_wait_queue
(
&
db
->
wait
,
&
wait
);
set_current_state
(
TASK_RUNNING
);
return
ret
;
}
static
ssize_t
au1000_write
(
struct
file
*
file
,
const
char
*
buffer
,
size_t
count
,
loff_t
*
ppos
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
file
->
private_data
;
struct
dmabuf
*
db
=
&
s
->
dma_dac
;
DECLARE_WAITQUEUE
(
wait
,
current
);
ssize_t
ret
=
0
;
unsigned
long
flags
;
int
cnt
,
usercnt
,
avail
;
#ifdef AU1000_VERBOSE_DEBUG
dbg
(
"write: count=%d"
,
count
);
#endif
if
(
ppos
!=
&
file
->
f_pos
)
return
-
ESPIPE
;
if
(
db
->
mapped
)
return
-
ENXIO
;
if
(
!
access_ok
(
VERIFY_READ
,
buffer
,
count
))
return
-
EFAULT
;
count
*=
db
->
cnt_factor
;
down
(
&
s
->
sem
);
add_wait_queue
(
&
db
->
wait
,
&
wait
);
while
(
count
>
0
)
{
// wait for space in playback buffer
do
{
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
avail
=
(
int
)
db
->
dmasize
-
db
->
count
;
if
(
avail
<=
0
)
__set_current_state
(
TASK_INTERRUPTIBLE
);
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
if
(
avail
<=
0
)
{
if
(
file
->
f_flags
&
O_NONBLOCK
)
{
if
(
!
ret
)
ret
=
-
EAGAIN
;
goto
out
;
}
up
(
&
s
->
sem
);
schedule
();
if
(
signal_pending
(
current
))
{
if
(
!
ret
)
ret
=
-
ERESTARTSYS
;
goto
out2
;
}
down
(
&
s
->
sem
);
}
}
while
(
avail
<=
0
);
// copy from user to nextIn
if
((
cnt
=
copy_dmabuf_user
(
db
,
(
char
*
)
buffer
,
count
>
avail
?
avail
:
count
,
0
))
<
0
)
{
if
(
!
ret
)
ret
=
-
EFAULT
;
goto
out
;
}
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
db
->
count
+=
cnt
;
db
->
nextIn
+=
cnt
;
if
(
db
->
nextIn
>=
db
->
rawbuf
+
db
->
dmasize
)
db
->
nextIn
-=
db
->
dmasize
;
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
if
(
db
->
stopped
)
start_dac
(
s
);
count
-=
cnt
;
usercnt
=
cnt
/
db
->
cnt_factor
;
buffer
+=
usercnt
;
ret
+=
usercnt
;
}
// while (count > 0)
out:
up
(
&
s
->
sem
);
out2:
remove_wait_queue
(
&
db
->
wait
,
&
wait
);
set_current_state
(
TASK_RUNNING
);
return
ret
;
}
/* No kernel lock - we have our own spinlock */
static
unsigned
int
au1000_poll
(
struct
file
*
file
,
struct
poll_table_struct
*
wait
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
file
->
private_data
;
unsigned
long
flags
;
unsigned
int
mask
=
0
;
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
if
(
!
s
->
dma_dac
.
ready
)
return
0
;
poll_wait
(
file
,
&
s
->
dma_dac
.
wait
,
wait
);
}
if
(
file
->
f_mode
&
FMODE_READ
)
{
if
(
!
s
->
dma_adc
.
ready
)
return
0
;
poll_wait
(
file
,
&
s
->
dma_adc
.
wait
,
wait
);
}
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
if
(
file
->
f_mode
&
FMODE_READ
)
{
if
(
s
->
dma_adc
.
count
>=
(
signed
)
s
->
dma_adc
.
dma_fragsize
)
mask
|=
POLLIN
|
POLLRDNORM
;
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
if
(
s
->
dma_dac
.
mapped
)
{
if
(
s
->
dma_dac
.
count
>=
(
signed
)
s
->
dma_dac
.
dma_fragsize
)
mask
|=
POLLOUT
|
POLLWRNORM
;
}
else
{
if
((
signed
)
s
->
dma_dac
.
dmasize
>=
s
->
dma_dac
.
count
+
(
signed
)
s
->
dma_dac
.
dma_fragsize
)
mask
|=
POLLOUT
|
POLLWRNORM
;
}
}
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
return
mask
;
}
static
int
au1000_mmap
(
struct
file
*
file
,
struct
vm_area_struct
*
vma
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
file
->
private_data
;
struct
dmabuf
*
db
;
unsigned
long
size
;
int
ret
=
0
;
dbg
(
__FUNCTION__
);
lock_kernel
();
down
(
&
s
->
sem
);
if
(
vma
->
vm_flags
&
VM_WRITE
)
db
=
&
s
->
dma_dac
;
else
if
(
vma
->
vm_flags
&
VM_READ
)
db
=
&
s
->
dma_adc
;
else
{
ret
=
-
EINVAL
;
goto
out
;
}
if
(
vma
->
vm_pgoff
!=
0
)
{
ret
=
-
EINVAL
;
goto
out
;
}
size
=
vma
->
vm_end
-
vma
->
vm_start
;
if
(
size
>
(
PAGE_SIZE
<<
db
->
buforder
))
{
ret
=
-
EINVAL
;
goto
out
;
}
if
(
remap_page_range
(
vma
->
vm_start
,
virt_to_phys
(
db
->
rawbuf
),
size
,
vma
->
vm_page_prot
))
{
ret
=
-
EAGAIN
;
goto
out
;
}
vma
->
vm_flags
&=
~
VM_IO
;
db
->
mapped
=
1
;
out:
up
(
&
s
->
sem
);
unlock_kernel
();
return
ret
;
}
#ifdef AU1000_VERBOSE_DEBUG
static
struct
ioctl_str_t
{
unsigned
int
cmd
;
const
char
*
str
;
}
ioctl_str
[]
=
{
{
SNDCTL_DSP_RESET
,
"SNDCTL_DSP_RESET"
},
{
SNDCTL_DSP_SYNC
,
"SNDCTL_DSP_SYNC"
},
{
SNDCTL_DSP_SPEED
,
"SNDCTL_DSP_SPEED"
},
{
SNDCTL_DSP_STEREO
,
"SNDCTL_DSP_STEREO"
},
{
SNDCTL_DSP_GETBLKSIZE
,
"SNDCTL_DSP_GETBLKSIZE"
},
{
SNDCTL_DSP_SAMPLESIZE
,
"SNDCTL_DSP_SAMPLESIZE"
},
{
SNDCTL_DSP_CHANNELS
,
"SNDCTL_DSP_CHANNELS"
},
{
SOUND_PCM_WRITE_CHANNELS
,
"SOUND_PCM_WRITE_CHANNELS"
},
{
SOUND_PCM_WRITE_FILTER
,
"SOUND_PCM_WRITE_FILTER"
},
{
SNDCTL_DSP_POST
,
"SNDCTL_DSP_POST"
},
{
SNDCTL_DSP_SUBDIVIDE
,
"SNDCTL_DSP_SUBDIVIDE"
},
{
SNDCTL_DSP_SETFRAGMENT
,
"SNDCTL_DSP_SETFRAGMENT"
},
{
SNDCTL_DSP_GETFMTS
,
"SNDCTL_DSP_GETFMTS"
},
{
SNDCTL_DSP_SETFMT
,
"SNDCTL_DSP_SETFMT"
},
{
SNDCTL_DSP_GETOSPACE
,
"SNDCTL_DSP_GETOSPACE"
},
{
SNDCTL_DSP_GETISPACE
,
"SNDCTL_DSP_GETISPACE"
},
{
SNDCTL_DSP_NONBLOCK
,
"SNDCTL_DSP_NONBLOCK"
},
{
SNDCTL_DSP_GETCAPS
,
"SNDCTL_DSP_GETCAPS"
},
{
SNDCTL_DSP_GETTRIGGER
,
"SNDCTL_DSP_GETTRIGGER"
},
{
SNDCTL_DSP_SETTRIGGER
,
"SNDCTL_DSP_SETTRIGGER"
},
{
SNDCTL_DSP_GETIPTR
,
"SNDCTL_DSP_GETIPTR"
},
{
SNDCTL_DSP_GETOPTR
,
"SNDCTL_DSP_GETOPTR"
},
{
SNDCTL_DSP_MAPINBUF
,
"SNDCTL_DSP_MAPINBUF"
},
{
SNDCTL_DSP_MAPOUTBUF
,
"SNDCTL_DSP_MAPOUTBUF"
},
{
SNDCTL_DSP_SETSYNCRO
,
"SNDCTL_DSP_SETSYNCRO"
},
{
SNDCTL_DSP_SETDUPLEX
,
"SNDCTL_DSP_SETDUPLEX"
},
{
SNDCTL_DSP_GETODELAY
,
"SNDCTL_DSP_GETODELAY"
},
{
SNDCTL_DSP_GETCHANNELMASK
,
"SNDCTL_DSP_GETCHANNELMASK"
},
{
SNDCTL_DSP_BIND_CHANNEL
,
"SNDCTL_DSP_BIND_CHANNEL"
},
{
OSS_GETVERSION
,
"OSS_GETVERSION"
},
{
SOUND_PCM_READ_RATE
,
"SOUND_PCM_READ_RATE"
},
{
SOUND_PCM_READ_CHANNELS
,
"SOUND_PCM_READ_CHANNELS"
},
{
SOUND_PCM_READ_BITS
,
"SOUND_PCM_READ_BITS"
},
{
SOUND_PCM_READ_FILTER
,
"SOUND_PCM_READ_FILTER"
}
};
#endif
// Need to hold a spin-lock before calling this!
static
int
dma_count_done
(
struct
dmabuf
*
db
)
{
if
(
db
->
stopped
)
return
0
;
return
db
->
dma_fragsize
-
get_dma_residue
(
db
->
dmanr
);
}
static
int
au1000_ioctl
(
struct
inode
*
inode
,
struct
file
*
file
,
unsigned
int
cmd
,
unsigned
long
arg
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
file
->
private_data
;
unsigned
long
flags
;
audio_buf_info
abinfo
;
count_info
cinfo
;
int
count
;
int
val
,
mapped
,
ret
,
diff
;
mapped
=
((
file
->
f_mode
&
FMODE_WRITE
)
&&
s
->
dma_dac
.
mapped
)
||
((
file
->
f_mode
&
FMODE_READ
)
&&
s
->
dma_adc
.
mapped
);
#ifdef AU1000_VERBOSE_DEBUG
for
(
count
=
0
;
count
<
sizeof
(
ioctl_str
)
/
sizeof
(
ioctl_str
[
0
]);
count
++
)
{
if
(
ioctl_str
[
count
].
cmd
==
cmd
)
break
;
}
if
(
count
<
sizeof
(
ioctl_str
)
/
sizeof
(
ioctl_str
[
0
]))
dbg
(
"ioctl %s, arg=0x%lx"
,
ioctl_str
[
count
].
str
,
arg
);
else
dbg
(
"ioctl 0x%x unknown, arg=0x%lx"
,
cmd
,
arg
);
#endif
switch
(
cmd
)
{
case
OSS_GETVERSION
:
return
put_user
(
SOUND_VERSION
,
(
int
*
)
arg
);
case
SNDCTL_DSP_SYNC
:
if
(
file
->
f_mode
&
FMODE_WRITE
)
return
drain_dac
(
s
,
file
->
f_flags
&
O_NONBLOCK
);
return
0
;
case
SNDCTL_DSP_SETDUPLEX
:
return
0
;
case
SNDCTL_DSP_GETCAPS
:
return
put_user
(
DSP_CAP_DUPLEX
|
DSP_CAP_REALTIME
|
DSP_CAP_TRIGGER
|
DSP_CAP_MMAP
,
(
int
*
)
arg
);
case
SNDCTL_DSP_RESET
:
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
stop_dac
(
s
);
synchronize_irq
();
s
->
dma_dac
.
count
=
s
->
dma_dac
.
total_bytes
=
0
;
s
->
dma_dac
.
nextIn
=
s
->
dma_dac
.
nextOut
=
s
->
dma_dac
.
rawbuf
;
}
if
(
file
->
f_mode
&
FMODE_READ
)
{
stop_adc
(
s
);
synchronize_irq
();
s
->
dma_adc
.
count
=
s
->
dma_adc
.
total_bytes
=
0
;
s
->
dma_adc
.
nextIn
=
s
->
dma_adc
.
nextOut
=
s
->
dma_adc
.
rawbuf
;
}
return
0
;
case
SNDCTL_DSP_SPEED
:
if
(
get_user
(
val
,
(
int
*
)
arg
))
return
-
EFAULT
;
if
(
val
>=
0
)
{
if
(
file
->
f_mode
&
FMODE_READ
)
{
stop_adc
(
s
);
set_adc_rate
(
s
,
val
);
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
stop_dac
(
s
);
set_dac_rate
(
s
,
val
);
}
if
(
s
->
open_mode
&
FMODE_READ
)
if
((
ret
=
prog_dmabuf_adc
(
s
)))
return
ret
;
if
(
s
->
open_mode
&
FMODE_WRITE
)
if
((
ret
=
prog_dmabuf_dac
(
s
)))
return
ret
;
}
return
put_user
((
file
->
f_mode
&
FMODE_READ
)
?
s
->
dma_adc
.
sample_rate
:
s
->
dma_dac
.
sample_rate
,
(
int
*
)
arg
);
case
SNDCTL_DSP_STEREO
:
if
(
get_user
(
val
,
(
int
*
)
arg
))
return
-
EFAULT
;
if
(
file
->
f_mode
&
FMODE_READ
)
{
stop_adc
(
s
);
s
->
dma_adc
.
num_channels
=
val
?
2
:
1
;
if
((
ret
=
prog_dmabuf_adc
(
s
)))
return
ret
;
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
stop_dac
(
s
);
s
->
dma_dac
.
num_channels
=
val
?
2
:
1
;
if
(
s
->
codec_ext_caps
&
AC97_EXT_DACS
)
{
// disable surround and center/lfe in AC'97
u16
ext_stat
=
rdcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
);
wrcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
,
ext_stat
|
(
AC97_EXTSTAT_PRI
|
AC97_EXTSTAT_PRJ
|
AC97_EXTSTAT_PRK
));
}
if
((
ret
=
prog_dmabuf_dac
(
s
)))
return
ret
;
}
return
0
;
case
SNDCTL_DSP_CHANNELS
:
if
(
get_user
(
val
,
(
int
*
)
arg
))
return
-
EFAULT
;
if
(
val
!=
0
)
{
if
(
file
->
f_mode
&
FMODE_READ
)
{
if
(
val
<
0
||
val
>
2
)
return
-
EINVAL
;
stop_adc
(
s
);
s
->
dma_adc
.
num_channels
=
val
;
if
((
ret
=
prog_dmabuf_adc
(
s
)))
return
ret
;
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
switch
(
val
)
{
case
1
:
case
2
:
break
;
case
3
:
case
5
:
return
-
EINVAL
;
case
4
:
if
(
!
(
s
->
codec_ext_caps
&
AC97_EXTID_SDAC
))
return
-
EINVAL
;
break
;
case
6
:
if
((
s
->
codec_ext_caps
&
AC97_EXT_DACS
)
!=
AC97_EXT_DACS
)
return
-
EINVAL
;
break
;
default:
return
-
EINVAL
;
}
stop_dac
(
s
);
if
(
val
<=
2
&&
(
s
->
codec_ext_caps
&
AC97_EXT_DACS
))
{
// disable surround and center/lfe
// channels in AC'97
u16
ext_stat
=
rdcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
);
wrcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
,
ext_stat
|
(
AC97_EXTSTAT_PRI
|
AC97_EXTSTAT_PRJ
|
AC97_EXTSTAT_PRK
));
}
else
if
(
val
>=
4
)
{
// enable surround, center/lfe
// channels in AC'97
u16
ext_stat
=
rdcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
);
ext_stat
&=
~
AC97_EXTSTAT_PRJ
;
if
(
val
==
6
)
ext_stat
&=
~
(
AC97_EXTSTAT_PRI
|
AC97_EXTSTAT_PRK
);
wrcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
,
ext_stat
);
}
s
->
dma_dac
.
num_channels
=
val
;
if
((
ret
=
prog_dmabuf_dac
(
s
)))
return
ret
;
}
}
return
put_user
(
val
,
(
int
*
)
arg
);
case
SNDCTL_DSP_GETFMTS
:
/* Returns a mask */
return
put_user
(
AFMT_S16_LE
|
AFMT_U8
,
(
int
*
)
arg
);
case
SNDCTL_DSP_SETFMT
:
/* Selects ONE fmt */
if
(
get_user
(
val
,
(
int
*
)
arg
))
return
-
EFAULT
;
if
(
val
!=
AFMT_QUERY
)
{
if
(
file
->
f_mode
&
FMODE_READ
)
{
stop_adc
(
s
);
if
(
val
==
AFMT_S16_LE
)
s
->
dma_adc
.
sample_size
=
16
;
else
{
val
=
AFMT_U8
;
s
->
dma_adc
.
sample_size
=
8
;
}
if
((
ret
=
prog_dmabuf_adc
(
s
)))
return
ret
;
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
stop_dac
(
s
);
if
(
val
==
AFMT_S16_LE
)
s
->
dma_dac
.
sample_size
=
16
;
else
{
val
=
AFMT_U8
;
s
->
dma_dac
.
sample_size
=
8
;
}
if
((
ret
=
prog_dmabuf_dac
(
s
)))
return
ret
;
}
}
else
{
if
(
file
->
f_mode
&
FMODE_READ
)
val
=
(
s
->
dma_adc
.
sample_size
==
16
)
?
AFMT_S16_LE
:
AFMT_U8
;
else
val
=
(
s
->
dma_dac
.
sample_size
==
16
)
?
AFMT_S16_LE
:
AFMT_U8
;
}
return
put_user
(
val
,
(
int
*
)
arg
);
case
SNDCTL_DSP_POST
:
return
0
;
case
SNDCTL_DSP_GETTRIGGER
:
val
=
0
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
if
(
file
->
f_mode
&
FMODE_READ
&&
!
s
->
dma_adc
.
stopped
)
val
|=
PCM_ENABLE_INPUT
;
if
(
file
->
f_mode
&
FMODE_WRITE
&&
!
s
->
dma_dac
.
stopped
)
val
|=
PCM_ENABLE_OUTPUT
;
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
return
put_user
(
val
,
(
int
*
)
arg
);
case
SNDCTL_DSP_SETTRIGGER
:
if
(
get_user
(
val
,
(
int
*
)
arg
))
return
-
EFAULT
;
if
(
file
->
f_mode
&
FMODE_READ
)
{
if
(
val
&
PCM_ENABLE_INPUT
)
start_adc
(
s
);
else
stop_adc
(
s
);
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
if
(
val
&
PCM_ENABLE_OUTPUT
)
start_dac
(
s
);
else
stop_dac
(
s
);
}
return
0
;
case
SNDCTL_DSP_GETOSPACE
:
if
(
!
(
file
->
f_mode
&
FMODE_WRITE
))
return
-
EINVAL
;
abinfo
.
fragsize
=
s
->
dma_dac
.
fragsize
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
count
=
s
->
dma_dac
.
count
;
count
-=
dma_count_done
(
&
s
->
dma_dac
);
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
if
(
count
<
0
)
count
=
0
;
abinfo
.
bytes
=
(
s
->
dma_dac
.
dmasize
-
count
)
/
s
->
dma_dac
.
cnt_factor
;
abinfo
.
fragstotal
=
s
->
dma_dac
.
numfrag
;
abinfo
.
fragments
=
abinfo
.
bytes
>>
s
->
dma_dac
.
fragshift
;
#ifdef AU1000_VERBOSE_DEBUG
dbg
(
"bytes=%d, fragments=%d"
,
abinfo
.
bytes
,
abinfo
.
fragments
);
#endif
return
copy_to_user
((
void
*
)
arg
,
&
abinfo
,
sizeof
(
abinfo
))
?
-
EFAULT
:
0
;
case
SNDCTL_DSP_GETISPACE
:
if
(
!
(
file
->
f_mode
&
FMODE_READ
))
return
-
EINVAL
;
abinfo
.
fragsize
=
s
->
dma_adc
.
fragsize
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
count
=
s
->
dma_adc
.
count
;
count
+=
dma_count_done
(
&
s
->
dma_adc
);
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
if
(
count
<
0
)
count
=
0
;
abinfo
.
bytes
=
count
/
s
->
dma_adc
.
cnt_factor
;
abinfo
.
fragstotal
=
s
->
dma_adc
.
numfrag
;
abinfo
.
fragments
=
abinfo
.
bytes
>>
s
->
dma_adc
.
fragshift
;
return
copy_to_user
((
void
*
)
arg
,
&
abinfo
,
sizeof
(
abinfo
))
?
-
EFAULT
:
0
;
case
SNDCTL_DSP_NONBLOCK
:
file
->
f_flags
|=
O_NONBLOCK
;
return
0
;
case
SNDCTL_DSP_GETODELAY
:
if
(
!
(
file
->
f_mode
&
FMODE_WRITE
))
return
-
EINVAL
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
count
=
s
->
dma_dac
.
count
;
count
-=
dma_count_done
(
&
s
->
dma_dac
);
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
if
(
count
<
0
)
count
=
0
;
count
/=
s
->
dma_dac
.
cnt_factor
;
return
put_user
(
count
,
(
int
*
)
arg
);
case
SNDCTL_DSP_GETIPTR
:
if
(
!
(
file
->
f_mode
&
FMODE_READ
))
return
-
EINVAL
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
cinfo
.
bytes
=
s
->
dma_adc
.
total_bytes
;
count
=
s
->
dma_adc
.
count
;
if
(
!
s
->
dma_adc
.
stopped
)
{
diff
=
dma_count_done
(
&
s
->
dma_adc
);
count
+=
diff
;
cinfo
.
bytes
+=
diff
;
cinfo
.
ptr
=
virt_to_phys
(
s
->
dma_adc
.
nextIn
)
+
diff
-
s
->
dma_adc
.
dmaaddr
;
}
else
cinfo
.
ptr
=
virt_to_phys
(
s
->
dma_adc
.
nextIn
)
-
s
->
dma_adc
.
dmaaddr
;
if
(
s
->
dma_adc
.
mapped
)
s
->
dma_adc
.
count
&=
(
s
->
dma_adc
.
dma_fragsize
-
1
);
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
if
(
count
<
0
)
count
=
0
;
cinfo
.
blocks
=
count
>>
s
->
dma_adc
.
fragshift
;
return
copy_to_user
((
void
*
)
arg
,
&
cinfo
,
sizeof
(
cinfo
));
case
SNDCTL_DSP_GETOPTR
:
if
(
!
(
file
->
f_mode
&
FMODE_READ
))
return
-
EINVAL
;
spin_lock_irqsave
(
&
s
->
lock
,
flags
);
cinfo
.
bytes
=
s
->
dma_dac
.
total_bytes
;
count
=
s
->
dma_dac
.
count
;
if
(
!
s
->
dma_dac
.
stopped
)
{
diff
=
dma_count_done
(
&
s
->
dma_dac
);
count
-=
diff
;
cinfo
.
bytes
+=
diff
;
cinfo
.
ptr
=
virt_to_phys
(
s
->
dma_dac
.
nextOut
)
+
diff
-
s
->
dma_dac
.
dmaaddr
;
}
else
cinfo
.
ptr
=
virt_to_phys
(
s
->
dma_dac
.
nextOut
)
-
s
->
dma_dac
.
dmaaddr
;
if
(
s
->
dma_dac
.
mapped
)
s
->
dma_dac
.
count
&=
(
s
->
dma_dac
.
dma_fragsize
-
1
);
spin_unlock_irqrestore
(
&
s
->
lock
,
flags
);
if
(
count
<
0
)
count
=
0
;
cinfo
.
blocks
=
count
>>
s
->
dma_dac
.
fragshift
;
return
copy_to_user
((
void
*
)
arg
,
&
cinfo
,
sizeof
(
cinfo
));
case
SNDCTL_DSP_GETBLKSIZE
:
if
(
file
->
f_mode
&
FMODE_WRITE
)
return
put_user
(
s
->
dma_dac
.
fragsize
,
(
int
*
)
arg
);
else
return
put_user
(
s
->
dma_adc
.
fragsize
,
(
int
*
)
arg
);
case
SNDCTL_DSP_SETFRAGMENT
:
if
(
get_user
(
val
,
(
int
*
)
arg
))
return
-
EFAULT
;
if
(
file
->
f_mode
&
FMODE_READ
)
{
stop_adc
(
s
);
s
->
dma_adc
.
ossfragshift
=
val
&
0xffff
;
s
->
dma_adc
.
ossmaxfrags
=
(
val
>>
16
)
&
0xffff
;
if
(
s
->
dma_adc
.
ossfragshift
<
4
)
s
->
dma_adc
.
ossfragshift
=
4
;
if
(
s
->
dma_adc
.
ossfragshift
>
15
)
s
->
dma_adc
.
ossfragshift
=
15
;
if
(
s
->
dma_adc
.
ossmaxfrags
<
4
)
s
->
dma_adc
.
ossmaxfrags
=
4
;
if
((
ret
=
prog_dmabuf_adc
(
s
)))
return
ret
;
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
stop_dac
(
s
);
s
->
dma_dac
.
ossfragshift
=
val
&
0xffff
;
s
->
dma_dac
.
ossmaxfrags
=
(
val
>>
16
)
&
0xffff
;
if
(
s
->
dma_dac
.
ossfragshift
<
4
)
s
->
dma_dac
.
ossfragshift
=
4
;
if
(
s
->
dma_dac
.
ossfragshift
>
15
)
s
->
dma_dac
.
ossfragshift
=
15
;
if
(
s
->
dma_dac
.
ossmaxfrags
<
4
)
s
->
dma_dac
.
ossmaxfrags
=
4
;
if
((
ret
=
prog_dmabuf_dac
(
s
)))
return
ret
;
}
return
0
;
case
SNDCTL_DSP_SUBDIVIDE
:
if
((
file
->
f_mode
&
FMODE_READ
&&
s
->
dma_adc
.
subdivision
)
||
(
file
->
f_mode
&
FMODE_WRITE
&&
s
->
dma_dac
.
subdivision
))
return
-
EINVAL
;
if
(
get_user
(
val
,
(
int
*
)
arg
))
return
-
EFAULT
;
if
(
val
!=
1
&&
val
!=
2
&&
val
!=
4
)
return
-
EINVAL
;
if
(
file
->
f_mode
&
FMODE_READ
)
{
stop_adc
(
s
);
s
->
dma_adc
.
subdivision
=
val
;
if
((
ret
=
prog_dmabuf_adc
(
s
)))
return
ret
;
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
stop_dac
(
s
);
s
->
dma_dac
.
subdivision
=
val
;
if
((
ret
=
prog_dmabuf_dac
(
s
)))
return
ret
;
}
return
0
;
case
SOUND_PCM_READ_RATE
:
return
put_user
((
file
->
f_mode
&
FMODE_READ
)
?
s
->
dma_adc
.
sample_rate
:
s
->
dma_dac
.
sample_rate
,
(
int
*
)
arg
);
case
SOUND_PCM_READ_CHANNELS
:
if
(
file
->
f_mode
&
FMODE_READ
)
return
put_user
(
s
->
dma_adc
.
num_channels
,
(
int
*
)
arg
);
else
return
put_user
(
s
->
dma_dac
.
num_channels
,
(
int
*
)
arg
);
case
SOUND_PCM_READ_BITS
:
if
(
file
->
f_mode
&
FMODE_READ
)
return
put_user
(
s
->
dma_adc
.
sample_size
,
(
int
*
)
arg
);
else
return
put_user
(
s
->
dma_dac
.
sample_size
,
(
int
*
)
arg
);
case
SOUND_PCM_WRITE_FILTER
:
case
SNDCTL_DSP_SETSYNCRO
:
case
SOUND_PCM_READ_FILTER
:
return
-
EINVAL
;
}
return
mixdev_ioctl
(
s
->
codec
,
cmd
,
arg
);
}
static
int
au1000_open
(
struct
inode
*
inode
,
struct
file
*
file
)
{
int
minor
=
MINOR
(
inode
->
i_rdev
);
DECLARE_WAITQUEUE
(
wait
,
current
);
struct
au1000_state
*
s
=
&
au1000_state
;
int
ret
;
#ifdef AU1000_VERBOSE_DEBUG
if
(
file
->
f_flags
&
O_NONBLOCK
)
dbg
(
__FUNCTION__
": non-blocking"
);
else
dbg
(
__FUNCTION__
": blocking"
);
#endif
file
->
private_data
=
s
;
/* wait for device to become free */
down
(
&
s
->
open_sem
);
while
(
s
->
open_mode
&
file
->
f_mode
)
{
if
(
file
->
f_flags
&
O_NONBLOCK
)
{
up
(
&
s
->
open_sem
);
return
-
EBUSY
;
}
add_wait_queue
(
&
s
->
open_wait
,
&
wait
);
__set_current_state
(
TASK_INTERRUPTIBLE
);
up
(
&
s
->
open_sem
);
schedule
();
remove_wait_queue
(
&
s
->
open_wait
,
&
wait
);
set_current_state
(
TASK_RUNNING
);
if
(
signal_pending
(
current
))
return
-
ERESTARTSYS
;
down
(
&
s
->
open_sem
);
}
stop_dac
(
s
);
stop_adc
(
s
);
if
(
file
->
f_mode
&
FMODE_READ
)
{
s
->
dma_adc
.
ossfragshift
=
s
->
dma_adc
.
ossmaxfrags
=
s
->
dma_adc
.
subdivision
=
s
->
dma_adc
.
total_bytes
=
0
;
s
->
dma_adc
.
num_channels
=
1
;
s
->
dma_adc
.
sample_size
=
8
;
set_adc_rate
(
s
,
8000
);
if
((
minor
&
0xf
)
==
SND_DEV_DSP16
)
s
->
dma_adc
.
sample_size
=
16
;
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
s
->
dma_dac
.
ossfragshift
=
s
->
dma_dac
.
ossmaxfrags
=
s
->
dma_dac
.
subdivision
=
s
->
dma_dac
.
total_bytes
=
0
;
s
->
dma_dac
.
num_channels
=
1
;
s
->
dma_dac
.
sample_size
=
8
;
set_dac_rate
(
s
,
8000
);
if
((
minor
&
0xf
)
==
SND_DEV_DSP16
)
s
->
dma_dac
.
sample_size
=
16
;
}
if
(
file
->
f_mode
&
FMODE_READ
)
{
if
((
ret
=
prog_dmabuf_adc
(
s
)))
return
ret
;
}
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
if
((
ret
=
prog_dmabuf_dac
(
s
)))
return
ret
;
}
s
->
open_mode
|=
file
->
f_mode
&
(
FMODE_READ
|
FMODE_WRITE
);
up
(
&
s
->
open_sem
);
init_MUTEX
(
&
s
->
sem
);
return
0
;
}
static
int
au1000_release
(
struct
inode
*
inode
,
struct
file
*
file
)
{
struct
au1000_state
*
s
=
(
struct
au1000_state
*
)
file
->
private_data
;
lock_kernel
();
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
unlock_kernel
();
drain_dac
(
s
,
file
->
f_flags
&
O_NONBLOCK
);
lock_kernel
();
}
down
(
&
s
->
open_sem
);
if
(
file
->
f_mode
&
FMODE_WRITE
)
{
stop_dac
(
s
);
dealloc_dmabuf
(
s
,
&
s
->
dma_dac
);
}
if
(
file
->
f_mode
&
FMODE_READ
)
{
stop_adc
(
s
);
dealloc_dmabuf
(
s
,
&
s
->
dma_adc
);
}
s
->
open_mode
&=
((
~
file
->
f_mode
)
&
(
FMODE_READ
|
FMODE_WRITE
));
up
(
&
s
->
open_sem
);
wake_up
(
&
s
->
open_wait
);
unlock_kernel
();
return
0
;
}
static
/*const */
struct
file_operations
au1000_audio_fops
=
{
owner:
THIS_MODULE
,
llseek:
au1000_llseek
,
read:
au1000_read
,
write:
au1000_write
,
poll:
au1000_poll
,
ioctl:
au1000_ioctl
,
mmap:
au1000_mmap
,
open:
au1000_open
,
release:
au1000_release
,
};
/* --------------------------------------------------------------------- */
/* --------------------------------------------------------------------- */
/*
* for debugging purposes, we'll create a proc device that dumps the
* CODEC chipstate
*/
#ifdef AU1000_DEBUG
static
int
proc_au1000_dump
(
char
*
buf
,
char
**
start
,
off_t
fpos
,
int
length
,
int
*
eof
,
void
*
data
)
{
struct
au1000_state
*
s
=
&
au1000_state
;
int
cnt
,
len
=
0
;
/* print out header */
len
+=
sprintf
(
buf
+
len
,
"
\n\t\t
AU1000 Audio Debug
\n\n
"
);
// print out digital controller state
len
+=
sprintf
(
buf
+
len
,
"AU1000 Audio Controller registers
\n
"
);
len
+=
sprintf
(
buf
+
len
,
"---------------------------------
\n
"
);
len
+=
sprintf
(
buf
+
len
,
"AC97C_CONFIG = %08x
\n
"
,
au_readl
(
AC97C_CONFIG
));
len
+=
sprintf
(
buf
+
len
,
"AC97C_STATUS = %08x
\n
"
,
au_readl
(
AC97C_STATUS
));
len
+=
sprintf
(
buf
+
len
,
"AC97C_CNTRL = %08x
\n
"
,
au_readl
(
AC97C_CNTRL
));
/* print out CODEC state */
len
+=
sprintf
(
buf
+
len
,
"
\n
AC97 CODEC registers
\n
"
);
len
+=
sprintf
(
buf
+
len
,
"----------------------
\n
"
);
for
(
cnt
=
0
;
cnt
<=
0x7e
;
cnt
+=
2
)
len
+=
sprintf
(
buf
+
len
,
"reg %02x = %04x
\n
"
,
cnt
,
rdcodec
(
s
->
codec
,
cnt
));
if
(
fpos
>=
len
)
{
*
start
=
buf
;
*
eof
=
1
;
return
0
;
}
*
start
=
buf
+
fpos
;
if
((
len
-=
fpos
)
>
length
)
return
length
;
*
eof
=
1
;
return
len
;
}
#endif
/* AU1000_DEBUG */
/* --------------------------------------------------------------------- */
MODULE_AUTHOR
(
"Monta Vista Software, stevel@mvista.com"
);
MODULE_DESCRIPTION
(
"Au1000 Audio Driver"
);
/* --------------------------------------------------------------------- */
static
int
__devinit
au1000_probe
(
void
)
{
struct
au1000_state
*
s
=
&
au1000_state
;
int
val
;
char
proc_str
[
80
];
memset
(
s
,
0
,
sizeof
(
struct
au1000_state
));
init_waitqueue_head
(
&
s
->
dma_adc
.
wait
);
init_waitqueue_head
(
&
s
->
dma_dac
.
wait
);
init_waitqueue_head
(
&
s
->
open_wait
);
init_MUTEX
(
&
s
->
open_sem
);
spin_lock_init
(
&
s
->
lock
);
s
->
codec
=
ac97_alloc_codec
();
if
(
s
->
codec
==
NULL
)
{
error
(
"Out of memory"
);
return
-
1
;
}
s
->
codec
->
private_data
=
s
;
s
->
codec
->
id
=
0
;
s
->
codec
->
codec_read
=
rdcodec
;
s
->
codec
->
codec_write
=
wrcodec
;
s
->
codec
->
codec_wait
=
waitcodec
;
if
(
!
request_region
(
virt_to_phys
((
void
*
)
AC97C_CONFIG
),
0x14
,
AU1000_MODULE_NAME
))
{
err
(
"AC'97 ports in use"
);
goto
err_codec
;
}
// Allocate the DMA Channels
if
((
s
->
dma_dac
.
dmanr
=
request_au1000_dma
(
DMA_ID_AC97C_TX
,
"audio DAC"
,
dac_dma_interrupt
,
SA_INTERRUPT
,
s
))
<
0
)
{
err
(
"Can't get DAC DMA"
);
goto
err_dma1
;
}
if
((
s
->
dma_adc
.
dmanr
=
request_au1000_dma
(
DMA_ID_AC97C_RX
,
"audio ADC"
,
adc_dma_interrupt
,
SA_INTERRUPT
,
s
))
<
0
)
{
err
(
"Can't get ADC DMA"
);
goto
err_dma2
;
}
info
(
"DAC: DMA%d/IRQ%d, ADC: DMA%d/IRQ%d"
,
s
->
dma_dac
.
dmanr
,
get_dma_done_irq
(
s
->
dma_dac
.
dmanr
),
s
->
dma_adc
.
dmanr
,
get_dma_done_irq
(
s
->
dma_adc
.
dmanr
));
#ifdef USE_COHERENT_DMA
// enable DMA coherency in read/write DMA channels
set_dma_mode
(
s
->
dma_dac
.
dmanr
,
get_dma_mode
(
s
->
dma_dac
.
dmanr
)
&
~
DMA_NC
);
set_dma_mode
(
s
->
dma_adc
.
dmanr
,
get_dma_mode
(
s
->
dma_adc
.
dmanr
)
&
~
DMA_NC
);
#else
// disable DMA coherency in read/write DMA channels
set_dma_mode
(
s
->
dma_dac
.
dmanr
,
get_dma_mode
(
s
->
dma_dac
.
dmanr
)
|
DMA_NC
);
set_dma_mode
(
s
->
dma_adc
.
dmanr
,
get_dma_mode
(
s
->
dma_adc
.
dmanr
)
|
DMA_NC
);
#endif
/* register devices */
if
((
s
->
dev_audio
=
register_sound_dsp
(
&
au1000_audio_fops
,
-
1
))
<
0
)
goto
err_dev1
;
if
((
s
->
codec
->
dev_mixer
=
register_sound_mixer
(
&
au1000_mixer_fops
,
-
1
))
<
0
)
goto
err_dev2
;
#ifdef AU1000_DEBUG
/* intialize the debug proc device */
s
->
ps
=
create_proc_read_entry
(
AU1000_MODULE_NAME
,
0
,
NULL
,
proc_au1000_dump
,
NULL
);
#endif
/* AU1000_DEBUG */
// configure pins for AC'97
au_writel
(
au_readl
(
SYS_PINFUNC
)
&
~
0x02
,
SYS_PINFUNC
);
// Assert reset for 10msec to the AC'97 controller, and enable clock
au_writel
(
AC97C_RS
|
AC97C_CE
,
AC97C_CNTRL
);
au1000_delay
(
10
);
au_writel
(
AC97C_CE
,
AC97C_CNTRL
);
au1000_delay
(
10
);
// wait for clock to stabilize
/* cold reset the AC'97 */
au_writel
(
AC97C_RESET
,
AC97C_CONFIG
);
au1000_delay
(
10
);
au_writel
(
0
,
AC97C_CONFIG
);
/* need to delay around 500msec(bleech) to give
some CODECs enough time to wakeup */
au1000_delay
(
500
);
/* warm reset the AC'97 to start the bitclk */
au_writel
(
AC97C_SG
|
AC97C_SYNC
,
AC97C_CONFIG
);
udelay
(
100
);
au_writel
(
0
,
AC97C_CONFIG
);
/* codec init */
if
(
!
ac97_probe_codec
(
s
->
codec
))
goto
err_dev3
;
s
->
codec_base_caps
=
rdcodec
(
s
->
codec
,
AC97_RESET
);
s
->
codec_ext_caps
=
rdcodec
(
s
->
codec
,
AC97_EXTENDED_ID
);
info
(
"AC'97 Base/Extended ID = %04x/%04x"
,
s
->
codec_base_caps
,
s
->
codec_ext_caps
);
/*
* On the Pb1000, audio playback is on the AUX_OUT
* channel (which defaults to LNLVL_OUT in AC'97
* rev 2.2) so make sure this channel is listed
* as supported (soundcard.h calls this channel
* ALTPCM). ac97_codec.c does not handle detection
* of this channel correctly.
*/
s
->
codec
->
supported_mixers
|=
SOUND_MASK_ALTPCM
;
/*
* Now set AUX_OUT's default volume.
*/
val
=
0x4343
;
mixdev_ioctl
(
s
->
codec
,
SOUND_MIXER_WRITE_ALTPCM
,
(
unsigned
long
)
&
val
);
if
(
!
(
s
->
codec_ext_caps
&
AC97_EXTID_VRA
))
{
// codec does not support VRA
s
->
no_vra
=
1
;
}
else
if
(
!
vra
)
{
// Boot option says disable VRA
u16
ac97_extstat
=
rdcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
);
wrcodec
(
s
->
codec
,
AC97_EXTENDED_STATUS
,
ac97_extstat
&
~
AC97_EXTSTAT_VRA
);
s
->
no_vra
=
1
;
}
if
(
s
->
no_vra
)
info
(
"no VRA, interpolating and decimating"
);
/* set mic to be the recording source */
val
=
SOUND_MASK_MIC
;
mixdev_ioctl
(
s
->
codec
,
SOUND_MIXER_WRITE_RECSRC
,
(
unsigned
long
)
&
val
);
#ifdef AU1000_DEBUG
sprintf
(
proc_str
,
"driver/%s/%d/ac97"
,
AU1000_MODULE_NAME
,
s
->
codec
->
id
);
s
->
ac97_ps
=
create_proc_read_entry
(
proc_str
,
0
,
NULL
,
ac97_read_proc
,
s
->
codec
);
#endif
return
0
;
err_dev3:
unregister_sound_mixer
(
s
->
codec
->
dev_mixer
);
err_dev2:
unregister_sound_dsp
(
s
->
dev_audio
);
err_dev1:
free_au1000_dma
(
s
->
dma_adc
.
dmanr
);
err_dma2:
free_au1000_dma
(
s
->
dma_dac
.
dmanr
);
err_dma1:
release_region
(
virt_to_phys
((
void
*
)
AC97C_CONFIG
),
0x14
);
err_codec:
ac97_release_codec
(
s
->
codec
);
return
-
1
;
}
static
void
__devinit
au1000_remove
(
void
)
{
struct
au1000_state
*
s
=
&
au1000_state
;
if
(
!
s
)
return
;
#ifdef AU1000_DEBUG
if
(
s
->
ps
)
remove_proc_entry
(
AU1000_MODULE_NAME
,
NULL
);
#endif
/* AU1000_DEBUG */
synchronize_irq
();
free_au1000_dma
(
s
->
dma_adc
.
dmanr
);
free_au1000_dma
(
s
->
dma_dac
.
dmanr
);
release_region
(
virt_to_phys
((
void
*
)
AC97C_CONFIG
),
0x14
);
unregister_sound_dsp
(
s
->
dev_audio
);
unregister_sound_mixer
(
s
->
codec
->
dev_mixer
);
ac97_release_codec
(
s
->
codec
);
}
static
int
__init
init_au1000
(
void
)
{
info
(
"stevel@mvista.com, built "
__TIME__
" on "
__DATE__
);
return
au1000_probe
();
}
static
void
__exit
cleanup_au1000
(
void
)
{
info
(
"unloading"
);
au1000_remove
();
}
module_init
(
init_au1000
);
module_exit
(
cleanup_au1000
);
/* --------------------------------------------------------------------- */
#ifndef MODULE
static
int
__init
au1000_setup
(
char
*
options
)
{
char
*
this_opt
;
if
(
!
options
||
!*
options
)
return
0
;
for
(
this_opt
=
strtok
(
options
,
","
);
this_opt
;
this_opt
=
strtok
(
NULL
,
","
))
{
if
(
!
strncmp
(
this_opt
,
"vra"
,
3
))
{
vra
=
1
;
}
}
return
1
;
}
__setup
(
"au1000_audio="
,
au1000_setup
);
#endif
/* MODULE */
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