Plan 9 from Bell Labs’s /usr/web/sources/contrib/fgb/root/sys/src/ape/X11/cmd/X/hw/xfree86/i2c/fi1236.c

Copyright © 2021 Plan 9 Foundation.
Distributed under the MIT License.
Download the Plan 9 distribution.



#ifdef HAVE_XORG_CONFIG_H
#include <xorg-config.h>
#endif

#include <unistd.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>

#include "xf86.h"
#include "xf86i2c.h"
#include "fi1236.h"
#include "tda9885.h"
#include "i2c_def.h"

#define NUM_TUNERS    8

const FI1236_parameters tuner_parms[NUM_TUNERS] =
{
    /* 0 - FI1236 */
    { 733 ,884 ,12820 ,2516 ,7220 ,0xA2 ,0x94, 0x34, 0x8e },
    /* !!!based on documentation - it should be:
    {733 ,16*55.25 ,16*801.25 ,16*160 ,16*454 ,0xA0 ,0x90, 0x30, 0x8e},*/
    
    /* 1 - FI1216 */
    { 623 ,16*48.75 ,16*855.25 ,16*170 ,16*450 ,0xA0 ,0x90, 0x30, 0x8e },
    /* 2 - TEMIC FN5AL */
    { 623 ,16*45.75 ,16*855.25 ,16*169 ,16*454 ,0xA0 ,0x90, 0x30, 0x8e },
    /* 3 - MT2032.. */
    { 733 ,768 ,13760 , 0 , 0 , 0 , 0,  0, 0 },
    /* 4 - FI1246 */
    { 623 ,16*45.75 ,16*855.25 ,16*170 ,16*450 ,0xA0 ,0x90, 0x30, 0x8e },
    /* 5 - FI1256 */
    { 623 ,16*49.75 ,16*863.25 ,16*170 ,16*450 ,0xA0 ,0x90, 0x30, 0x8e },
    /* 6 - FI1236W */
    /*{ 733 ,884 ,12820 ,2516 ,7220 ,0x1 ,0x2, 0x4, 0x8e },*/
    { 732, 16*55.25, 16*801.25, 16*160, 16*442, 0x1, 0x2, 0x4, 0x8e },
	 /* 7 - FM1216ME */
    { 623 ,16*48.25 ,16*863.25 ,16*158.00 ,16*442.00 ,0x1 ,0x2, 0x4, 0x8e }
};


FI1236Ptr Detect_FI1236(I2CBusPtr b, I2CSlaveAddr addr)
{
   FI1236Ptr f;
   I2CByte a;

   f = xcalloc(1,sizeof(FI1236Rec));
   if(f == NULL) return NULL;
   f->d.DevName = strdup("FI12xx Tuner");
   f->d.SlaveAddr = addr;
   f->d.pI2CBus = b;
   f->d.NextDev = NULL;
   f->d.StartTimeout = b->StartTimeout;
   f->d.BitTimeout = b->BitTimeout;
   f->d.AcknTimeout = b->AcknTimeout;
   f->d.ByteTimeout = b->ByteTimeout;
   f->type=TUNER_TYPE_FI1236;
   f->afc_timer_installed=FALSE;
   f->last_afc_hint=TUNER_OFF;
   f->video_if=45.7812;
  
   if(!I2C_WriteRead(&(f->d), NULL, 0, &a, 1))
   {
   	free(f);
	return NULL;
    }
    FI1236_set_tuner_type(f, TUNER_TYPE_FI1236);
    if(!I2CDevInit(&(f->d)))
    {
       free(f);
       return NULL;
    }
    return f;
}

static void MT2032_dump_parameters(FI1236Ptr f, MT2032_parameters *m)
{
xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: input f_rf=%g f_if1=%g f_if2=%g f_ref=%g f_ifbw=%g f_step=%g\n", 
	m->f_rf, m->f_if1, m->f_if2, m->f_ref, m->f_ifbw, m->f_step);

xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: computed f_lo1=%g f_lo2=%g LO1I=%d LO2I=%d SEL=%d STEP=%d NUM=%d\n", 
	m->f_lo1, m->f_lo2, m->LO1I, m->LO2I, m->SEL, m->STEP, m->NUM);
}


static void MT2032_getid(FI1236Ptr f)
{
CARD8 out[4];
CARD8 in;

in=0x11;
I2C_WriteRead(&(f->d), (I2CByte *)&in, 1, out, 4);
xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: Company code 0x%02x%02x, part code 0x%02x, revision code 0x%02x\n",
	out[0], out[1], out[2], out[3]);

}

/* might be buggy */
#if 0
static void MT2032_shutdown(FI1236Ptr f)
{
CARD8 data[10];

data[0]=0x00; /* start with register 0x00 */
data[1]=0x1A; 
data[2]=0x44;
data[3]=0x20;

I2C_WriteRead(&(f->d), (I2CByte *)data, 4, NULL, 0);

data[0]=0x05; /* now start with register 0x05 */
data[1]=0xD7;
data[2]=0x14;
data[3]=0x05;
I2C_WriteRead(&(f->d), (I2CByte *)data, 4, NULL, 0);

data[0]=0x0B; /* now start with register 0x05 */
data[1]=0x8F;
data[2]=0x07;
data[3]=0x43;
I2C_WriteRead(&(f->d), (I2CByte *)data, 4, NULL, 0);

usleep(15000);
}
#endif

static void MT2032_dump_status(FI1236Ptr f);

static void MT2032_init(FI1236Ptr f)
{
CARD8 data[10];
CARD8 value;
CARD8 xogc = 0x00;

MT2032_getid(f);

data[0]=0x02; /* start with register 0x02 */
data[1]=0xFF; 
data[2]=0x0F;
data[3]=0x1F;

I2C_WriteRead(&(f->d), (I2CByte *)data, 4, NULL, 0);

data[0]=0x06; /* now start with register 0x06 */
data[1]=0xE4;
data[2]=0x8F;
data[3]=0xC3;
data[4]=0x4E;
data[5]=0xEC;
I2C_WriteRead(&(f->d), (I2CByte *)data, 6, NULL, 0);

data[0]=0x0d; /* now start with register 0x0d */
data[1]=0x32;
I2C_WriteRead(&(f->d), (I2CByte *)data, 2, NULL, 0);

while(1) {
	usleep(15000); /* wait 15 milliseconds */

	data[0]=0x0e; /* register number 7, status */
	value=0xFF;
	if(!I2C_WriteRead(&(f->d), (I2CByte *)data, 1, &value, 1))
		xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: failed to read XOK\n"); 
	xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: XOK=%d\n", value & 0x01); 
	if(value & 1) break;
	
	data[0]=0x07;
	if(!I2C_WriteRead(&(f->d), (I2CByte *)data, 1, &value, 1))
		xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: failed to read XOGC\n"); 
	 
	xogc=value & 0x7;
	if(xogc==4){
		break; /* XOGC has reached 4.. stop */	
		}
	xogc--;
	xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: try XOGC=%d\n", xogc); 
	usleep(15000);
	data[0]=0x07; /* register number 7, control byte 2 */
	data[1]=0x08 | xogc;
	I2C_WriteRead(&(f->d), (I2CByte *)data, 2, NULL, 0);	
	}
f->xogc=xogc;
/* wait before continuing */
usleep(15000); /* wait 50 milliseconds */
MT2032_dump_status(f);
}

static int MT2032_no_spur_in_band(MT2032_parameters *m)
{
int n_max, n1, n2;
double f_test;
n_max=5;
n1=1;
while(1){
	n2=-n1;
	f_test=n1*(m->f_lo1-m->f_lo2);
	while(1){
		n2--;
		f_test=f_test-m->f_lo2;
		xf86DrvMsg(0, X_INFO, "testing f_test=%g n1=%d n2=%d f_lo1=%g f_lo2=%g f_if2=%g\n", f_test, n1, n2, m->f_lo1, m->f_lo2, m->f_if2);  
		xf86DrvMsg(0, X_INFO, "d_f=%g f_ifbw=%g\n",fabs(fabs(f_test)-m->f_if2), m->f_ifbw);  
		if((fabs(fabs(f_test)-m->f_if2)*2.0)<=m->f_ifbw)return 0;
		if(n2<=-n_max)break;
  		/* this line in the manual is bogus. I say it is faster
		and more correct to go over all harmonics.. */
		#if 0
		if(f_test<(m->f_lo2-m->f_if2-m->f_ifbw))break; 
		#endif
		}
	n1++;
	if(n1>=n_max)return 1;
	}

}

static void MT2032_calculate_register_settings(MT2032_parameters *m, double f_rf, double f_if1, double f_if2, double f_ref, double f_ifbw, double f_step)
{
int n;
m->f_rf=f_rf;
m->f_if1=f_if1;
m->f_if2=f_if2;
m->f_ref=f_ref;
m->f_ifbw=f_ifbw;
m->f_step=f_step;

m->f_lo1=f_rf+f_if1;
m->LO1I=(int)floor((m->f_lo1/f_ref)+0.5);
m->f_lo1=f_ref*m->LO1I;

m->f_lo2=m->f_lo1-f_rf-f_if2;

/* check for spurs */
n=1;
while(n<3){
	if(MT2032_no_spur_in_band(m))break;
	if(m->f_lo1<(f_rf+f_if1)){
		m->LO1I+=n;
		} else {
		m->LO1I-=n;
		}
	m->f_lo1=m->LO1I*f_ref;
	m->f_lo2=m->f_lo1-f_rf-f_if2;
	n++;
	}
/* xf86DrvMsg(0, X_INFO, "MT2032: n=%d\n", n); */
/* select VCO */

/* m->f_lo1>1100.0 */
if(m->f_lo1<1370.0)m->SEL=4;
	else
if(m->f_lo1<1530.0)m->SEL=3;
	else
if(m->f_lo1<1720.0)m->SEL=2;
	else
if(m->f_lo1<1890.0)m->SEL=1;
	else  /* m->f_lo1 < 1958.0 */
	m->SEL=0;

/* calculate the rest of the registers */
m->LO2I=(int)floor(m->f_lo2/f_ref);
m->STEP=(int)floor(3780.0*f_step/f_ref);
m->NUM=(int)floor(3780.0*(m->f_lo2/f_ref-m->LO2I));
m->NUM=m->STEP*(int)floor((1.0*m->NUM)/(1.0*m->STEP)+0.5);
}

static int MT2032_wait_for_lock(FI1236Ptr f)
{
int n;
CARD8 data[10];
CARD8 value;

n=12;
while(1){
	data[0]=0x0e; /* register number 7, status */
	I2C_WriteRead(&(f->d), (I2CByte *)data, 1, &value, 1);
/*	xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: LO1LK=%d LO2LK=%d\n", (value & 0x04)>>2, (value & 0x02)>>1); */
	if((value & 6)==6) break;
	usleep(1500);
	n--;
	if(n<0)break;
	}
if(n<0){
	xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: failed to set frequency\n");
	return 0;
	}
return 1;
}

static void MT2032_implement_settings(FI1236Ptr f, MT2032_parameters *m)
{
CARD8 data[10];
CARD8 value;

data[0]=0x00;     /* start with register 0x00 */
data[1]=(m->LO1I>>3)-1;
data[2]=(m->SEL<<4)|(m->LO1I & 0x7);
data[3]=0x86;
I2C_WriteRead(&(f->d), (I2CByte *)data, 4, NULL, 0);

data[0]=0x05;     /* start with register 0x05 */
data[1]=((m->LO2I & 0x7)<<5)|((m->LO2I>>3)-1);
if(m->f_rf<400.0)data[2]=0xe4;
	else data[2]=0xf4;
I2C_WriteRead(&(f->d), (I2CByte *)data, 3, NULL, 0);

data[0]=0x07; /* register number 7, control byte 2 */
I2C_WriteRead(&(f->d), (I2CByte *)data, 1, &value, 1);
xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: using XOGC=%d\n", (value & 0x07));
data[1]=8 | (value & 0x7);
I2C_WriteRead(&(f->d), (I2CByte *)data, 2, NULL, 0);	

data[0]=0x0b;   /* start with register 0x0b */
data[1]=m->NUM & 0xff;
data[2]=(1<<7)|((m->NUM >> 8) & 0x0f);
I2C_WriteRead(&(f->d), (I2CByte *)data, 3, NULL, 0);

MT2032_wait_for_lock(f);
}

static void MT2032_optimize_VCO(FI1236Ptr f, MT2032_parameters *m)
{
CARD8 data[10];
CARD8 value;
CARD8 TAD1;

data[0]=0x0f; /* register number 7, status */
I2C_WriteRead(&(f->d), (I2CByte *)data, 1, &value, 1);
TAD1=value & 0x07;
xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: TAD1=%d SEL=%d\n", TAD1, m->SEL);
if(TAD1 < 2)return;
if(TAD1==2){
	if(m->SEL==0)return;
	m->SEL--;
	} else {
	if(m->SEL>=4)return;
	m->SEL++;
	}
data[0]=0x01;  /* start with register 1 */
data[1]=(m->SEL<<4)|(m->LO1I & 0x7);
I2C_WriteRead(&(f->d), (I2CByte *)data, 2, NULL, 0);

}

static int FI1236_get_afc_hint(FI1236Ptr f)
{
	CARD8 out;
	CARD8 AFC;

	if ((f->type == TUNER_TYPE_FM1216ME) || (f->type == TUNER_TYPE_FI1236W))
	{
		TDA9885Ptr t = (TDA9885Ptr)f->afc_source;
		if (t == NULL)
			return TUNER_OFF; 
		
		tda9885_getstatus(t);
		tda9885_dumpstatus(t);
		AFC = t->afc_status & 0x0f;

		xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "AFC: FI1236_get_afc_hint: %i\n", AFC);
		if (AFC == 0) return TUNER_TUNED;
		else if (AFC <= 0x07)return TUNER_JUST_BELOW;
		else if (AFC < 0x0f )return TUNER_JUST_ABOVE;
		else if (AFC == 0x0f)return TUNER_TUNED;
	}
	else
	{
		I2C_WriteRead(&(f->d), NULL, 0, &out, 1);
		AFC=out & 0x7;
		xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "AFC: FI1236_get_afc_hint: %i\n", AFC);
		if(AFC==2)return TUNER_TUNED;
		if(AFC==3)return TUNER_JUST_BELOW;
		if(AFC==1)return TUNER_JUST_ABOVE;
		return TUNER_OFF;
	}
	return TUNER_OFF;
}

static int MT2032_get_afc_hint(FI1236Ptr f)
{
CARD8 in;
CARD8 out[2];
CARD8 AFC;
in=0x0e;
I2C_WriteRead(&(f->d), (I2CByte *)&in, 1, out, 2);
AFC=(out[0]>>4) & 0x7;
#if 0
xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "AFC=%d TAD1=%d TAD2=%d\n", AFC, out[1] & 0x7, (out[1]>>4)& 0x07);
#endif
if(AFC==2)return TUNER_TUNED;
if(AFC==3)return TUNER_JUST_BELOW;
if(AFC==1)return TUNER_JUST_ABOVE;
return TUNER_OFF;
}

/* this function is for external use only */
int TUNER_get_afc_hint(FI1236Ptr f)
{
if(f->afc_timer_installed)return TUNER_STILL_TUNING;
return f->last_afc_hint;
if(f->type==TUNER_TYPE_MT2032)
	return MT2032_get_afc_hint(f);
	else
	return FI1236_get_afc_hint(f);
}

static void MT2032_dump_status(FI1236Ptr f)
{
CARD8 in;
CARD8 out[2];
CARD8 AFC;
CARD8 LDONrb;
CARD8 LO1LK, LO2LK, XOK;
CARD8 TAD2, TAD1;

in=0x0e;
I2C_WriteRead(&(f->d), (I2CByte *)&in, 1, out, 2);
XOK=out[0] & 1;
LO1LK=(out[0]>>2) &1;
LO2LK=(out[0]>>1) &1;
LDONrb=(out[0]>>3) &1;

AFC=(out[0]>>4) & 0x7;

TAD1=(out[1] & 0x7);
TAD2=(out[1]>>4) & 0x7;

xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: status: XOK=%d LO1LK=%d LO2LK=%d LDONrb=%d AFC=%d TAD1=%d TAD2=%d\n", 
	XOK, LO1LK, LO2LK, LDONrb, AFC, TAD1, TAD2);
xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: status: OSCILLATOR:%s PLL1:%s PLL2:%s\n", 
	XOK ? "ok":"off", LO1LK ? "locked" : "off" , LO2LK ? "locked" : "off");

}

static void MT2032_tune(FI1236Ptr f, double freq, double step)
{
MT2032_parameters m;
CARD8 data[10];
int i;
/* NTSC IF is 44mhz.. but 733/16=45.8125 and all TDAXXXX docs mention
     45.75, 39, 58.75 and 30. */
#if 0
MT2032_calculate_register_settings(&m, freq, 1090.0, 45.125, 5.25, 6.0, step);
MT2032_calculate_register_settings(&m, freq, 1090.0, 45.74, 5.25, 6.0, step);
#endif
MT2032_calculate_register_settings(&m, freq, 1090.0, f->video_if, 5.25, 3.0, step);
MT2032_dump_parameters(f, &m);
MT2032_implement_settings(f, &m);
/* MT2032_dump_parameters(f, &m); */
for(i=0;i<3;i++){
	MT2032_optimize_VCO(f, &m);
	if(MT2032_wait_for_lock(f)){
		data[0]=0x02;  /* LO Gain control register 0x02 */
		data[1]=0x20;
		I2C_WriteRead(&(f->d), (I2CByte *)data, 2, NULL, 0);
		return;
		}
	data[0]=0x07;
	data[1]=0x88|f->xogc;
	I2C_WriteRead(&(f->d), (I2CByte *)data, 2, NULL, 0);
	usleep(15000);
	data[1]=0x08|f->xogc;
	I2C_WriteRead(&(f->d), (I2CByte *)data, 2, NULL, 0);	
	}
xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "MT2032: failed to set frequency\n");
}

void FI1236_set_tuner_type(FI1236Ptr f, int type)
{
f->type=type;
if(type>=NUM_TUNERS)type = NUM_TUNERS-1;
if(type<0)type = 0;
memcpy(&(f->parm), &(tuner_parms[type]), sizeof(FI1236_parameters));
f->original_frequency=f->parm.min_freq;
f->afc_delta=0;
if(type==TUNER_TYPE_MT2032){
	MT2032_init(f);
	return;
	}
}


static CARD32 AFC_TimerCallback(OsTimerPtr timer, CARD32 time, pointer data){
FI1236Ptr f=(FI1236Ptr)data;
if(FI1236_AFC(f))return 150;
	else {
	f->afc_timer_installed=FALSE;
	f->afc_count=0;
	return 0;
	}
}

void FI1236_tune(FI1236Ptr f, CARD32 frequency)
{
    CARD16 divider;
	 CARD8 data;

    if(frequency < f->parm.min_freq) frequency = f->parm.min_freq;
    if(frequency > f->parm.max_freq) frequency = f->parm.max_freq;

    divider = (f->parm.fcar+(CARD16)frequency) & 0x7fff;
    f->tuner_data.div1 = (CARD8)((divider>>8)&0x7f);
    f->tuner_data.div2 = (CARD8)(divider & 0xff);
    f->tuner_data.control = f->parm.control; 

    if(frequency < f->parm.threshold1)
    {
        f->tuner_data.band = f->parm.band_low;
    } 
    else if (frequency < f->parm.threshold2)
    {
        f->tuner_data.band = f->parm.band_mid;
    }
    else
    {
        f->tuner_data.band = f->parm.band_high;
    }

	 xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "Setting tuner band to %d\n", f->tuner_data.band);

    xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "Setting tuner frequency to %d\n", (int)frequency);

	 if ((f->type == TUNER_TYPE_FM1216ME) || (f->type == TUNER_TYPE_FI1236W))
	 {
				f->tuner_data.aux = 0x20;
				I2C_WriteRead(&(f->d), (I2CByte *)&(f->tuner_data), 5, NULL, 0);
				I2C_WriteRead(&(f->d), NULL, 0, &data, 1);
				xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "Tuner status %x\n", data);

	 }
	 else
				I2C_WriteRead(&(f->d), (I2CByte *)&(f->tuner_data), 4, NULL, 0);
}

void TUNER_set_frequency(FI1236Ptr f, CARD32 frequency)
{
    if(frequency < f->parm.min_freq) frequency = f->parm.min_freq;
    if(frequency > f->parm.max_freq) frequency = f->parm.max_freq;

    f->afc_delta=0;
    f->original_frequency=frequency;

    if(f->type==TUNER_TYPE_MT2032)
        {
    	MT2032_tune(f, (1.0*frequency)/16.0, 0.0625);
	} else 
	{
	FI1236_tune(f, frequency);
	}
    
    if(!f->afc_timer_installed)
        {
     	f->afc_timer_installed=TRUE;
/*     	RegisterBlockAndWakeupHandlers(FI1236_BlockHandler, AFCWakeup, f); */
	TimerSet(NULL, 0, 300, AFC_TimerCallback, f);
	}
	
}


int FI1236_AFC(FI1236Ptr f)
{
    #if 0
    xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "AFC: f=%p f->count=%d f->original_frequency=%d f->afc_delta=%d\n", f, f->afc_count, f->original_frequency, f->afc_delta);
    #endif
    f->afc_count++;
    if(f->type==TUNER_TYPE_MT2032)
        {
    	f->last_afc_hint=MT2032_get_afc_hint(f);
        xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "AFC: afc_hint=%d\n", f->last_afc_hint);
	if(f->last_afc_hint==TUNER_TUNED)return 0;
	if(f->afc_count>3)f->last_afc_hint=TUNER_OFF;
	if(f->last_afc_hint==TUNER_OFF)
	        {
		f->afc_delta=0;
		} else
		f->afc_delta+=f->last_afc_hint;
        xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "AFC: Setting tuner frequency to %g\n", (0.5*(2*f->original_frequency+f->afc_delta))/16.0);
    	MT2032_tune(f, (1.0*f->original_frequency+0.5*f->afc_delta)/16.0, 0.03125);
	if(f->last_afc_hint==TUNER_OFF)return 0;
	return 1; /* call me again */
	} else 
	{
    	f->last_afc_hint=FI1236_get_afc_hint(f);
	if(f->last_afc_hint==TUNER_TUNED)
	{
			  xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "AFC: TUNER_TUNNED\n");
			  return 0;
	}
	if(f->afc_count>3)f->last_afc_hint=TUNER_OFF;
	if(f->last_afc_hint==TUNER_OFF)
	        {
		f->afc_delta=0;
		} else
		f->afc_delta+=f->last_afc_hint;
        xf86DrvMsg(f->d.pI2CBus->scrnIndex, X_INFO, "AFC: Setting tuner frequency to %g\n", (0.5*(2*f->original_frequency+f->afc_delta))/16.0);
	FI1236_tune(f, f->original_frequency+f->afc_delta);
	if(f->last_afc_hint==TUNER_OFF)return 0;
	return 1; /* call me again */
	}
    return 0; /* done */
}

void fi1236_dump_status(FI1236Ptr f)
{
if(f->type==TUNER_TYPE_MT2032){
	MT2032_dump_status(f);
	}
}

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