ref: 974c4fc768c12af947af13de75c227ef7e6ca50d
dir: /sys/src/9/bitsy/devuda1341.c/
/*
* SAC/UDA 1341 Audio driver for the Bitsy
*
* The Philips UDA 1341 sound chip is accessed through the Serial Audio
* Controller (SAC) of the StrongARM SA-1110. This is much more a SAC
* controller than a UDA controller, but we have a devsac.c already.
*
* The code morphs Nicolas Pitre's <nico@cam.org> Linux controller
* and Ken's Soundblaster controller.
*
* The interface should be identical to that of devaudio.c
*/
#include "u.h"
#include "../port/lib.h"
#include "mem.h"
#include "dat.h"
#include "fns.h"
#include "../port/error.h"
#include "io.h"
#include "sa1110dma.h"
static int debug = 0;
/*
* GPIO based L3 bus support.
*
* This provides control of Philips L3 type devices.
* GPIO lines are used for clock, data and mode pins.
*
* Note: The L3 pins are shared with I2C devices. This should not present
* any problems as long as an I2C start sequence is not generated. This is
* defined as a 1->0 transition on the data lines when the clock is high.
* It is critical this code only allow data transitions when the clock
* is low. This is always legal in L3.
*
* The IIC interface requires the clock and data pin to be LOW when idle. We
* must make sure we leave them in this state.
*
* It appears the read data is generated on the falling edge of the clock
* and should be held stable during the clock high time.
*/
/*
* L3 setup and hold times (expressed in µs)
*/
enum {
L3_AcquireTime = 1,
L3_ReleaseTime = 1,
L3_DataSetupTime = (190+999)/1000, /* 190 ns */
L3_DataHoldTime = ( 30+999)/1000,
L3_ModeSetupTime = (190+999)/1000,
L3_ModeHoldTime = (190+999)/1000,
L3_ClockHighTime = (100+999)/1000,
L3_ClockLowTime = (100+999)/1000,
L3_HaltTime = (190+999)/1000,
};
/* UDA 1341 Registers */
enum {
/* Status0 register */
UdaStatusDC = 0, /* 1 bit */
UdaStatusIF = 1, /* 3 bits */
UdaStatusSC = 4, /* 2 bits */
UdaStatusRST = 6, /* 1 bit */
};
enum {
/* Status1 register */
UdaStatusPC = 0, /* 2 bits */
UdaStatusDS = 2, /* 1 bit */
UdaStatusPDA = 3, /* 1 bit */
UdaStatusPAD = 4, /* 1 bit */
UdaStatusIGS = 5, /* 1 bit */
UdaStatusOGS = 6, /* 1 bit */
};
/*
* UDA1341 L3 address and command types
*/
enum {
UDA1341_DATA0 = 0,
UDA1341_DATA1,
UDA1341_STATUS,
UDA1341_L3Addr = 0x14,
};
typedef struct AQueue AQueue;
typedef struct Buf Buf;
typedef struct IOstate IOstate;
enum
{
Qdir = 0,
Qaudio,
Qvolume,
Qstatus,
Qstats,
Fmono = 1,
Fin = 2,
Fout = 4,
Aclosed = 0,
Aread,
Awrite,
Vaudio = 0,
Vmic,
Vtreb,
Vbass,
Vspeed,
Vbufsize,
Vfilter,
Vinvert,
Nvol,
Bufsize = 4* 1024, /* 46 ms each */
Nbuf = 10, /* 1.5 seconds total */
Speed = 44100,
Ncmd = 50, /* max volume command words */
};
enum {
Flushbuf = 0xe0000000,
};
/* System Clock -- according to the manual, it seems that when the UDA is
configured in non MSB/I2S mode, it uses a divisor of 256 to the 12.288MHz
clock. The other rates are only supported in MSB mode, which should be
implemented at some point */
enum {
SC512FS = 0 << 2,
SC384FS = 1 << 2,
SC256FS = 2 << 2,
CLOCKMASK = 3 << 2,
};
/* Format */
enum {
LSB16 = 1 << 1,
LSB18 = 2 << 1,
LSB20 = 3 << 1,
MSB = 4 << 1,
MSB16 = 5 << 1,
MSB18 = 6 << 1,
MSB20 = 7 << 1,
};
Dirtab
audiodir[] =
{
".", {Qdir, 0, QTDIR}, 0, DMDIR|0555,
"audio", {Qaudio}, 0, 0666,
"volume", {Qvolume}, 0, 0666,
"audiostatus", {Qstatus}, 0, 0444,
"audiostats", {Qstats}, 0, 0444,
};
struct Buf
{
uchar* virt;
ulong phys;
uint nbytes;
};
struct IOstate
{
QLock;
Lock ilock;
Rendez vous;
Chan *chan; /* chan of open */
int dma; /* dma chan, alloc on open, free on close */
int bufinit; /* boolean, if buffers allocated */
Buf buf[Nbuf]; /* buffers and queues */
volatile Buf *current; /* next dma to finish */
volatile Buf *next; /* next candidate for dma */
volatile Buf *filling; /* buffer being filled */
/* to have defines just like linux — there's a real operating system */
#define emptying filling
};
static struct
{
QLock;
int amode; /* Aclosed/Aread/Awrite for /audio */
int intr; /* boolean an interrupt has happened */
int rivol[Nvol]; /* right/left input/output volumes */
int livol[Nvol];
int rovol[Nvol];
int lovol[Nvol];
ulong totcount; /* how many bytes processed since open */
vlong tottime; /* time at which totcount bytes were processed */
IOstate i;
IOstate o;
} audio;
int zerodma; /* dma buffer used for sending zero */
typedef struct Iostats Iostats;
struct Iostats {
ulong totaldma;
ulong idledma;
ulong faildma;
ulong samedma;
ulong empties;
};
static struct
{
ulong bytes;
Iostats rx, tx;
} iostats;
static void setaudio(int in, int out, int left, int right, int value);
static void setspeed(int in, int out, int left, int right, int value);
static void setbufsize(int in, int out, int left, int right, int value);
static struct
{
char* name;
int flag;
int ilval; /* initial values */
int irval;
void (*setval)(int, int, int, int, int);
} volumes[] =
{
[Vaudio] {"audio", Fout|Fmono, 80, 80, setaudio },
[Vmic] {"mic", Fin|Fmono, 0, 0, nil },
[Vtreb] {"treb", Fout|Fmono, 50, 50, nil },
[Vbass] {"bass", Fout|Fmono, 50, 50, nil },
[Vspeed] {"speed", Fin|Fout|Fmono, Speed, Speed, setspeed },
[Vbufsize] {"bufsize", Fin|Fout|Fmono, Bufsize, Bufsize, setbufsize },
[Vfilter] {"filter", Fout|Fmono, 0, 0, nil },
[Vinvert] {"invert", Fin|Fout|Fmono, 0, 0, nil },
[Nvol] {0}
};
static void setreg(char *name, int val, int n);
/*
* Grab control of the IIC/L3 shared pins
*/
static void
L3_acquirepins(void)
{
gpioregs->set = (GPIO_L3_MODE_o | GPIO_L3_SCLK_o | GPIO_L3_SDA_io);
gpioregs->direction |= (GPIO_L3_MODE_o | GPIO_L3_SCLK_o | GPIO_L3_SDA_io);
microdelay(L3_AcquireTime);
}
/*
* Release control of the IIC/L3 shared pins
*/
static void
L3_releasepins(void)
{
gpioregs->direction &= ~(GPIO_L3_MODE_o | GPIO_L3_SCLK_o | GPIO_L3_SDA_io);
microdelay(L3_ReleaseTime);
}
/*
* Initialize the interface
*/
static void
L3_init(void)
{
gpioregs->altfunc &= ~(GPIO_L3_SDA_io | GPIO_L3_SCLK_o | GPIO_L3_MODE_o);
L3_releasepins();
}
/*
* Get a bit. The clock is high on entry and on exit. Data is read after
* the clock low time has expired.
*/
static int
L3_getbit(void)
{
int data;
gpioregs->clear = GPIO_L3_SCLK_o;
microdelay(L3_ClockLowTime);
data = (gpioregs->level & GPIO_L3_SDA_io) ? 1 : 0;
gpioregs->set = GPIO_L3_SCLK_o;
microdelay(L3_ClockHighTime);
return data;
}
/*
* Send a bit. The clock is high on entry and on exit. Data is sent only
* when the clock is low (I2C compatibility).
*/
static void
L3_sendbit(int bit)
{
gpioregs->clear = GPIO_L3_SCLK_o;
if (bit & 1)
gpioregs->set = GPIO_L3_SDA_io;
else
gpioregs->clear = GPIO_L3_SDA_io;
/* Assumes L3_DataSetupTime < L3_ClockLowTime */
microdelay(L3_ClockLowTime);
gpioregs->set = GPIO_L3_SCLK_o;
microdelay(L3_ClockHighTime);
}
/*
* Send a byte. The mode line is set or pulsed based on the mode sequence
* count. The mode line is high on entry and exit. The mod line is pulsed
* before the second data byte and before ech byte thereafter.
*/
static void
L3_sendbyte(char data, int mode)
{
int i;
switch(mode) {
case 0: /* Address mode */
gpioregs->clear = GPIO_L3_MODE_o;
break;
case 1: /* First data byte */
break;
default: /* Subsequent bytes */
gpioregs->clear = GPIO_L3_MODE_o;
microdelay(L3_HaltTime);
gpioregs->set = GPIO_L3_MODE_o;
break;
}
microdelay(L3_ModeSetupTime);
for (i = 0; i < 8; i++)
L3_sendbit(data >> i);
if (mode == 0) /* Address mode */
gpioregs->set = GPIO_L3_MODE_o;
microdelay(L3_ModeHoldTime);
}
/*
* Get a byte. The mode line is set or pulsed based on the mode sequence
* count. The mode line is high on entry and exit. The mod line is pulsed
* before the second data byte and before each byte thereafter. This
* function is never valid with mode == 0 (address cycle) as the address
* is always sent on the bus, not read.
*/
static char
L3_getbyte(int mode)
{
char data = 0;
int i;
switch(mode) {
case 0: /* Address mode - never valid */
break;
case 1: /* First data byte */
break;
default: /* Subsequent bytes */
gpioregs->clear = GPIO_L3_MODE_o;
microdelay(L3_HaltTime);
gpioregs->set = GPIO_L3_MODE_o;
break;
}
microdelay(L3_ModeSetupTime);
for (i = 0; i < 8; i++)
data |= (L3_getbit() << i);
microdelay(L3_ModeHoldTime);
return data;
}
/*
* Write data to a device on the L3 bus. The address is passed as well as
* the data and length. The length written is returned. The register space
* is encoded in the address (low two bits are set and device address is
* in the upper 6 bits).
*/
static int
L3_write(uchar addr, uchar *data, int len)
{
int mode = 0;
int bytes = len;
L3_acquirepins();
L3_sendbyte(addr, mode++);
while(len--)
L3_sendbyte(*data++, mode++);
L3_releasepins();
return bytes;
}
/*
* Read data from a device on the L3 bus. The address is passed as well as
* the data and length. The length read is returned. The register space
* is encoded in the address (low two bits are set and device address is
* in the upper 6 bits).
* Commented out, not used
static int
L3_read(uchar addr, uchar *data, int len)
{
int mode = 0;
int bytes = len;
L3_acquirepins();
L3_sendbyte(addr, mode++);
gpioregs->direction &= ~(GPIO_L3_SDA_io);
while(len--)
*data++ = L3_getbyte(mode++);
L3_releasepins();
return bytes;
}
*/
void
audiomute(int on)
{
egpiobits(EGPIO_audio_mute, on);
}
static char Emode[] = "illegal open mode";
static char Evolume[] = "illegal volume specifier";
static void
bufinit(IOstate *b)
{
int i;
if (debug) print("bufinit\n");
for (i = 0; i < Nbuf; i++) {
b->buf[i].virt = xalloc(Bufsize);
b->buf[i].phys = PADDR(b->buf[i].virt);
memset(b->buf[i].virt, 0xAA, Bufsize);
}
b->bufinit = 1;
};
static void
setempty(IOstate *b)
{
int i;
if (debug) print("setempty\n");
for (i = 0; i < Nbuf; i++) {
b->buf[i].nbytes = 0;
}
b->filling = b->buf;
b->current = b->buf;
b->next = b->buf;
}
static int
audioqnotempty(void *x)
{
IOstate *s = x;
return dmaidle(s->dma) || s->emptying != s->current;
}
static int
audioqnotfull(void *x)
{
IOstate *s = x;
return dmaidle(s->dma) || s->filling != s->current;
}
SSPregs *sspregs;
MCPregs *mcpregs;
static void
audioinit(void)
{
/* Turn MCP operations off */
mcpregs = mapspecial(MCPREGS, sizeof(MCPregs));
mcpregs->status &= ~(1<<16);
sspregs = mapspecial(SSPREGS, sizeof(SSPregs));
}
uchar status0[1] = {0x02};
uchar status1[1] = {0x80};
uchar data00[1] = {0x00}; /* volume control, bits 0 – 5 */
uchar data01[1] = {0x40};
uchar data02[1] = {0x80};
uchar data0e0[2] = {0xc0, 0xe0};
uchar data0e1[2] = {0xc1, 0xe0};
uchar data0e2[2] = {0xc2, 0xf2};
/* there is no data0e3 */
uchar data0e4[2] = {0xc4, 0xe0};
uchar data0e5[2] = {0xc5, 0xe0};
uchar data0e6[2] = {0xc6, 0xe3};
static void
enable(void)
{
uchar data[1];
L3_init();
/* Setup the uarts */
ppcregs->assignment &= ~(1<<18);
sspregs->control0 = 0;
sspregs->control0 = 0x031f; /* 16 bits, TI frames, serial clock rate 3 */
sspregs->control1 = 0x0020; /* ext clock */
sspregs->control0 = 0x039f; /* enable */
/* Enable the audio power */
audioicpower(1);
egpiobits(EGPIO_codec_reset, 1);
setspeed(0, 0, 0, 0, volumes[Vspeed].ilval);
data[0] = status0[0] | 1 << UdaStatusRST;
L3_write(UDA1341_L3Addr | UDA1341_STATUS, data, 1 );
gpioregs->clear = EGPIO_codec_reset;
gpioregs->set = EGPIO_codec_reset;
/* write uda 1341 status[0] */
data[0] = status0[0];
L3_write(UDA1341_L3Addr | UDA1341_STATUS, data, 1);
if (debug)
print("enable: status0 = 0x%2.2ux\n", data[0]);
L3_write(UDA1341_L3Addr | UDA1341_STATUS, status1, 1);
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data02, 1);
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data0e2, 2);
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data0e6, 2 );
if (debug) {
print("enable: status0 = 0x%2.2ux\n", data[0]);
print("enable: status1 = 0x%2.2ux\n", status1[0]);
print("enable: data02 = 0x%2.2ux\n", data02[0]);
print("enable: data0e2 = 0x%4.4ux\n", data0e2[0] | data0e2[1]<<8);
print("enable: data0e4 = 0x%4.4ux\n", data0e4[0] | data0e4[1]<<8);
print("enable: data0e6 = 0x%4.4ux\n", data0e6[0] | data0e6[1]<<8);
print("enable: sspregs->control0 = 0x%lux\n", sspregs->control0);
print("enable: sspregs->control1 = 0x%lux\n", sspregs->control1);
}
}
static void
resetlevel(void)
{
int i;
for(i=0; volumes[i].name; i++) {
audio.lovol[i] = volumes[i].ilval;
audio.rovol[i] = volumes[i].irval;
audio.livol[i] = volumes[i].ilval;
audio.rivol[i] = volumes[i].irval;
}
}
static void
mxvolume(void) {
int *left, *right;
setspeed(0, 0, 0, 0, volumes[Vspeed].ilval);
if (!dmaidle(audio.i.dma) || !dmaidle(audio.o.dma))
L3_write(UDA1341_L3Addr | UDA1341_STATUS, status0, 1);
if(audio.amode & Aread){
left = audio.livol;
right = audio.rivol;
if (left[Vmic]+right[Vmic] == 0) {
/* Turn on automatic gain control (AGC) */
data0e4[1] |= 0x10;
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data0e4, 2 );
} else {
int v;
/* Turn on manual gain control */
v = ((left[Vmic]+right[Vmic])*0x7f/200)&0x7f;
data0e4[1] &= ~0x13;
data0e5[1] &= ~0x1f;
data0e4[1] |= v & 0x3;
data0e5[0] |= (v & 0x7c)<<6;
data0e5[1] |= (v & 0x7c)>>2;
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data0e4, 2 );
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data0e5, 2 );
}
if (left[Vinvert]+right[Vinvert] == 0)
status1[0] &= ~0x04;
else
status1[0] |= 0x04;
L3_write(UDA1341_L3Addr | UDA1341_STATUS, status1, 1);
if (debug) {
print("mxvolume: status1 = 0x%2.2ux\n", status1[0]);
print("mxvolume: data0e4 = 0x%4.4ux\n", data0e4[0]|data0e4[0]<<8);
print("mxvolume: data0e5 = 0x%4.4ux\n", data0e5[0]|data0e5[0]<<8);
}
}
if(audio.amode & Awrite){
left = audio.lovol;
right = audio.rovol;
data00[0] &= ~0x3f;
data00[0] |= ((200-left[Vaudio]-right[Vaudio])*0x3f/200)&0x3f;
if (left[Vtreb]+right[Vtreb] <= 100
&& left[Vbass]+right[Vbass] <= 100)
/* settings neutral */
data02[0] &= ~0x03;
else {
data02[0] |= 0x03;
data01[0] &= ~0x3f;
data01[0] |= ((left[Vtreb]+right[Vtreb]-100)*0x3/100)&0x03;
data01[0] |= (((left[Vbass]+right[Vbass]-100)*0xf/100)&0xf)<<2;
}
if (left[Vfilter]+right[Vfilter] == 0)
data02[0] &= ~0x10;
else
data02[0]|= 0x10;
if (left[Vinvert]+right[Vinvert] == 0)
status1[0] &= ~0x10;
else
status1[0] |= 0x10;
L3_write(UDA1341_L3Addr | UDA1341_STATUS, status1, 1);
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data00, 1);
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data01, 1);
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data02, 1);
if (debug) {
print("mxvolume: status1 = 0x%2.2ux\n", status1[0]);
print("mxvolume: data00 = 0x%2.2ux\n", data00[0]);
print("mxvolume: data01 = 0x%2.2ux\n", data01[0]);
print("mxvolume: data02 = 0x%2.2ux\n", data02[0]);
}
}
}
static void
setreg(char *name, int val, int n)
{
uchar x[2];
int i;
x[0] = val;
x[1] = val>>8;
if(strcmp(name, "pause") == 0){
for(i = 0; i < n; i++)
microdelay(val);
return;
}
switch(n){
case 1:
case 2:
break;
default:
error("setreg");
}
if(strcmp(name, "status") == 0){
L3_write(UDA1341_L3Addr | UDA1341_STATUS, x, n);
} else if(strcmp(name, "data0") == 0){
L3_write(UDA1341_L3Addr | UDA1341_DATA0, x, n);
} else if(strcmp(name, "data1") == 0){
L3_write(UDA1341_L3Addr | UDA1341_DATA1, x, n);
} else
error("setreg");
}
static void
outenable(void) {
/* turn on DAC, set output gain switch */
audioamppower(1);
audiomute(0);
status1[0] |= 0x41;
L3_write(UDA1341_L3Addr | UDA1341_STATUS, status1, 1);
/* set volume */
data00[0] |= 0xf;
L3_write(UDA1341_L3Addr | UDA1341_DATA0, data00, 1);
if (debug) {
print("outenable: status1 = 0x%2.2ux\n", status1[0]);
print("outenable: data00 = 0x%2.2ux\n", data00[0]);
}
}
static void
outdisable(void) {
dmastop(audio.o.dma);
/* turn off DAC, clear output gain switch */
audiomute(1);
status1[0] &= ~0x41;
L3_write(UDA1341_L3Addr | UDA1341_STATUS, status1, 1);
if (debug) {
print("outdisable: status1 = 0x%2.2ux\n", status1[0]);
}
audioamppower(0);
}
static void
inenable(void) {
/* turn on ADC, set input gain switch */
status1[0] |= 0x22;
L3_write(UDA1341_L3Addr | UDA1341_STATUS, status1, 1);
if (debug) {
print("inenable: status1 = 0x%2.2ux\n", status1[0]);
}
}
static void
indisable(void) {
dmastop(audio.i.dma);
/* turn off ADC, clear input gain switch */
status1[0] &= ~0x22;
L3_write(UDA1341_L3Addr | UDA1341_STATUS, status1, 1);
if (debug) {
print("indisable: status1 = 0x%2.2ux\n", status1[0]);
}
}
static void
sendaudio(IOstate *s) {
/* interrupt routine calls this too */
int n;
if (debug > 1) print("#A: sendaudio\n");
ilock(&s->ilock);
if ((audio.amode & Aread) && s->next == s->filling && dmaidle(s->dma)) {
// send an empty buffer to provide an input clock
zerodma |= dmastart(s->dma, Flushbuf, volumes[Vbufsize].ilval) & 0xff;
if (zerodma == 0)
if (debug) print("emptyfail\n");
iostats.tx.empties++;
iunlock(&s->ilock);
return;
}
while (s->next != s->filling) {
s->next->nbytes &= ~0x3; /* must be a multiple of 4 */
if(s->next->nbytes) {
if ((n = dmastart(s->dma, s->next->phys, s->next->nbytes)) == 0) {
iostats.tx.faildma++;
break;
}
iostats.tx.totaldma++;
switch (n >> 8) {
case 1:
iostats.tx.idledma++;
break;
case 3:
iostats.tx.faildma++;
break;
}
if (debug) {
if (debug > 1)
print("dmastart @%p\n", s->next);
else
iprint("+");
}
s->next->nbytes = 0;
}
s->next++;
if (s->next == &s->buf[Nbuf])
s->next = &s->buf[0];
}
iunlock(&s->ilock);
}
static void
recvaudio(IOstate *s) {
/* interrupt routine calls this too */
int n;
if (debug > 1) print("#A: recvaudio\n");
ilock(&s->ilock);
while (s->next != s->emptying) {
assert(s->next->nbytes == 0);
if ((n = dmastart(s->dma, s->next->phys, volumes[Vbufsize].ilval)) == 0) {
iostats.rx.faildma++;
break;
}
iostats.rx.totaldma++;
switch (n >> 8) {
case 1:
iostats.rx.idledma++;
break;
case 3:
iostats.rx.faildma++;
break;
}
if (debug) {
if (debug > 1)
print("dmastart @%p\n", s->next);
else
iprint("+");
}
s->next++;
if (s->next == &s->buf[Nbuf])
s->next = &s->buf[0];
}
iunlock(&s->ilock);
}
void
audiopower(int flag) {
IOstate *s;
if (debug) {
iprint("audiopower %d\n", flag);
}
if (flag) {
/* power on only when necessary */
if (audio.amode) {
audioamppower(1);
audioicpower(1);
egpiobits(EGPIO_codec_reset, 1);
enable();
if (audio.amode & Aread) {
inenable();
s = &audio.i;
dmareset(s->dma, 1, 0, 4, 2, SSPRecvDMA, Port4SSP);
recvaudio(s);
}
if (audio.amode & Awrite) {
outenable();
s = &audio.o;
dmareset(s->dma, 0, 0, 4, 2, SSPXmitDMA, Port4SSP);
sendaudio(s);
}
mxvolume();
}
} else {
/* power off */
if (audio.amode & Aread)
indisable();
if (audio.amode & Awrite)
outdisable();
egpiobits(EGPIO_codec_reset, 0);
audioamppower(0);
audioicpower(0);
}
}
static void
audiointr(void *x, ulong ndma) {
IOstate *s = x;
if (debug) {
if (debug > 1)
iprint("#A: audio interrupt @%p\n", s->current);
else
iprint("-");
}
if (s == &audio.i || (ndma & ~zerodma)) {
/* A dma, not of a zero buffer completed, update current
* Only interrupt routine touches s->current
*/
s->current->nbytes = (s == &audio.i)? volumes[Vbufsize].ilval: 0;
s->current++;
if (s->current == &s->buf[Nbuf])
s->current = &s->buf[0];
}
if (ndma) {
if (s == &audio.o) {
zerodma &= ~ndma;
sendaudio(s);
} else if (s == &audio.i)
recvaudio(s);
}
wakeup(&s->vous);
}
static Chan*
audioattach(char *param)
{
return devattach('A', param);
}
static Walkqid*
audiowalk(Chan *c, Chan *nc, char **name, int nname)
{
return devwalk(c, nc, name, nname, audiodir, nelem(audiodir), devgen);
}
static int
audiostat(Chan *c, uchar *db, int n)
{
return devstat(c, db, n, audiodir, nelem(audiodir), devgen);
}
static Chan*
audioopen(Chan *c, int mode)
{
IOstate *s;
int omode = mode;
switch((ulong)c->qid.path) {
default:
error(Eperm);
break;
case Qstatus:
case Qstats:
if((omode&7) != OREAD)
error(Eperm);
case Qvolume:
case Qdir:
break;
case Qaudio:
omode = (omode & 0x7) + 1;
if (omode & ~(Aread | Awrite))
error(Ebadarg);
qlock(&audio);
if(audio.amode & omode){
qunlock(&audio);
error(Einuse);
}
enable();
memset(&iostats, 0, sizeof(iostats));
if (omode & Aread) {
inenable();
s = &audio.i;
if(s->bufinit == 0)
bufinit(s);
setempty(s);
s->emptying = &s->buf[Nbuf-1];
s->chan = c;
s->dma = dmaalloc(1, 0, 4, 2, SSPRecvDMA, Port4SSP, audiointr, (void*)s);
audio.amode |= Aread;
}
if (omode & (Aread|Awrite) && (audio.amode & Awrite) == 0) {
s = &audio.o;
if(s->bufinit == 0)
bufinit(s);
setempty(s);
s->chan = c;
s->dma = dmaalloc(0, 0, 4, 2, SSPXmitDMA, Port4SSP, audiointr, (void*)s);
}
if (omode & Awrite) {
audio.amode |= Awrite;
outenable();
}
mxvolume();
if (audio.amode & Aread)
sendaudio(&audio.o);
qunlock(&audio);
if (debug) print("open done\n");
break;
}
c = devopen(c, mode, audiodir, nelem(audiodir), devgen);
c->mode = openmode(mode);
c->flag |= COPEN;
c->offset = 0;
return c;
}
static void
audioclose(Chan *c)
{
IOstate *s;
switch((ulong)c->qid.path) {
default:
error(Eperm);
break;
case Qdir:
case Qvolume:
case Qstatus:
case Qstats:
break;
case Qaudio:
if (debug > 1) print("#A: close\n");
if(c->flag & COPEN) {
qlock(&audio);
if (audio.i.chan == c) {
/* closing the read end */
audio.amode &= ~Aread;
s = &audio.i;
qlock(s);
indisable();
setempty(s);
dmafree(s->dma);
qunlock(s);
if ((audio.amode & Awrite) == 0) {
s = &audio.o;
qlock(s);
while(waserror())
;
dmawait(s->dma);
poperror();
outdisable();
setempty(s);
dmafree(s->dma);
qunlock(s);
}
}
if (audio.o.chan == c) {
/* closing the write end */
audio.amode &= ~Awrite;
s = &audio.o;
qlock(s);
if (s->filling->nbytes) {
/* send remaining partial buffer */
s->filling++;
if (s->filling == &s->buf[Nbuf])
s->filling = &s->buf[0];
sendaudio(s);
}
while(waserror())
;
dmawait(s->dma);
poperror();
outdisable();
setempty(s);
if ((audio.amode & Aread) == 0)
dmafree(s->dma);
qunlock(s);
}
if (audio.amode == 0) {
/* turn audio off */
egpiobits(EGPIO_codec_reset, 0);
audioicpower(0);
}
qunlock(&audio);
}
break;
}
}
static long
audioread(Chan *c, void *v, long n, vlong off)
{
int liv, riv, lov, rov;
long m, n0;
char buf[300];
int j;
ulong offset = off;
char *p;
IOstate *s;
n0 = n;
p = v;
switch((ulong)c->qid.path) {
default:
error(Eperm);
break;
case Qdir:
return devdirread(c, p, n, audiodir, nelem(audiodir), devgen);
case Qaudio:
if (debug > 1) print("#A: read %ld\n", n);
if((audio.amode & Aread) == 0)
error(Emode);
s = &audio.i;
qlock(s);
if(waserror()){
qunlock(s);
nexterror();
}
while(n > 0) {
if(s->emptying->nbytes == 0) {
if (debug > 1) print("#A: emptied @%p\n", s->emptying);
recvaudio(s);
s->emptying++;
if (s->emptying == &s->buf[Nbuf])
s->emptying = s->buf;
}
/* wait if dma in progress */
while (!dmaidle(s->dma) && s->emptying == s->current) {
if (debug > 1) print("#A: sleep\n");
sleep(&s->vous, audioqnotempty, s);
}
m = (s->emptying->nbytes > n)? n: s->emptying->nbytes;
memmove(p, s->emptying->virt + volumes[Vbufsize].ilval -
s->emptying->nbytes, m);
s->emptying->nbytes -= m;
n -= m;
p += m;
}
poperror();
qunlock(s);
break;
case Qstatus:
buf[0] = 0;
snprint(buf, sizeof(buf), "bytes %lud\ntime %lld\n",
audio.totcount, audio.tottime);
return readstr(offset, p, n, buf);
case Qstats:
buf[0] = 0;
snprint(buf, sizeof(buf),
"bytes %lud\nRX dmas %lud, while idle %lud, while busy %lud, "
"out-of-order %lud, empty dmas %lud\n"
"TX dmas %lud, while idle %lud, while busy %lud, "
"out-of-order %lud, empty dmas %lud\n",
iostats.bytes, iostats.rx.totaldma, iostats.rx.idledma,
iostats.rx.faildma, iostats.rx.samedma, iostats.rx.empties,
iostats.tx.totaldma, iostats.tx.idledma,
iostats.tx.faildma, iostats.tx.samedma, iostats.tx.empties);
return readstr(offset, p, n, buf);
case Qvolume:
j = 0;
buf[0] = 0;
for(m=0; volumes[m].name; m++){
if (m == Vaudio) {
liv = audio.livol[m];
riv = audio.rivol[m];
lov = audio.lovol[m];
rov = audio.rovol[m];
}
else {
lov = liv = volumes[m].ilval;
rov = riv = volumes[m].irval;
}
j += snprint(buf+j, sizeof(buf)-j, "%s", volumes[m].name);
if((volumes[m].flag & Fmono) || liv==riv && lov==rov){
if((volumes[m].flag&(Fin|Fout))==(Fin|Fout) && liv==lov)
j += snprint(buf+j, sizeof(buf)-j, " %d", liv);
else{
if(volumes[m].flag & Fin)
j += snprint(buf+j, sizeof(buf)-j,
" in %d", liv);
if(volumes[m].flag & Fout)
j += snprint(buf+j, sizeof(buf)-j,
" out %d", lov);
}
}else{
if((volumes[m].flag&(Fin|Fout))==(Fin|Fout) &&
liv==lov && riv==rov)
j += snprint(buf+j, sizeof(buf)-j,
" left %d right %d",
liv, riv);
else{
if(volumes[m].flag & Fin)
j += snprint(buf+j, sizeof(buf)-j,
" in left %d right %d",
liv, riv);
if(volumes[m].flag & Fout)
j += snprint(buf+j, sizeof(buf)-j,
" out left %d right %d",
lov, rov);
}
}
j += snprint(buf+j, sizeof(buf)-j, "\n");
}
return readstr(offset, p, n, buf);
}
return n0-n;
}
static void
setaudio(int in, int out, int left, int right, int value)
{
if (value < 0 || value > 100)
error(Evolume);
if(left && out)
audio.lovol[Vaudio] = value;
if(left && in)
audio.livol[Vaudio] = value;
if(right && out)
audio.rovol[Vaudio] = value;
if(right && in)
audio.rivol[Vaudio] = value;
}
static void
setspeed(int, int, int, int, int speed)
{
uchar clock;
/* external clock configured for 44100 samples/sec */
switch (speed) {
case 32000:
/* 00 */
gpioregs->clear = GPIO_CLK_SET0_o|GPIO_CLK_SET1_o;
clock = SC384FS; /* Only works in MSB mode! */
break;
case 48000:
/* 00 */
gpioregs->clear = GPIO_CLK_SET0_o|GPIO_CLK_SET1_o;
clock = SC256FS;
break;
default:
speed = 44100;
case 44100:
/* 01 */
gpioregs->set = GPIO_CLK_SET0_o;
gpioregs->clear = GPIO_CLK_SET1_o;
clock = SC256FS;
break;
case 8000:
/* 10 */
gpioregs->set = GPIO_CLK_SET1_o;
gpioregs->clear = GPIO_CLK_SET0_o;
clock = SC512FS; /* Only works in MSB mode! */
break;
case 16000:
/* 10 */
gpioregs->set = GPIO_CLK_SET1_o;
gpioregs->clear = GPIO_CLK_SET0_o;
clock = SC256FS;
break;
case 11025:
/* 11 */
gpioregs->set = GPIO_CLK_SET0_o|GPIO_CLK_SET1_o;
clock = SC512FS; /* Only works in MSB mode! */
break;
case 22050:
/* 11 */
gpioregs->set = GPIO_CLK_SET0_o|GPIO_CLK_SET1_o;
clock = SC256FS;
break;
}
/* Wait for the UDA1341 to wake up */
delay(100);
/* Reset the chip */
status0[0] &= ~CLOCKMASK;
status0[0] |=clock;
volumes[Vspeed].ilval = speed;
}
static void
setbufsize(int, int, int, int, int value)
{
if ((value % 8) != 0 || value < 8 || value >= Bufsize)
error(Ebadarg);
volumes[Vbufsize].ilval = value;
}
static long
audiowrite(Chan *c, void *vp, long n, vlong)
{
long m, n0;
int i, v, left, right, in, out;
char *p;
IOstate *a;
Cmdbuf *cb;
p = vp;
n0 = n;
switch((ulong)c->qid.path) {
default:
error(Eperm);
break;
case Qvolume:
v = Vaudio;
left = 1;
right = 1;
in = 1;
out = 1;
cb = parsecmd(p, n);
if(waserror()){
free(cb);
nexterror();
}
for(i = 0; i < cb->nf; i++){
/*
* a number is volume
*/
if(cb->f[i][0] >= '0' && cb->f[i][0] <= '9') {
m = strtoul(cb->f[i], 0, 10);
if (volumes[v].setval)
volumes[v].setval(in, out, left, right, m);
goto cont0;
}
for(m=0; volumes[m].name; m++) {
if(strcmp(cb->f[i], volumes[m].name) == 0) {
v = m;
in = 1;
out = 1;
left = 1;
right = 1;
goto cont0;
}
}
if(strcmp(cb->f[i], "reset") == 0) {
resetlevel();
goto cont0;
}
if(strcmp(cb->f[i], "debug") == 0) {
debug = debug?0:1;
goto cont0;
}
if(strcmp(cb->f[i], "in") == 0) {
in = 1;
out = 0;
goto cont0;
}
if(strcmp(cb->f[i], "out") == 0) {
in = 0;
out = 1;
goto cont0;
}
if(strcmp(cb->f[i], "left") == 0) {
left = 1;
right = 0;
goto cont0;
}
if(strcmp(cb->f[i], "right") == 0) {
left = 0;
right = 1;
goto cont0;
}
if(strcmp(cb->f[i], "reg") == 0) {
if(cb->nf < 3)
error(Evolume);
setreg(cb->f[1], strtol(cb->f[2], 0, 0),
cb->nf == 4 ? strtol(cb->f[3], 0, 0):1);
return n0;
}
error(Evolume);
break;
cont0:;
}
mxvolume();
poperror();
free(cb);
break;
case Qaudio:
if (debug > 1) print("#A: write %ld\n", n);
if((audio.amode & Awrite) == 0)
error(Emode);
a = &audio.o;
qlock(a);
if(waserror()){
qunlock(a);
nexterror();
}
while(n > 0) {
/* wait if dma in progress */
while (!dmaidle(a->dma) && !zerodma && a->filling == a->current) {
if (debug > 1) print("#A: sleep\n");
sleep(&a->vous, audioqnotfull, a);
}
m = volumes[Vbufsize].ilval - a->filling->nbytes;
if(m > n)
m = n;
memmove(a->filling->virt + a->filling->nbytes, p, m);
a->filling->nbytes += m;
n -= m;
p += m;
if(a->filling->nbytes >= volumes[Vbufsize].ilval) {
if (debug > 1) print("#A: filled @%p\n", a->filling);
a->filling++;
if (a->filling == &a->buf[Nbuf])
a->filling = a->buf;
sendaudio(a);
}
}
poperror();
qunlock(a);
break;
}
return n0 - n;
}
Dev uda1341devtab = {
'A',
"audio",
devreset,
audioinit,
devshutdown,
audioattach,
audiowalk,
audiostat,
audioopen,
devcreate,
audioclose,
audioread,
devbread,
audiowrite,
devbwrite,
devremove,
devwstat,
audiopower,
};