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linux/drivers/media/dvb-frontends/drxd_hard.c
Thomas Gleixner 89ee7f4f33 treewide: Replace GPLv2 boilerplate/reference with SPDX - rule 461
Based on 1 normalized pattern(s):

  this program is free software you can redistribute it and or modify
  it under the terms of the gnu general public license version 2 only
  as published by the free software foundation this program is
  distributed in the hope that it will be useful but without any
  warranty without even the implied warranty of merchantability or
  fitness for a particular purpose see the gnu general public license
  for more details to obtain the license point your browser to http
  www gnu org copyleft gpl html

extracted by the scancode license scanner the SPDX license identifier

  GPL-2.0-only

has been chosen to replace the boilerplate/reference in 12 file(s).

Signed-off-by: Thomas Gleixner <tglx@linutronix.de>
Reviewed-by: Allison Randal <allison@lohutok.net>
Reviewed-by: Enrico Weigelt <info@metux.net>
Cc: linux-spdx@vger.kernel.org
Link: https://lkml.kernel.org/r/20190604081202.028166291@linutronix.de
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-06-19 17:09:09 +02:00

2956 lines
74 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* drxd_hard.c: DVB-T Demodulator Micronas DRX3975D-A2,DRX397xD-B1
*
* Copyright (C) 2003-2007 Micronas
*/
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/moduleparam.h>
#include <linux/init.h>
#include <linux/delay.h>
#include <linux/firmware.h>
#include <linux/i2c.h>
#include <asm/div64.h>
#include <media/dvb_frontend.h>
#include "drxd.h"
#include "drxd_firm.h"
#define DRX_FW_FILENAME_A2 "drxd-a2-1.1.fw"
#define DRX_FW_FILENAME_B1 "drxd-b1-1.1.fw"
#define CHUNK_SIZE 48
#define DRX_I2C_RMW 0x10
#define DRX_I2C_BROADCAST 0x20
#define DRX_I2C_CLEARCRC 0x80
#define DRX_I2C_SINGLE_MASTER 0xC0
#define DRX_I2C_MODEFLAGS 0xC0
#define DRX_I2C_FLAGS 0xF0
#define DEFAULT_LOCK_TIMEOUT 1100
#define DRX_CHANNEL_AUTO 0
#define DRX_CHANNEL_HIGH 1
#define DRX_CHANNEL_LOW 2
#define DRX_LOCK_MPEG 1
#define DRX_LOCK_FEC 2
#define DRX_LOCK_DEMOD 4
/****************************************************************************/
enum CSCDState {
CSCD_INIT = 0,
CSCD_SET,
CSCD_SAVED
};
enum CDrxdState {
DRXD_UNINITIALIZED = 0,
DRXD_STOPPED,
DRXD_STARTED
};
enum AGC_CTRL_MODE {
AGC_CTRL_AUTO = 0,
AGC_CTRL_USER,
AGC_CTRL_OFF
};
enum OperationMode {
OM_Default,
OM_DVBT_Diversity_Front,
OM_DVBT_Diversity_End
};
struct SCfgAgc {
enum AGC_CTRL_MODE ctrlMode;
u16 outputLevel; /* range [0, ... , 1023], 1/n of fullscale range */
u16 settleLevel; /* range [0, ... , 1023], 1/n of fullscale range */
u16 minOutputLevel; /* range [0, ... , 1023], 1/n of fullscale range */
u16 maxOutputLevel; /* range [0, ... , 1023], 1/n of fullscale range */
u16 speed; /* range [0, ... , 1023], 1/n of fullscale range */
u16 R1;
u16 R2;
u16 R3;
};
struct SNoiseCal {
int cpOpt;
short cpNexpOfs;
short tdCal2k;
short tdCal8k;
};
enum app_env {
APPENV_STATIC = 0,
APPENV_PORTABLE = 1,
APPENV_MOBILE = 2
};
enum EIFFilter {
IFFILTER_SAW = 0,
IFFILTER_DISCRETE = 1
};
struct drxd_state {
struct dvb_frontend frontend;
struct dvb_frontend_ops ops;
struct dtv_frontend_properties props;
const struct firmware *fw;
struct device *dev;
struct i2c_adapter *i2c;
void *priv;
struct drxd_config config;
int i2c_access;
int init_done;
struct mutex mutex;
u8 chip_adr;
u16 hi_cfg_timing_div;
u16 hi_cfg_bridge_delay;
u16 hi_cfg_wakeup_key;
u16 hi_cfg_ctrl;
u16 intermediate_freq;
u16 osc_clock_freq;
enum CSCDState cscd_state;
enum CDrxdState drxd_state;
u16 sys_clock_freq;
s16 osc_clock_deviation;
u16 expected_sys_clock_freq;
u16 insert_rs_byte;
u16 enable_parallel;
int operation_mode;
struct SCfgAgc if_agc_cfg;
struct SCfgAgc rf_agc_cfg;
struct SNoiseCal noise_cal;
u32 fe_fs_add_incr;
u32 org_fe_fs_add_incr;
u16 current_fe_if_incr;
u16 m_FeAgRegAgPwd;
u16 m_FeAgRegAgAgcSio;
u16 m_EcOcRegOcModeLop;
u16 m_EcOcRegSncSncLvl;
u8 *m_InitAtomicRead;
u8 *m_HiI2cPatch;
u8 *m_ResetCEFR;
u8 *m_InitFE_1;
u8 *m_InitFE_2;
u8 *m_InitCP;
u8 *m_InitCE;
u8 *m_InitEQ;
u8 *m_InitSC;
u8 *m_InitEC;
u8 *m_ResetECRAM;
u8 *m_InitDiversityFront;
u8 *m_InitDiversityEnd;
u8 *m_DisableDiversity;
u8 *m_StartDiversityFront;
u8 *m_StartDiversityEnd;
u8 *m_DiversityDelay8MHZ;
u8 *m_DiversityDelay6MHZ;
u8 *microcode;
u32 microcode_length;
int type_A;
int PGA;
int diversity;
int tuner_mirrors;
enum app_env app_env_default;
enum app_env app_env_diversity;
};
/****************************************************************************/
/* I2C **********************************************************************/
/****************************************************************************/
static int i2c_write(struct i2c_adapter *adap, u8 adr, u8 * data, int len)
{
struct i2c_msg msg = {.addr = adr, .flags = 0, .buf = data, .len = len };
if (i2c_transfer(adap, &msg, 1) != 1)
return -1;
return 0;
}
static int i2c_read(struct i2c_adapter *adap,
u8 adr, u8 *msg, int len, u8 *answ, int alen)
{
struct i2c_msg msgs[2] = {
{
.addr = adr, .flags = 0,
.buf = msg, .len = len
}, {
.addr = adr, .flags = I2C_M_RD,
.buf = answ, .len = alen
}
};
if (i2c_transfer(adap, msgs, 2) != 2)
return -1;
return 0;
}
static inline u32 MulDiv32(u32 a, u32 b, u32 c)
{
u64 tmp64;
tmp64 = (u64)a * (u64)b;
do_div(tmp64, c);
return (u32) tmp64;
}
static int Read16(struct drxd_state *state, u32 reg, u16 *data, u8 flags)
{
u8 adr = state->config.demod_address;
u8 mm1[4] = { reg & 0xff, (reg >> 16) & 0xff,
flags | ((reg >> 24) & 0xff), (reg >> 8) & 0xff
};
u8 mm2[2];
if (i2c_read(state->i2c, adr, mm1, 4, mm2, 2) < 0)
return -1;
if (data)
*data = mm2[0] | (mm2[1] << 8);
return mm2[0] | (mm2[1] << 8);
}
static int Read32(struct drxd_state *state, u32 reg, u32 *data, u8 flags)
{
u8 adr = state->config.demod_address;
u8 mm1[4] = { reg & 0xff, (reg >> 16) & 0xff,
flags | ((reg >> 24) & 0xff), (reg >> 8) & 0xff
};
u8 mm2[4];
if (i2c_read(state->i2c, adr, mm1, 4, mm2, 4) < 0)
return -1;
if (data)
*data =
mm2[0] | (mm2[1] << 8) | (mm2[2] << 16) | (mm2[3] << 24);
return 0;
}
static int Write16(struct drxd_state *state, u32 reg, u16 data, u8 flags)
{
u8 adr = state->config.demod_address;
u8 mm[6] = { reg & 0xff, (reg >> 16) & 0xff,
flags | ((reg >> 24) & 0xff), (reg >> 8) & 0xff,
data & 0xff, (data >> 8) & 0xff
};
if (i2c_write(state->i2c, adr, mm, 6) < 0)
return -1;
return 0;
}
static int Write32(struct drxd_state *state, u32 reg, u32 data, u8 flags)
{
u8 adr = state->config.demod_address;
u8 mm[8] = { reg & 0xff, (reg >> 16) & 0xff,
flags | ((reg >> 24) & 0xff), (reg >> 8) & 0xff,
data & 0xff, (data >> 8) & 0xff,
(data >> 16) & 0xff, (data >> 24) & 0xff
};
if (i2c_write(state->i2c, adr, mm, 8) < 0)
return -1;
return 0;
}
static int write_chunk(struct drxd_state *state,
u32 reg, u8 *data, u32 len, u8 flags)
{
u8 adr = state->config.demod_address;
u8 mm[CHUNK_SIZE + 4] = { reg & 0xff, (reg >> 16) & 0xff,
flags | ((reg >> 24) & 0xff), (reg >> 8) & 0xff
};
int i;
for (i = 0; i < len; i++)
mm[4 + i] = data[i];
if (i2c_write(state->i2c, adr, mm, 4 + len) < 0) {
printk(KERN_ERR "error in write_chunk\n");
return -1;
}
return 0;
}
static int WriteBlock(struct drxd_state *state,
u32 Address, u16 BlockSize, u8 *pBlock, u8 Flags)
{
while (BlockSize > 0) {
u16 Chunk = BlockSize > CHUNK_SIZE ? CHUNK_SIZE : BlockSize;
if (write_chunk(state, Address, pBlock, Chunk, Flags) < 0)
return -1;
pBlock += Chunk;
Address += (Chunk >> 1);
BlockSize -= Chunk;
}
return 0;
}
static int WriteTable(struct drxd_state *state, u8 * pTable)
{
int status = 0;
if (!pTable)
return 0;
while (!status) {
u16 Length;
u32 Address = pTable[0] | (pTable[1] << 8) |
(pTable[2] << 16) | (pTable[3] << 24);
if (Address == 0xFFFFFFFF)
break;
pTable += sizeof(u32);
Length = pTable[0] | (pTable[1] << 8);
pTable += sizeof(u16);
if (!Length)
break;
status = WriteBlock(state, Address, Length * 2, pTable, 0);
pTable += (Length * 2);
}
return status;
}
/****************************************************************************/
/****************************************************************************/
/****************************************************************************/
static int ResetCEFR(struct drxd_state *state)
{
return WriteTable(state, state->m_ResetCEFR);
}
static int InitCP(struct drxd_state *state)
{
return WriteTable(state, state->m_InitCP);
}
static int InitCE(struct drxd_state *state)
{
int status;
enum app_env AppEnv = state->app_env_default;
do {
status = WriteTable(state, state->m_InitCE);
if (status < 0)
break;
if (state->operation_mode == OM_DVBT_Diversity_Front ||
state->operation_mode == OM_DVBT_Diversity_End) {
AppEnv = state->app_env_diversity;
}
if (AppEnv == APPENV_STATIC) {
status = Write16(state, CE_REG_TAPSET__A, 0x0000, 0);
if (status < 0)
break;
} else if (AppEnv == APPENV_PORTABLE) {
status = Write16(state, CE_REG_TAPSET__A, 0x0001, 0);
if (status < 0)
break;
} else if (AppEnv == APPENV_MOBILE && state->type_A) {
status = Write16(state, CE_REG_TAPSET__A, 0x0002, 0);
if (status < 0)
break;
} else if (AppEnv == APPENV_MOBILE && !state->type_A) {
status = Write16(state, CE_REG_TAPSET__A, 0x0006, 0);
if (status < 0)
break;
}
/* start ce */
status = Write16(state, B_CE_REG_COMM_EXEC__A, 0x0001, 0);
if (status < 0)
break;
} while (0);
return status;
}
static int StopOC(struct drxd_state *state)
{
int status = 0;
u16 ocSyncLvl = 0;
u16 ocModeLop = state->m_EcOcRegOcModeLop;
u16 dtoIncLop = 0;
u16 dtoIncHip = 0;
do {
/* Store output configuration */
status = Read16(state, EC_OC_REG_SNC_ISC_LVL__A, &ocSyncLvl, 0);
if (status < 0)
break;
/* CHK_ERROR(Read16(EC_OC_REG_OC_MODE_LOP__A, &ocModeLop)); */
state->m_EcOcRegSncSncLvl = ocSyncLvl;
/* m_EcOcRegOcModeLop = ocModeLop; */
/* Flush FIFO (byte-boundary) at fixed rate */
status = Read16(state, EC_OC_REG_RCN_MAP_LOP__A, &dtoIncLop, 0);
if (status < 0)
break;
status = Read16(state, EC_OC_REG_RCN_MAP_HIP__A, &dtoIncHip, 0);
if (status < 0)
break;
status = Write16(state, EC_OC_REG_DTO_INC_LOP__A, dtoIncLop, 0);
if (status < 0)
break;
status = Write16(state, EC_OC_REG_DTO_INC_HIP__A, dtoIncHip, 0);
if (status < 0)
break;
ocModeLop &= ~(EC_OC_REG_OC_MODE_LOP_DTO_CTR_SRC__M);
ocModeLop |= EC_OC_REG_OC_MODE_LOP_DTO_CTR_SRC_STATIC;
status = Write16(state, EC_OC_REG_OC_MODE_LOP__A, ocModeLop, 0);
if (status < 0)
break;
status = Write16(state, EC_OC_REG_COMM_EXEC__A, EC_OC_REG_COMM_EXEC_CTL_HOLD, 0);
if (status < 0)
break;
msleep(1);
/* Output pins to '0' */
status = Write16(state, EC_OC_REG_OCR_MPG_UOS__A, EC_OC_REG_OCR_MPG_UOS__M, 0);
if (status < 0)
break;
/* Force the OC out of sync */
ocSyncLvl &= ~(EC_OC_REG_SNC_ISC_LVL_OSC__M);
status = Write16(state, EC_OC_REG_SNC_ISC_LVL__A, ocSyncLvl, 0);
if (status < 0)
break;
ocModeLop &= ~(EC_OC_REG_OC_MODE_LOP_PAR_ENA__M);
ocModeLop |= EC_OC_REG_OC_MODE_LOP_PAR_ENA_ENABLE;
ocModeLop |= 0x2; /* Magically-out-of-sync */
status = Write16(state, EC_OC_REG_OC_MODE_LOP__A, ocModeLop, 0);
if (status < 0)
break;
status = Write16(state, EC_OC_REG_COMM_INT_STA__A, 0x0, 0);
if (status < 0)
break;
status = Write16(state, EC_OC_REG_COMM_EXEC__A, EC_OC_REG_COMM_EXEC_CTL_ACTIVE, 0);
if (status < 0)
break;
} while (0);
return status;
}
static int StartOC(struct drxd_state *state)
{
int status = 0;
do {
/* Stop OC */
status = Write16(state, EC_OC_REG_COMM_EXEC__A, EC_OC_REG_COMM_EXEC_CTL_HOLD, 0);
if (status < 0)
break;
/* Restore output configuration */
status = Write16(state, EC_OC_REG_SNC_ISC_LVL__A, state->m_EcOcRegSncSncLvl, 0);
if (status < 0)
break;
status = Write16(state, EC_OC_REG_OC_MODE_LOP__A, state->m_EcOcRegOcModeLop, 0);
if (status < 0)
break;
/* Output pins active again */
status = Write16(state, EC_OC_REG_OCR_MPG_UOS__A, EC_OC_REG_OCR_MPG_UOS_INIT, 0);
if (status < 0)
break;
/* Start OC */
status = Write16(state, EC_OC_REG_COMM_EXEC__A, EC_OC_REG_COMM_EXEC_CTL_ACTIVE, 0);
if (status < 0)
break;
} while (0);
return status;
}
static int InitEQ(struct drxd_state *state)
{
return WriteTable(state, state->m_InitEQ);
}
static int InitEC(struct drxd_state *state)
{
return WriteTable(state, state->m_InitEC);
}
static int InitSC(struct drxd_state *state)
{
return WriteTable(state, state->m_InitSC);
}
static int InitAtomicRead(struct drxd_state *state)
{
return WriteTable(state, state->m_InitAtomicRead);
}
static int CorrectSysClockDeviation(struct drxd_state *state);
static int DRX_GetLockStatus(struct drxd_state *state, u32 * pLockStatus)
{
u16 ScRaRamLock = 0;
const u16 mpeg_lock_mask = (SC_RA_RAM_LOCK_MPEG__M |
SC_RA_RAM_LOCK_FEC__M |
SC_RA_RAM_LOCK_DEMOD__M);
const u16 fec_lock_mask = (SC_RA_RAM_LOCK_FEC__M |
SC_RA_RAM_LOCK_DEMOD__M);
const u16 demod_lock_mask = SC_RA_RAM_LOCK_DEMOD__M;
int status;
*pLockStatus = 0;
status = Read16(state, SC_RA_RAM_LOCK__A, &ScRaRamLock, 0x0000);
if (status < 0) {
printk(KERN_ERR "Can't read SC_RA_RAM_LOCK__A status = %08x\n", status);
return status;
}
if (state->drxd_state != DRXD_STARTED)
return 0;
if ((ScRaRamLock & mpeg_lock_mask) == mpeg_lock_mask) {
*pLockStatus |= DRX_LOCK_MPEG;
CorrectSysClockDeviation(state);
}
if ((ScRaRamLock & fec_lock_mask) == fec_lock_mask)
*pLockStatus |= DRX_LOCK_FEC;
if ((ScRaRamLock & demod_lock_mask) == demod_lock_mask)
*pLockStatus |= DRX_LOCK_DEMOD;
return 0;
}
/****************************************************************************/
static int SetCfgIfAgc(struct drxd_state *state, struct SCfgAgc *cfg)
{
int status;
if (cfg->outputLevel > DRXD_FE_CTRL_MAX)
return -1;
if (cfg->ctrlMode == AGC_CTRL_USER) {
do {
u16 FeAgRegPm1AgcWri;
u16 FeAgRegAgModeLop;
status = Read16(state, FE_AG_REG_AG_MODE_LOP__A, &FeAgRegAgModeLop, 0);
if (status < 0)
break;
FeAgRegAgModeLop &= (~FE_AG_REG_AG_MODE_LOP_MODE_4__M);
FeAgRegAgModeLop |= FE_AG_REG_AG_MODE_LOP_MODE_4_STATIC;
status = Write16(state, FE_AG_REG_AG_MODE_LOP__A, FeAgRegAgModeLop, 0);
if (status < 0)
break;
FeAgRegPm1AgcWri = (u16) (cfg->outputLevel &
FE_AG_REG_PM1_AGC_WRI__M);
status = Write16(state, FE_AG_REG_PM1_AGC_WRI__A, FeAgRegPm1AgcWri, 0);
if (status < 0)
break;
} while (0);
} else if (cfg->ctrlMode == AGC_CTRL_AUTO) {
if (((cfg->maxOutputLevel) < (cfg->minOutputLevel)) ||
((cfg->maxOutputLevel) > DRXD_FE_CTRL_MAX) ||
((cfg->speed) > DRXD_FE_CTRL_MAX) ||
((cfg->settleLevel) > DRXD_FE_CTRL_MAX)
)
return -1;
do {
u16 FeAgRegAgModeLop;
u16 FeAgRegEgcSetLvl;
u16 slope, offset;
/* == Mode == */
status = Read16(state, FE_AG_REG_AG_MODE_LOP__A, &FeAgRegAgModeLop, 0);
if (status < 0)
break;
FeAgRegAgModeLop &= (~FE_AG_REG_AG_MODE_LOP_MODE_4__M);
FeAgRegAgModeLop |=
FE_AG_REG_AG_MODE_LOP_MODE_4_DYNAMIC;
status = Write16(state, FE_AG_REG_AG_MODE_LOP__A, FeAgRegAgModeLop, 0);
if (status < 0)
break;
/* == Settle level == */
FeAgRegEgcSetLvl = (u16) ((cfg->settleLevel >> 1) &
FE_AG_REG_EGC_SET_LVL__M);
status = Write16(state, FE_AG_REG_EGC_SET_LVL__A, FeAgRegEgcSetLvl, 0);
if (status < 0)
break;
/* == Min/Max == */
slope = (u16) ((cfg->maxOutputLevel -
cfg->minOutputLevel) / 2);
offset = (u16) ((cfg->maxOutputLevel +
cfg->minOutputLevel) / 2 - 511);
status = Write16(state, FE_AG_REG_GC1_AGC_RIC__A, slope, 0);
if (status < 0)
break;
status = Write16(state, FE_AG_REG_GC1_AGC_OFF__A, offset, 0);
if (status < 0)
break;
/* == Speed == */
{
const u16 maxRur = 8;
static const u16 slowIncrDecLUT[] = {
3, 4, 4, 5, 6 };
static const u16 fastIncrDecLUT[] = {
14, 15, 15, 16,
17, 18, 18, 19,
20, 21, 22, 23,
24, 26, 27, 28,
29, 31
};
u16 fineSteps = (DRXD_FE_CTRL_MAX + 1) /
(maxRur + 1);
u16 fineSpeed = (u16) (cfg->speed -
((cfg->speed /
fineSteps) *
fineSteps));
u16 invRurCount = (u16) (cfg->speed /
fineSteps);
u16 rurCount;
if (invRurCount > maxRur) {
rurCount = 0;
fineSpeed += fineSteps;
} else {
rurCount = maxRur - invRurCount;
}
/*
fastInc = default *
(2^(fineSpeed/fineSteps))
=> range[default...2*default>
slowInc = default *
(2^(fineSpeed/fineSteps))
*/
{
u16 fastIncrDec =
fastIncrDecLUT[fineSpeed /
((fineSteps /
(14 + 1)) + 1)];
u16 slowIncrDec =
slowIncrDecLUT[fineSpeed /
(fineSteps /
(3 + 1))];
status = Write16(state, FE_AG_REG_EGC_RUR_CNT__A, rurCount, 0);
if (status < 0)
break;
status = Write16(state, FE_AG_REG_EGC_FAS_INC__A, fastIncrDec, 0);
if (status < 0)
break;
status = Write16(state, FE_AG_REG_EGC_FAS_DEC__A, fastIncrDec, 0);
if (status < 0)
break;
status = Write16(state, FE_AG_REG_EGC_SLO_INC__A, slowIncrDec, 0);
if (status < 0)
break;
status = Write16(state, FE_AG_REG_EGC_SLO_DEC__A, slowIncrDec, 0);
if (status < 0)
break;
}
}
} while (0);
} else {
/* No OFF mode for IF control */
return -1;
}
return status;
}
static int SetCfgRfAgc(struct drxd_state *state, struct SCfgAgc *cfg)
{
int status = 0;
if (cfg->outputLevel > DRXD_FE_CTRL_MAX)
return -1;
if (cfg->ctrlMode == AGC_CTRL_USER) {
do {
u16 AgModeLop = 0;
u16 level = (cfg->outputLevel);
if (level == DRXD_FE_CTRL_MAX)
level++;
status = Write16(state, FE_AG_REG_PM2_AGC_WRI__A, level, 0x0000);
if (status < 0)
break;
/*==== Mode ====*/
/* Powerdown PD2, WRI source */
state->m_FeAgRegAgPwd &= ~(FE_AG_REG_AG_PWD_PWD_PD2__M);
state->m_FeAgRegAgPwd |=
FE_AG_REG_AG_PWD_PWD_PD2_DISABLE;
status = Write16(state, FE_AG_REG_AG_PWD__A, state->m_FeAgRegAgPwd, 0x0000);
if (status < 0)
break;
status = Read16(state, FE_AG_REG_AG_MODE_LOP__A, &AgModeLop, 0x0000);
if (status < 0)
break;
AgModeLop &= (~(FE_AG_REG_AG_MODE_LOP_MODE_5__M |
FE_AG_REG_AG_MODE_LOP_MODE_E__M));
AgModeLop |= (FE_AG_REG_AG_MODE_LOP_MODE_5_STATIC |
FE_AG_REG_AG_MODE_LOP_MODE_E_STATIC);
status = Write16(state, FE_AG_REG_AG_MODE_LOP__A, AgModeLop, 0x0000);
if (status < 0)
break;
/* enable AGC2 pin */
{
u16 FeAgRegAgAgcSio = 0;
status = Read16(state, FE_AG_REG_AG_AGC_SIO__A, &FeAgRegAgAgcSio, 0x0000);
if (status < 0)
break;
FeAgRegAgAgcSio &=
~(FE_AG_REG_AG_AGC_SIO_AGC_SIO_2__M);
FeAgRegAgAgcSio |=
FE_AG_REG_AG_AGC_SIO_AGC_SIO_2_OUTPUT;
status = Write16(state, FE_AG_REG_AG_AGC_SIO__A, FeAgRegAgAgcSio, 0x0000);
if (status < 0)
break;
}
} while (0);
} else if (cfg->ctrlMode == AGC_CTRL_AUTO) {
u16 AgModeLop = 0;
do {
u16 level;
/* Automatic control */
/* Powerup PD2, AGC2 as output, TGC source */
(state->m_FeAgRegAgPwd) &=
~(FE_AG_REG_AG_PWD_PWD_PD2__M);
(state->m_FeAgRegAgPwd) |=
FE_AG_REG_AG_PWD_PWD_PD2_DISABLE;
status = Write16(state, FE_AG_REG_AG_PWD__A, (state->m_FeAgRegAgPwd), 0x0000);
if (status < 0)
break;
status = Read16(state, FE_AG_REG_AG_MODE_LOP__A, &AgModeLop, 0x0000);
if (status < 0)
break;
AgModeLop &= (~(FE_AG_REG_AG_MODE_LOP_MODE_5__M |
FE_AG_REG_AG_MODE_LOP_MODE_E__M));
AgModeLop |= (FE_AG_REG_AG_MODE_LOP_MODE_5_STATIC |
FE_AG_REG_AG_MODE_LOP_MODE_E_DYNAMIC);
status = Write16(state, FE_AG_REG_AG_MODE_LOP__A, AgModeLop, 0x0000);
if (status < 0)
break;
/* Settle level */
level = (((cfg->settleLevel) >> 4) &
FE_AG_REG_TGC_SET_LVL__M);
status = Write16(state, FE_AG_REG_TGC_SET_LVL__A, level, 0x0000);
if (status < 0)
break;
/* Min/max: don't care */
/* Speed: TODO */
/* enable AGC2 pin */
{
u16 FeAgRegAgAgcSio = 0;
status = Read16(state, FE_AG_REG_AG_AGC_SIO__A, &FeAgRegAgAgcSio, 0x0000);
if (status < 0)
break;
FeAgRegAgAgcSio &=
~(FE_AG_REG_AG_AGC_SIO_AGC_SIO_2__M);
FeAgRegAgAgcSio |=
FE_AG_REG_AG_AGC_SIO_AGC_SIO_2_OUTPUT;
status = Write16(state, FE_AG_REG_AG_AGC_SIO__A, FeAgRegAgAgcSio, 0x0000);
if (status < 0)
break;
}
} while (0);
} else {
u16 AgModeLop = 0;
do {
/* No RF AGC control */
/* Powerdown PD2, AGC2 as output, WRI source */
(state->m_FeAgRegAgPwd) &=
~(FE_AG_REG_AG_PWD_PWD_PD2__M);
(state->m_FeAgRegAgPwd) |=
FE_AG_REG_AG_PWD_PWD_PD2_ENABLE;
status = Write16(state, FE_AG_REG_AG_PWD__A, (state->m_FeAgRegAgPwd), 0x0000);
if (status < 0)
break;
status = Read16(state, FE_AG_REG_AG_MODE_LOP__A, &AgModeLop, 0x0000);
if (status < 0)
break;
AgModeLop &= (~(FE_AG_REG_AG_MODE_LOP_MODE_5__M |
FE_AG_REG_AG_MODE_LOP_MODE_E__M));
AgModeLop |= (FE_AG_REG_AG_MODE_LOP_MODE_5_STATIC |
FE_AG_REG_AG_MODE_LOP_MODE_E_STATIC);
status = Write16(state, FE_AG_REG_AG_MODE_LOP__A, AgModeLop, 0x0000);
if (status < 0)
break;
/* set FeAgRegAgAgcSio AGC2 (RF) as input */
{
u16 FeAgRegAgAgcSio = 0;
status = Read16(state, FE_AG_REG_AG_AGC_SIO__A, &FeAgRegAgAgcSio, 0x0000);
if (status < 0)
break;
FeAgRegAgAgcSio &=
~(FE_AG_REG_AG_AGC_SIO_AGC_SIO_2__M);
FeAgRegAgAgcSio |=
FE_AG_REG_AG_AGC_SIO_AGC_SIO_2_INPUT;
status = Write16(state, FE_AG_REG_AG_AGC_SIO__A, FeAgRegAgAgcSio, 0x0000);
if (status < 0)
break;
}
} while (0);
}
return status;
}
static int ReadIFAgc(struct drxd_state *state, u32 * pValue)
{
int status = 0;
*pValue = 0;
if (state->if_agc_cfg.ctrlMode != AGC_CTRL_OFF) {
u16 Value;
status = Read16(state, FE_AG_REG_GC1_AGC_DAT__A, &Value, 0);
Value &= FE_AG_REG_GC1_AGC_DAT__M;
if (status >= 0) {
/* 3.3V
|
R1
|
Vin - R3 - * -- Vout
|
R2
|
GND
*/
u32 R1 = state->if_agc_cfg.R1;
u32 R2 = state->if_agc_cfg.R2;
u32 R3 = state->if_agc_cfg.R3;
u32 Vmax, Rpar, Vmin, Vout;
if (R2 == 0 && (R1 == 0 || R3 == 0))
return 0;
Vmax = (3300 * R2) / (R1 + R2);
Rpar = (R2 * R3) / (R3 + R2);
Vmin = (3300 * Rpar) / (R1 + Rpar);
Vout = Vmin + ((Vmax - Vmin) * Value) / 1024;
*pValue = Vout;
}
}
return status;
}
static int load_firmware(struct drxd_state *state, const char *fw_name)
{
const struct firmware *fw;
if (request_firmware(&fw, fw_name, state->dev) < 0) {
printk(KERN_ERR "drxd: firmware load failure [%s]\n", fw_name);
return -EIO;
}
state->microcode = kmemdup(fw->data, fw->size, GFP_KERNEL);
if (!state->microcode) {
release_firmware(fw);
return -ENOMEM;
}
state->microcode_length = fw->size;
release_firmware(fw);
return 0;
}
static int DownloadMicrocode(struct drxd_state *state,
const u8 *pMCImage, u32 Length)
{
u8 *pSrc;
u32 Address;
u16 nBlocks;
u16 BlockSize;
u32 offset = 0;
int i, status = 0;
pSrc = (u8 *) pMCImage;
/* We're not using Flags */
/* Flags = (pSrc[0] << 8) | pSrc[1]; */
pSrc += sizeof(u16);
offset += sizeof(u16);
nBlocks = (pSrc[0] << 8) | pSrc[1];
pSrc += sizeof(u16);
offset += sizeof(u16);
for (i = 0; i < nBlocks; i++) {
Address = (pSrc[0] << 24) | (pSrc[1] << 16) |
(pSrc[2] << 8) | pSrc[3];
pSrc += sizeof(u32);
offset += sizeof(u32);
BlockSize = ((pSrc[0] << 8) | pSrc[1]) * sizeof(u16);
pSrc += sizeof(u16);
offset += sizeof(u16);
/* We're not using Flags */
/* u16 Flags = (pSrc[0] << 8) | pSrc[1]; */
pSrc += sizeof(u16);
offset += sizeof(u16);
/* We're not using BlockCRC */
/* u16 BlockCRC = (pSrc[0] << 8) | pSrc[1]; */
pSrc += sizeof(u16);
offset += sizeof(u16);
status = WriteBlock(state, Address, BlockSize,
pSrc, DRX_I2C_CLEARCRC);
if (status < 0)
break;
pSrc += BlockSize;
offset += BlockSize;
}
return status;
}
static int HI_Command(struct drxd_state *state, u16 cmd, u16 * pResult)
{
u32 nrRetries = 0;
int status;
status = Write16(state, HI_RA_RAM_SRV_CMD__A, cmd, 0);
if (status < 0)
return status;
do {
nrRetries += 1;
if (nrRetries > DRXD_MAX_RETRIES) {
status = -1;
break;
}
status = Read16(state, HI_RA_RAM_SRV_CMD__A, NULL, 0);
} while (status != 0);
if (status >= 0)
status = Read16(state, HI_RA_RAM_SRV_RES__A, pResult, 0);
return status;
}
static int HI_CfgCommand(struct drxd_state *state)
{
int status = 0;
mutex_lock(&state->mutex);
Write16(state, HI_RA_RAM_SRV_CFG_KEY__A, HI_RA_RAM_SRV_RST_KEY_ACT, 0);
Write16(state, HI_RA_RAM_SRV_CFG_DIV__A, state->hi_cfg_timing_div, 0);
Write16(state, HI_RA_RAM_SRV_CFG_BDL__A, state->hi_cfg_bridge_delay, 0);
Write16(state, HI_RA_RAM_SRV_CFG_WUP__A, state->hi_cfg_wakeup_key, 0);
Write16(state, HI_RA_RAM_SRV_CFG_ACT__A, state->hi_cfg_ctrl, 0);
Write16(state, HI_RA_RAM_SRV_CFG_KEY__A, HI_RA_RAM_SRV_RST_KEY_ACT, 0);
if ((state->hi_cfg_ctrl & HI_RA_RAM_SRV_CFG_ACT_PWD_EXE) ==
HI_RA_RAM_SRV_CFG_ACT_PWD_EXE)
status = Write16(state, HI_RA_RAM_SRV_CMD__A,
HI_RA_RAM_SRV_CMD_CONFIG, 0);
else
status = HI_Command(state, HI_RA_RAM_SRV_CMD_CONFIG, NULL);
mutex_unlock(&state->mutex);
return status;
}
static int InitHI(struct drxd_state *state)
{
state->hi_cfg_wakeup_key = (state->chip_adr);
/* port/bridge/power down ctrl */
state->hi_cfg_ctrl = HI_RA_RAM_SRV_CFG_ACT_SLV0_ON;
return HI_CfgCommand(state);
}
static int HI_ResetCommand(struct drxd_state *state)
{
int status;
mutex_lock(&state->mutex);
status = Write16(state, HI_RA_RAM_SRV_RST_KEY__A,
HI_RA_RAM_SRV_RST_KEY_ACT, 0);
if (status == 0)
status = HI_Command(state, HI_RA_RAM_SRV_CMD_RESET, NULL);
mutex_unlock(&state->mutex);
msleep(1);
return status;
}
static int DRX_ConfigureI2CBridge(struct drxd_state *state, int bEnableBridge)
{
state->hi_cfg_ctrl &= (~HI_RA_RAM_SRV_CFG_ACT_BRD__M);
if (bEnableBridge)
state->hi_cfg_ctrl |= HI_RA_RAM_SRV_CFG_ACT_BRD_ON;
else
state->hi_cfg_ctrl |= HI_RA_RAM_SRV_CFG_ACT_BRD_OFF;
return HI_CfgCommand(state);
}
#define HI_TR_WRITE 0x9
#define HI_TR_READ 0xA
#define HI_TR_READ_WRITE 0xB
#define HI_TR_BROADCAST 0x4
#if 0
static int AtomicReadBlock(struct drxd_state *state,
u32 Addr, u16 DataSize, u8 *pData, u8 Flags)
{
int status;
int i = 0;
/* Parameter check */
if ((!pData) || ((DataSize & 1) != 0))
return -1;
mutex_lock(&state->mutex);
do {
/* Instruct HI to read n bytes */
/* TODO use proper names forthese egisters */
status = Write16(state, HI_RA_RAM_SRV_CFG_KEY__A, (HI_TR_FUNC_ADDR & 0xFFFF), 0);
if (status < 0)
break;
status = Write16(state, HI_RA_RAM_SRV_CFG_DIV__A, (u16) (Addr >> 16), 0);
if (status < 0)
break;
status = Write16(state, HI_RA_RAM_SRV_CFG_BDL__A, (u16) (Addr & 0xFFFF), 0);
if (status < 0)
break;
status = Write16(state, HI_RA_RAM_SRV_CFG_WUP__A, (u16) ((DataSize / 2) - 1), 0);
if (status < 0)
break;
status = Write16(state, HI_RA_RAM_SRV_CFG_ACT__A, HI_TR_READ, 0);
if (status < 0)
break;
status = HI_Command(state, HI_RA_RAM_SRV_CMD_EXECUTE, 0);
if (status < 0)
break;
} while (0);
if (status >= 0) {
for (i = 0; i < (DataSize / 2); i += 1) {
u16 word;
status = Read16(state, (HI_RA_RAM_USR_BEGIN__A + i),
&word, 0);
if (status < 0)
break;
pData[2 * i] = (u8) (word & 0xFF);
pData[(2 * i) + 1] = (u8) (word >> 8);
}
}
mutex_unlock(&state->mutex);
return status;
}
static int AtomicReadReg32(struct drxd_state *state,
u32 Addr, u32 *pData, u8 Flags)
{
u8 buf[sizeof(u32)];
int status;
if (!pData)
return -1;
status = AtomicReadBlock(state, Addr, sizeof(u32), buf, Flags);
*pData = (((u32) buf[0]) << 0) +
(((u32) buf[1]) << 8) +
(((u32) buf[2]) << 16) + (((u32) buf[3]) << 24);
return status;
}
#endif
static int StopAllProcessors(struct drxd_state *state)
{
return Write16(state, HI_COMM_EXEC__A,
SC_COMM_EXEC_CTL_STOP, DRX_I2C_BROADCAST);
}
static int EnableAndResetMB(struct drxd_state *state)
{
if (state->type_A) {
/* disable? monitor bus observe @ EC_OC */
Write16(state, EC_OC_REG_OC_MON_SIO__A, 0x0000, 0x0000);
}
/* do inverse broadcast, followed by explicit write to HI */
Write16(state, HI_COMM_MB__A, 0x0000, DRX_I2C_BROADCAST);
Write16(state, HI_COMM_MB__A, 0x0000, 0x0000);
return 0;
}
static int InitCC(struct drxd_state *state)
{
int status = 0;
if (state->osc_clock_freq == 0 ||
state->osc_clock_freq > 20000 ||
(state->osc_clock_freq % 4000) != 0) {
printk(KERN_ERR "invalid osc frequency %d\n", state->osc_clock_freq);
return -1;
}
status |= Write16(state, CC_REG_OSC_MODE__A, CC_REG_OSC_MODE_M20, 0);
status |= Write16(state, CC_REG_PLL_MODE__A,
CC_REG_PLL_MODE_BYPASS_PLL |
CC_REG_PLL_MODE_PUMP_CUR_12, 0);
status |= Write16(state, CC_REG_REF_DIVIDE__A,
state->osc_clock_freq / 4000, 0);
status |= Write16(state, CC_REG_PWD_MODE__A, CC_REG_PWD_MODE_DOWN_PLL,
0);
status |= Write16(state, CC_REG_UPDATE__A, CC_REG_UPDATE_KEY, 0);
return status;
}
static int ResetECOD(struct drxd_state *state)
{
int status = 0;
if (state->type_A)
status = Write16(state, EC_OD_REG_SYNC__A, 0x0664, 0);
else
status = Write16(state, B_EC_OD_REG_SYNC__A, 0x0664, 0);
if (!(status < 0))
status = WriteTable(state, state->m_ResetECRAM);
if (!(status < 0))
status = Write16(state, EC_OD_REG_COMM_EXEC__A, 0x0001, 0);
return status;
}
/* Configure PGA switch */
static int SetCfgPga(struct drxd_state *state, int pgaSwitch)
{
int status;
u16 AgModeLop = 0;
u16 AgModeHip = 0;
do {
if (pgaSwitch) {
/* PGA on */
/* fine gain */
status = Read16(state, B_FE_AG_REG_AG_MODE_LOP__A, &AgModeLop, 0x0000);
if (status < 0)
break;
AgModeLop &= (~(B_FE_AG_REG_AG_MODE_LOP_MODE_C__M));
AgModeLop |= B_FE_AG_REG_AG_MODE_LOP_MODE_C_DYNAMIC;
status = Write16(state, B_FE_AG_REG_AG_MODE_LOP__A, AgModeLop, 0x0000);
if (status < 0)
break;
/* coarse gain */
status = Read16(state, B_FE_AG_REG_AG_MODE_HIP__A, &AgModeHip, 0x0000);
if (status < 0)
break;
AgModeHip &= (~(B_FE_AG_REG_AG_MODE_HIP_MODE_J__M));
AgModeHip |= B_FE_AG_REG_AG_MODE_HIP_MODE_J_DYNAMIC;
status = Write16(state, B_FE_AG_REG_AG_MODE_HIP__A, AgModeHip, 0x0000);
if (status < 0)
break;
/* enable fine and coarse gain, enable AAF,
no ext resistor */
status = Write16(state, B_FE_AG_REG_AG_PGA_MODE__A, B_FE_AG_REG_AG_PGA_MODE_PFY_PCY_AFY_REN, 0x0000);
if (status < 0)
break;
} else {
/* PGA off, bypass */
/* fine gain */
status = Read16(state, B_FE_AG_REG_AG_MODE_LOP__A, &AgModeLop, 0x0000);
if (status < 0)
break;
AgModeLop &= (~(B_FE_AG_REG_AG_MODE_LOP_MODE_C__M));
AgModeLop |= B_FE_AG_REG_AG_MODE_LOP_MODE_C_STATIC;
status = Write16(state, B_FE_AG_REG_AG_MODE_LOP__A, AgModeLop, 0x0000);
if (status < 0)
break;
/* coarse gain */
status = Read16(state, B_FE_AG_REG_AG_MODE_HIP__A, &AgModeHip, 0x0000);
if (status < 0)
break;
AgModeHip &= (~(B_FE_AG_REG_AG_MODE_HIP_MODE_J__M));
AgModeHip |= B_FE_AG_REG_AG_MODE_HIP_MODE_J_STATIC;
status = Write16(state, B_FE_AG_REG_AG_MODE_HIP__A, AgModeHip, 0x0000);
if (status < 0)
break;
/* disable fine and coarse gain, enable AAF,
no ext resistor */
status = Write16(state, B_FE_AG_REG_AG_PGA_MODE__A, B_FE_AG_REG_AG_PGA_MODE_PFN_PCN_AFY_REN, 0x0000);
if (status < 0)
break;
}
} while (0);
return status;
}
static int InitFE(struct drxd_state *state)
{
int status;
do {
status = WriteTable(state, state->m_InitFE_1);
if (status < 0)
break;
if (state->type_A) {
status = Write16(state, FE_AG_REG_AG_PGA_MODE__A,
FE_AG_REG_AG_PGA_MODE_PFN_PCN_AFY_REN,
0);
} else {
if (state->PGA)
status = SetCfgPga(state, 0);
else
status =
Write16(state, B_FE_AG_REG_AG_PGA_MODE__A,
B_FE_AG_REG_AG_PGA_MODE_PFN_PCN_AFY_REN,
0);
}
if (status < 0)
break;
status = Write16(state, FE_AG_REG_AG_AGC_SIO__A, state->m_FeAgRegAgAgcSio, 0x0000);
if (status < 0)
break;
status = Write16(state, FE_AG_REG_AG_PWD__A, state->m_FeAgRegAgPwd, 0x0000);
if (status < 0)
break;
status = WriteTable(state, state->m_InitFE_2);
if (status < 0)
break;
} while (0);
return status;
}
static int InitFT(struct drxd_state *state)
{
/*
norm OFFSET, MB says =2 voor 8K en =3 voor 2K waarschijnlijk
SC stuff
*/
return Write16(state, FT_REG_COMM_EXEC__A, 0x0001, 0x0000);
}
static int SC_WaitForReady(struct drxd_state *state)
{
int i;
for (i = 0; i < DRXD_MAX_RETRIES; i += 1) {
int status = Read16(state, SC_RA_RAM_CMD__A, NULL, 0);
if (status == 0)
return status;
}
return -1;
}
static int SC_SendCommand(struct drxd_state *state, u16 cmd)
{
int status = 0, ret;
u16 errCode;
status = Write16(state, SC_RA_RAM_CMD__A, cmd, 0);
if (status < 0)
return status;
SC_WaitForReady(state);
ret = Read16(state, SC_RA_RAM_CMD_ADDR__A, &errCode, 0);
if (ret < 0 || errCode == 0xFFFF) {
printk(KERN_ERR "Command Error\n");
status = -1;
}
return status;
}
static int SC_ProcStartCommand(struct drxd_state *state,
u16 subCmd, u16 param0, u16 param1)
{
int ret, status = 0;
u16 scExec;
mutex_lock(&state->mutex);
do {
ret = Read16(state, SC_COMM_EXEC__A, &scExec, 0);
if (ret < 0 || scExec != 1) {
status = -1;
break;
}
SC_WaitForReady(state);
status |= Write16(state, SC_RA_RAM_CMD_ADDR__A, subCmd, 0);
status |= Write16(state, SC_RA_RAM_PARAM1__A, param1, 0);
status |= Write16(state, SC_RA_RAM_PARAM0__A, param0, 0);
SC_SendCommand(state, SC_RA_RAM_CMD_PROC_START);
} while (0);
mutex_unlock(&state->mutex);
return status;
}
static int SC_SetPrefParamCommand(struct drxd_state *state,
u16 subCmd, u16 param0, u16 param1)
{
int status;
mutex_lock(&state->mutex);
do {
status = SC_WaitForReady(state);
if (status < 0)
break;
status = Write16(state, SC_RA_RAM_CMD_ADDR__A, subCmd, 0);
if (status < 0)
break;
status = Write16(state, SC_RA_RAM_PARAM1__A, param1, 0);
if (status < 0)
break;
status = Write16(state, SC_RA_RAM_PARAM0__A, param0, 0);
if (status < 0)
break;
status = SC_SendCommand(state, SC_RA_RAM_CMD_SET_PREF_PARAM);
if (status < 0)
break;
} while (0);
mutex_unlock(&state->mutex);
return status;
}
#if 0
static int SC_GetOpParamCommand(struct drxd_state *state, u16 * result)
{
int status = 0;
mutex_lock(&state->mutex);
do {
status = SC_WaitForReady(state);
if (status < 0)
break;
status = SC_SendCommand(state, SC_RA_RAM_CMD_GET_OP_PARAM);
if (status < 0)
break;
status = Read16(state, SC_RA_RAM_PARAM0__A, result, 0);
if (status < 0)
break;
} while (0);
mutex_unlock(&state->mutex);
return status;
}
#endif
static int ConfigureMPEGOutput(struct drxd_state *state, int bEnableOutput)
{
int status;
do {
u16 EcOcRegIprInvMpg = 0;
u16 EcOcRegOcModeLop = 0;
u16 EcOcRegOcModeHip = 0;
u16 EcOcRegOcMpgSio = 0;
/*CHK_ERROR(Read16(state, EC_OC_REG_OC_MODE_LOP__A, &EcOcRegOcModeLop, 0)); */
if (state->operation_mode == OM_DVBT_Diversity_Front) {
if (bEnableOutput) {
EcOcRegOcModeHip |=
B_EC_OC_REG_OC_MODE_HIP_MPG_BUS_SRC_MONITOR;
} else
EcOcRegOcMpgSio |= EC_OC_REG_OC_MPG_SIO__M;
EcOcRegOcModeLop |=
EC_OC_REG_OC_MODE_LOP_PAR_ENA_DISABLE;
} else {
EcOcRegOcModeLop = state->m_EcOcRegOcModeLop;
if (bEnableOutput)
EcOcRegOcMpgSio &= (~(EC_OC_REG_OC_MPG_SIO__M));
else
EcOcRegOcMpgSio |= EC_OC_REG_OC_MPG_SIO__M;
/* Don't Insert RS Byte */
if (state->insert_rs_byte) {
EcOcRegOcModeLop &=
(~(EC_OC_REG_OC_MODE_LOP_PAR_ENA__M));
EcOcRegOcModeHip &=
(~EC_OC_REG_OC_MODE_HIP_MPG_PAR_VAL__M);
EcOcRegOcModeHip |=
EC_OC_REG_OC_MODE_HIP_MPG_PAR_VAL_ENABLE;
} else {
EcOcRegOcModeLop |=
EC_OC_REG_OC_MODE_LOP_PAR_ENA_DISABLE;
EcOcRegOcModeHip &=
(~EC_OC_REG_OC_MODE_HIP_MPG_PAR_VAL__M);
EcOcRegOcModeHip |=
EC_OC_REG_OC_MODE_HIP_MPG_PAR_VAL_DISABLE;
}
/* Mode = Parallel */
if (state->enable_parallel)
EcOcRegOcModeLop &=
(~(EC_OC_REG_OC_MODE_LOP_MPG_TRM_MDE__M));
else
EcOcRegOcModeLop |=
EC_OC_REG_OC_MODE_LOP_MPG_TRM_MDE_SERIAL;
}
/* Invert Data */
/* EcOcRegIprInvMpg |= 0x00FF; */
EcOcRegIprInvMpg &= (~(0x00FF));
/* Invert Error ( we don't use the pin ) */
/* EcOcRegIprInvMpg |= 0x0100; */
EcOcRegIprInvMpg &= (~(0x0100));
/* Invert Start ( we don't use the pin ) */
/* EcOcRegIprInvMpg |= 0x0200; */
EcOcRegIprInvMpg &= (~(0x0200));
/* Invert Valid ( we don't use the pin ) */
/* EcOcRegIprInvMpg |= 0x0400; */
EcOcRegIprInvMpg &= (~(0x0400));
/* Invert Clock */
/* EcOcRegIprInvMpg |= 0x0800; */
EcOcRegIprInvMpg &= (~(0x0800));
/* EcOcRegOcModeLop =0x05; */
status = Write16(state, EC_OC_REG_IPR_INV_MPG__A, EcOcRegIprInvMpg, 0);
if (status < 0)
break;
status = Write16(state, EC_OC_REG_OC_MODE_LOP__A, EcOcRegOcModeLop, 0);
if (status < 0)
break;
status = Write16(state, EC_OC_REG_OC_MODE_HIP__A, EcOcRegOcModeHip, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_OC_REG_OC_MPG_SIO__A, EcOcRegOcMpgSio, 0);
if (status < 0)
break;
} while (0);
return status;
}
static int SetDeviceTypeId(struct drxd_state *state)
{
int status = 0;
u16 deviceId = 0;
do {
status = Read16(state, CC_REG_JTAGID_L__A, &deviceId, 0);
if (status < 0)
break;
/* TODO: why twice? */
status = Read16(state, CC_REG_JTAGID_L__A, &deviceId, 0);
if (status < 0)
break;
printk(KERN_INFO "drxd: deviceId = %04x\n", deviceId);
state->type_A = 0;
state->PGA = 0;
state->diversity = 0;
if (deviceId == 0) { /* on A2 only 3975 available */
state->type_A = 1;
printk(KERN_INFO "DRX3975D-A2\n");
} else {
deviceId >>= 12;
printk(KERN_INFO "DRX397%dD-B1\n", deviceId);
switch (deviceId) {
case 4:
state->diversity = 1;
/* fall through */
case 3:
case 7:
state->PGA = 1;
break;
case 6:
state->diversity = 1;
/* fall through */
case 5:
case 8:
break;
default:
status = -1;
break;
}
}
} while (0);
if (status < 0)
return status;
/* Init Table selection */
state->m_InitAtomicRead = DRXD_InitAtomicRead;
state->m_InitSC = DRXD_InitSC;
state->m_ResetECRAM = DRXD_ResetECRAM;
if (state->type_A) {
state->m_ResetCEFR = DRXD_ResetCEFR;
state->m_InitFE_1 = DRXD_InitFEA2_1;
state->m_InitFE_2 = DRXD_InitFEA2_2;
state->m_InitCP = DRXD_InitCPA2;
state->m_InitCE = DRXD_InitCEA2;
state->m_InitEQ = DRXD_InitEQA2;
state->m_InitEC = DRXD_InitECA2;
if (load_firmware(state, DRX_FW_FILENAME_A2))
return -EIO;
} else {
state->m_ResetCEFR = NULL;
state->m_InitFE_1 = DRXD_InitFEB1_1;
state->m_InitFE_2 = DRXD_InitFEB1_2;
state->m_InitCP = DRXD_InitCPB1;
state->m_InitCE = DRXD_InitCEB1;
state->m_InitEQ = DRXD_InitEQB1;
state->m_InitEC = DRXD_InitECB1;
if (load_firmware(state, DRX_FW_FILENAME_B1))
return -EIO;
}
if (state->diversity) {
state->m_InitDiversityFront = DRXD_InitDiversityFront;
state->m_InitDiversityEnd = DRXD_InitDiversityEnd;
state->m_DisableDiversity = DRXD_DisableDiversity;
state->m_StartDiversityFront = DRXD_StartDiversityFront;
state->m_StartDiversityEnd = DRXD_StartDiversityEnd;
state->m_DiversityDelay8MHZ = DRXD_DiversityDelay8MHZ;
state->m_DiversityDelay6MHZ = DRXD_DiversityDelay6MHZ;
} else {
state->m_InitDiversityFront = NULL;
state->m_InitDiversityEnd = NULL;
state->m_DisableDiversity = NULL;
state->m_StartDiversityFront = NULL;
state->m_StartDiversityEnd = NULL;
state->m_DiversityDelay8MHZ = NULL;
state->m_DiversityDelay6MHZ = NULL;
}
return status;
}
static int CorrectSysClockDeviation(struct drxd_state *state)
{
int status;
s32 incr = 0;
s32 nomincr = 0;
u32 bandwidth = 0;
u32 sysClockInHz = 0;
u32 sysClockFreq = 0; /* in kHz */
s16 oscClockDeviation;
s16 Diff;
do {
/* Retrieve bandwidth and incr, sanity check */
/* These accesses should be AtomicReadReg32, but that
causes trouble (at least for diversity */
status = Read32(state, LC_RA_RAM_IFINCR_NOM_L__A, ((u32 *) &nomincr), 0);
if (status < 0)
break;
status = Read32(state, FE_IF_REG_INCR0__A, (u32 *) &incr, 0);
if (status < 0)
break;
if (state->type_A) {
if ((nomincr - incr < -500) || (nomincr - incr > 500))
break;
} else {
if ((nomincr - incr < -2000) || (nomincr - incr > 2000))
break;
}
switch (state->props.bandwidth_hz) {
case 8000000:
bandwidth = DRXD_BANDWIDTH_8MHZ_IN_HZ;
break;
case 7000000:
bandwidth = DRXD_BANDWIDTH_7MHZ_IN_HZ;
break;
case 6000000:
bandwidth = DRXD_BANDWIDTH_6MHZ_IN_HZ;
break;
default:
return -1;
break;
}
/* Compute new sysclock value
sysClockFreq = (((incr + 2^23)*bandwidth)/2^21)/1000 */
incr += (1 << 23);
sysClockInHz = MulDiv32(incr, bandwidth, 1 << 21);
sysClockFreq = (u32) (sysClockInHz / 1000);
/* rounding */
if ((sysClockInHz % 1000) > 500)
sysClockFreq++;
/* Compute clock deviation in ppm */
oscClockDeviation = (u16) ((((s32) (sysClockFreq) -
(s32)
(state->expected_sys_clock_freq)) *
1000000L) /
(s32)
(state->expected_sys_clock_freq));
Diff = oscClockDeviation - state->osc_clock_deviation;
/*printk(KERN_INFO "sysclockdiff=%d\n", Diff); */
if (Diff >= -200 && Diff <= 200) {
state->sys_clock_freq = (u16) sysClockFreq;
if (oscClockDeviation != state->osc_clock_deviation) {
if (state->config.osc_deviation) {
state->config.osc_deviation(state->priv,
oscClockDeviation,
1);
state->osc_clock_deviation =
oscClockDeviation;
}
}
/* switch OFF SRMM scan in SC */
status = Write16(state, SC_RA_RAM_SAMPLE_RATE_COUNT__A, DRXD_OSCDEV_DONT_SCAN, 0);
if (status < 0)
break;
/* overrule FE_IF internal value for
proper re-locking */
status = Write16(state, SC_RA_RAM_IF_SAVE__AX, state->current_fe_if_incr, 0);
if (status < 0)
break;
state->cscd_state = CSCD_SAVED;
}
} while (0);
return status;
}
static int DRX_Stop(struct drxd_state *state)
{
int status;
if (state->drxd_state != DRXD_STARTED)
return 0;
do {
if (state->cscd_state != CSCD_SAVED) {
u32 lock;
status = DRX_GetLockStatus(state, &lock);
if (status < 0)
break;
}
status = StopOC(state);
if (status < 0)
break;
state->drxd_state = DRXD_STOPPED;
status = ConfigureMPEGOutput(state, 0);
if (status < 0)
break;
if (state->type_A) {
/* Stop relevant processors off the device */
status = Write16(state, EC_OD_REG_COMM_EXEC__A, 0x0000, 0x0000);
if (status < 0)
break;
status = Write16(state, SC_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
status = Write16(state, LC_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
} else {
/* Stop all processors except HI & CC & FE */
status = Write16(state, B_SC_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
status = Write16(state, B_LC_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
status = Write16(state, B_FT_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
status = Write16(state, B_CP_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
status = Write16(state, B_CE_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
status = Write16(state, B_EQ_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
status = Write16(state, EC_OD_REG_COMM_EXEC__A, 0x0000, 0);
if (status < 0)
break;
}
} while (0);
return status;
}
#if 0 /* Currently unused */
static int SetOperationMode(struct drxd_state *state, int oMode)
{
int status;
do {
if (state->drxd_state != DRXD_STOPPED) {
status = -1;
break;
}
if (oMode == state->operation_mode) {
status = 0;
break;
}
if (oMode != OM_Default && !state->diversity) {
status = -1;
break;
}
switch (oMode) {
case OM_DVBT_Diversity_Front:
status = WriteTable(state, state->m_InitDiversityFront);
break;
case OM_DVBT_Diversity_End:
status = WriteTable(state, state->m_InitDiversityEnd);
break;
case OM_Default:
/* We need to check how to
get DRXD out of diversity */
default:
status = WriteTable(state, state->m_DisableDiversity);
break;
}
} while (0);
if (!status)
state->operation_mode = oMode;
return status;
}
#endif
static int StartDiversity(struct drxd_state *state)
{
int status = 0;
u16 rcControl;
do {
if (state->operation_mode == OM_DVBT_Diversity_Front) {
status = WriteTable(state, state->m_StartDiversityFront);
if (status < 0)
break;
} else if (state->operation_mode == OM_DVBT_Diversity_End) {
status = WriteTable(state, state->m_StartDiversityEnd);
if (status < 0)
break;
if (state->props.bandwidth_hz == 8000000) {
status = WriteTable(state, state->m_DiversityDelay8MHZ);
if (status < 0)
break;
} else {
status = WriteTable(state, state->m_DiversityDelay6MHZ);
if (status < 0)
break;
}
status = Read16(state, B_EQ_REG_RC_SEL_CAR__A, &rcControl, 0);
if (status < 0)
break;
rcControl &= ~(B_EQ_REG_RC_SEL_CAR_FFTMODE__M);
rcControl |= B_EQ_REG_RC_SEL_CAR_DIV_ON |
/* combining enabled */
B_EQ_REG_RC_SEL_CAR_MEAS_A_CC |
B_EQ_REG_RC_SEL_CAR_PASS_A_CC |
B_EQ_REG_RC_SEL_CAR_LOCAL_A_CC;
status = Write16(state, B_EQ_REG_RC_SEL_CAR__A, rcControl, 0);
if (status < 0)
break;
}
} while (0);
return status;
}
static int SetFrequencyShift(struct drxd_state *state,
u32 offsetFreq, int channelMirrored)
{
int negativeShift = (state->tuner_mirrors == channelMirrored);
/* Handle all mirroring
*
* Note: ADC mirroring (aliasing) is implictly handled by limiting
* feFsRegAddInc to 28 bits below
* (if the result before masking is more than 28 bits, this means
* that the ADC is mirroring.
* The masking is in fact the aliasing of the ADC)
*
*/
/* Compute register value, unsigned computation */
state->fe_fs_add_incr = MulDiv32(state->intermediate_freq +
offsetFreq,
1 << 28, state->sys_clock_freq);
/* Remove integer part */
state->fe_fs_add_incr &= 0x0FFFFFFFL;
if (negativeShift)
state->fe_fs_add_incr = ((1 << 28) - state->fe_fs_add_incr);
/* Save the frequency shift without tunerOffset compensation
for CtrlGetChannel. */
state->org_fe_fs_add_incr = MulDiv32(state->intermediate_freq,
1 << 28, state->sys_clock_freq);
/* Remove integer part */
state->org_fe_fs_add_incr &= 0x0FFFFFFFL;
if (negativeShift)
state->org_fe_fs_add_incr = ((1L << 28) -
state->org_fe_fs_add_incr);
return Write32(state, FE_FS_REG_ADD_INC_LOP__A,
state->fe_fs_add_incr, 0);
}
static int SetCfgNoiseCalibration(struct drxd_state *state,
struct SNoiseCal *noiseCal)
{
u16 beOptEna;
int status = 0;
do {
status = Read16(state, SC_RA_RAM_BE_OPT_ENA__A, &beOptEna, 0);
if (status < 0)
break;
if (noiseCal->cpOpt) {
beOptEna |= (1 << SC_RA_RAM_BE_OPT_ENA_CP_OPT);
} else {
beOptEna &= ~(1 << SC_RA_RAM_BE_OPT_ENA_CP_OPT);
status = Write16(state, CP_REG_AC_NEXP_OFFS__A, noiseCal->cpNexpOfs, 0);
if (status < 0)
break;
}
status = Write16(state, SC_RA_RAM_BE_OPT_ENA__A, beOptEna, 0);
if (status < 0)
break;
if (!state->type_A) {
status = Write16(state, B_SC_RA_RAM_CO_TD_CAL_2K__A, noiseCal->tdCal2k, 0);
if (status < 0)
break;
status = Write16(state, B_SC_RA_RAM_CO_TD_CAL_8K__A, noiseCal->tdCal8k, 0);
if (status < 0)
break;
}
} while (0);
return status;
}
static int DRX_Start(struct drxd_state *state, s32 off)
{
struct dtv_frontend_properties *p = &state->props;
int status;
u16 transmissionParams = 0;
u16 operationMode = 0;
u16 qpskTdTpsPwr = 0;
u16 qam16TdTpsPwr = 0;
u16 qam64TdTpsPwr = 0;
u32 feIfIncr = 0;
u32 bandwidth = 0;
int mirrorFreqSpect;
u16 qpskSnCeGain = 0;
u16 qam16SnCeGain = 0;
u16 qam64SnCeGain = 0;
u16 qpskIsGainMan = 0;
u16 qam16IsGainMan = 0;
u16 qam64IsGainMan = 0;
u16 qpskIsGainExp = 0;
u16 qam16IsGainExp = 0;
u16 qam64IsGainExp = 0;
u16 bandwidthParam = 0;
if (off < 0)
off = (off - 500) / 1000;
else
off = (off + 500) / 1000;
do {
if (state->drxd_state != DRXD_STOPPED)
return -1;
status = ResetECOD(state);
if (status < 0)
break;
if (state->type_A) {
status = InitSC(state);
if (status < 0)
break;
} else {
status = InitFT(state);
if (status < 0)
break;
status = InitCP(state);
if (status < 0)
break;
status = InitCE(state);
if (status < 0)
break;
status = InitEQ(state);
if (status < 0)
break;
status = InitSC(state);
if (status < 0)
break;
}
/* Restore current IF & RF AGC settings */
status = SetCfgIfAgc(state, &state->if_agc_cfg);
if (status < 0)
break;
status = SetCfgRfAgc(state, &state->rf_agc_cfg);
if (status < 0)
break;
mirrorFreqSpect = (state->props.inversion == INVERSION_ON);
switch (p->transmission_mode) {
default: /* Not set, detect it automatically */
operationMode |= SC_RA_RAM_OP_AUTO_MODE__M;
/* fall through - try first guess DRX_FFTMODE_8K */
case TRANSMISSION_MODE_8K:
transmissionParams |= SC_RA_RAM_OP_PARAM_MODE_8K;
if (state->type_A) {
status = Write16(state, EC_SB_REG_TR_MODE__A, EC_SB_REG_TR_MODE_8K, 0x0000);
if (status < 0)
break;
qpskSnCeGain = 99;
qam16SnCeGain = 83;
qam64SnCeGain = 67;
}
break;
case TRANSMISSION_MODE_2K:
transmissionParams |= SC_RA_RAM_OP_PARAM_MODE_2K;
if (state->type_A) {
status = Write16(state, EC_SB_REG_TR_MODE__A, EC_SB_REG_TR_MODE_2K, 0x0000);
if (status < 0)
break;
qpskSnCeGain = 97;
qam16SnCeGain = 71;
qam64SnCeGain = 65;
}
break;
}
switch (p->guard_interval) {
case GUARD_INTERVAL_1_4:
transmissionParams |= SC_RA_RAM_OP_PARAM_GUARD_4;
break;
case GUARD_INTERVAL_1_8:
transmissionParams |= SC_RA_RAM_OP_PARAM_GUARD_8;
break;
case GUARD_INTERVAL_1_16:
transmissionParams |= SC_RA_RAM_OP_PARAM_GUARD_16;
break;
case GUARD_INTERVAL_1_32:
transmissionParams |= SC_RA_RAM_OP_PARAM_GUARD_32;
break;
default: /* Not set, detect it automatically */
operationMode |= SC_RA_RAM_OP_AUTO_GUARD__M;
/* try first guess 1/4 */
transmissionParams |= SC_RA_RAM_OP_PARAM_GUARD_4;
break;
}
switch (p->hierarchy) {
case HIERARCHY_1:
transmissionParams |= SC_RA_RAM_OP_PARAM_HIER_A1;
if (state->type_A) {
status = Write16(state, EQ_REG_OT_ALPHA__A, 0x0001, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_ALPHA__A, 0x0001, 0x0000);
if (status < 0)
break;
qpskTdTpsPwr = EQ_TD_TPS_PWR_UNKNOWN;
qam16TdTpsPwr = EQ_TD_TPS_PWR_QAM16_ALPHA1;
qam64TdTpsPwr = EQ_TD_TPS_PWR_QAM64_ALPHA1;
qpskIsGainMan =
SC_RA_RAM_EQ_IS_GAIN_UNKNOWN_MAN__PRE;
qam16IsGainMan =
SC_RA_RAM_EQ_IS_GAIN_16QAM_MAN__PRE;
qam64IsGainMan =
SC_RA_RAM_EQ_IS_GAIN_64QAM_MAN__PRE;
qpskIsGainExp =
SC_RA_RAM_EQ_IS_GAIN_UNKNOWN_EXP__PRE;
qam16IsGainExp =
SC_RA_RAM_EQ_IS_GAIN_16QAM_EXP__PRE;
qam64IsGainExp =
SC_RA_RAM_EQ_IS_GAIN_64QAM_EXP__PRE;
}
break;
case HIERARCHY_2:
transmissionParams |= SC_RA_RAM_OP_PARAM_HIER_A2;
if (state->type_A) {
status = Write16(state, EQ_REG_OT_ALPHA__A, 0x0002, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_ALPHA__A, 0x0002, 0x0000);
if (status < 0)
break;
qpskTdTpsPwr = EQ_TD_TPS_PWR_UNKNOWN;
qam16TdTpsPwr = EQ_TD_TPS_PWR_QAM16_ALPHA2;
qam64TdTpsPwr = EQ_TD_TPS_PWR_QAM64_ALPHA2;
qpskIsGainMan =
SC_RA_RAM_EQ_IS_GAIN_UNKNOWN_MAN__PRE;
qam16IsGainMan =
SC_RA_RAM_EQ_IS_GAIN_16QAM_A2_MAN__PRE;
qam64IsGainMan =
SC_RA_RAM_EQ_IS_GAIN_64QAM_A2_MAN__PRE;
qpskIsGainExp =
SC_RA_RAM_EQ_IS_GAIN_UNKNOWN_EXP__PRE;
qam16IsGainExp =
SC_RA_RAM_EQ_IS_GAIN_16QAM_A2_EXP__PRE;
qam64IsGainExp =
SC_RA_RAM_EQ_IS_GAIN_64QAM_A2_EXP__PRE;
}
break;
case HIERARCHY_4:
transmissionParams |= SC_RA_RAM_OP_PARAM_HIER_A4;
if (state->type_A) {
status = Write16(state, EQ_REG_OT_ALPHA__A, 0x0003, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_ALPHA__A, 0x0003, 0x0000);
if (status < 0)
break;
qpskTdTpsPwr = EQ_TD_TPS_PWR_UNKNOWN;
qam16TdTpsPwr = EQ_TD_TPS_PWR_QAM16_ALPHA4;
qam64TdTpsPwr = EQ_TD_TPS_PWR_QAM64_ALPHA4;
qpskIsGainMan =
SC_RA_RAM_EQ_IS_GAIN_UNKNOWN_MAN__PRE;
qam16IsGainMan =
SC_RA_RAM_EQ_IS_GAIN_16QAM_A4_MAN__PRE;
qam64IsGainMan =
SC_RA_RAM_EQ_IS_GAIN_64QAM_A4_MAN__PRE;
qpskIsGainExp =
SC_RA_RAM_EQ_IS_GAIN_UNKNOWN_EXP__PRE;
qam16IsGainExp =
SC_RA_RAM_EQ_IS_GAIN_16QAM_A4_EXP__PRE;
qam64IsGainExp =
SC_RA_RAM_EQ_IS_GAIN_64QAM_A4_EXP__PRE;
}
break;
case HIERARCHY_AUTO:
default:
/* Not set, detect it automatically, start with none */
operationMode |= SC_RA_RAM_OP_AUTO_HIER__M;
transmissionParams |= SC_RA_RAM_OP_PARAM_HIER_NO;
if (state->type_A) {
status = Write16(state, EQ_REG_OT_ALPHA__A, 0x0000, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_ALPHA__A, 0x0000, 0x0000);
if (status < 0)
break;
qpskTdTpsPwr = EQ_TD_TPS_PWR_QPSK;
qam16TdTpsPwr = EQ_TD_TPS_PWR_QAM16_ALPHAN;
qam64TdTpsPwr = EQ_TD_TPS_PWR_QAM64_ALPHAN;
qpskIsGainMan =
SC_RA_RAM_EQ_IS_GAIN_QPSK_MAN__PRE;
qam16IsGainMan =
SC_RA_RAM_EQ_IS_GAIN_16QAM_MAN__PRE;
qam64IsGainMan =
SC_RA_RAM_EQ_IS_GAIN_64QAM_MAN__PRE;
qpskIsGainExp =
SC_RA_RAM_EQ_IS_GAIN_QPSK_EXP__PRE;
qam16IsGainExp =
SC_RA_RAM_EQ_IS_GAIN_16QAM_EXP__PRE;
qam64IsGainExp =
SC_RA_RAM_EQ_IS_GAIN_64QAM_EXP__PRE;
}
break;
}
if (status < 0)
break;
switch (p->modulation) {
default:
operationMode |= SC_RA_RAM_OP_AUTO_CONST__M;
/* fall through - try first guess DRX_CONSTELLATION_QAM64 */
case QAM_64:
transmissionParams |= SC_RA_RAM_OP_PARAM_CONST_QAM64;
if (state->type_A) {
status = Write16(state, EQ_REG_OT_CONST__A, 0x0002, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_CONST__A, EC_SB_REG_CONST_64QAM, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_SCALE_MSB__A, 0x0020, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_SCALE_BIT2__A, 0x0008, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_SCALE_LSB__A, 0x0002, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_TD_TPS_PWR_OFS__A, qam64TdTpsPwr, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_SN_CEGAIN__A, qam64SnCeGain, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_IS_GAIN_MAN__A, qam64IsGainMan, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_IS_GAIN_EXP__A, qam64IsGainExp, 0x0000);
if (status < 0)
break;
}
break;
case QPSK:
transmissionParams |= SC_RA_RAM_OP_PARAM_CONST_QPSK;
if (state->type_A) {
status = Write16(state, EQ_REG_OT_CONST__A, 0x0000, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_CONST__A, EC_SB_REG_CONST_QPSK, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_SCALE_MSB__A, 0x0010, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_SCALE_BIT2__A, 0x0000, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_SCALE_LSB__A, 0x0000, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_TD_TPS_PWR_OFS__A, qpskTdTpsPwr, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_SN_CEGAIN__A, qpskSnCeGain, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_IS_GAIN_MAN__A, qpskIsGainMan, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_IS_GAIN_EXP__A, qpskIsGainExp, 0x0000);
if (status < 0)
break;
}
break;
case QAM_16:
transmissionParams |= SC_RA_RAM_OP_PARAM_CONST_QAM16;
if (state->type_A) {
status = Write16(state, EQ_REG_OT_CONST__A, 0x0001, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_CONST__A, EC_SB_REG_CONST_16QAM, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_SCALE_MSB__A, 0x0010, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_SCALE_BIT2__A, 0x0004, 0x0000);
if (status < 0)
break;
status = Write16(state, EC_SB_REG_SCALE_LSB__A, 0x0000, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_TD_TPS_PWR_OFS__A, qam16TdTpsPwr, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_SN_CEGAIN__A, qam16SnCeGain, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_IS_GAIN_MAN__A, qam16IsGainMan, 0x0000);
if (status < 0)
break;
status = Write16(state, EQ_REG_IS_GAIN_EXP__A, qam16IsGainExp, 0x0000);
if (status < 0)
break;
}
break;
}
if (status < 0)
break;
switch (DRX_CHANNEL_HIGH) {
default:
case DRX_CHANNEL_AUTO:
case DRX_CHANNEL_LOW:
transmissionParams |= SC_RA_RAM_OP_PARAM_PRIO_LO;
status = Write16(state, EC_SB_REG_PRIOR__A, EC_SB_REG_PRIOR_LO, 0x0000);
break;
case DRX_CHANNEL_HIGH:
transmissionParams |= SC_RA_RAM_OP_PARAM_PRIO_HI;
status = Write16(state, EC_SB_REG_PRIOR__A, EC_SB_REG_PRIOR_HI, 0x0000);
break;
}
switch (p->code_rate_HP) {
case FEC_1_2:
transmissionParams |= SC_RA_RAM_OP_PARAM_RATE_1_2;
if (state->type_A)
status = Write16(state, EC_VD_REG_SET_CODERATE__A, EC_VD_REG_SET_CODERATE_C1_2, 0x0000);
break;
default:
operationMode |= SC_RA_RAM_OP_AUTO_RATE__M;
/* fall through */
case FEC_2_3:
transmissionParams |= SC_RA_RAM_OP_PARAM_RATE_2_3;
if (state->type_A)
status = Write16(state, EC_VD_REG_SET_CODERATE__A, EC_VD_REG_SET_CODERATE_C2_3, 0x0000);
break;
case FEC_3_4:
transmissionParams |= SC_RA_RAM_OP_PARAM_RATE_3_4;
if (state->type_A)
status = Write16(state, EC_VD_REG_SET_CODERATE__A, EC_VD_REG_SET_CODERATE_C3_4, 0x0000);
break;
case FEC_5_6:
transmissionParams |= SC_RA_RAM_OP_PARAM_RATE_5_6;
if (state->type_A)
status = Write16(state, EC_VD_REG_SET_CODERATE__A, EC_VD_REG_SET_CODERATE_C5_6, 0x0000);
break;
case FEC_7_8:
transmissionParams |= SC_RA_RAM_OP_PARAM_RATE_7_8;
if (state->type_A)
status = Write16(state, EC_VD_REG_SET_CODERATE__A, EC_VD_REG_SET_CODERATE_C7_8, 0x0000);
break;
}
if (status < 0)
break;
/* First determine real bandwidth (Hz) */
/* Also set delay for impulse noise cruncher (only A2) */
/* Also set parameters for EC_OC fix, note
EC_OC_REG_TMD_HIL_MAR is changed
by SC for fix for some 8K,1/8 guard but is restored by
InitEC and ResetEC
functions */
switch (p->bandwidth_hz) {
case 0:
p->bandwidth_hz = 8000000;
/* fall through */
case 8000000:
/* (64/7)*(8/8)*1000000 */
bandwidth = DRXD_BANDWIDTH_8MHZ_IN_HZ;
bandwidthParam = 0;
status = Write16(state,
FE_AG_REG_IND_DEL__A, 50, 0x0000);
break;
case 7000000:
/* (64/7)*(7/8)*1000000 */
bandwidth = DRXD_BANDWIDTH_7MHZ_IN_HZ;
bandwidthParam = 0x4807; /*binary:0100 1000 0000 0111 */
status = Write16(state,
FE_AG_REG_IND_DEL__A, 59, 0x0000);
break;
case 6000000:
/* (64/7)*(6/8)*1000000 */
bandwidth = DRXD_BANDWIDTH_6MHZ_IN_HZ;
bandwidthParam = 0x0F07; /*binary: 0000 1111 0000 0111 */
status = Write16(state,
FE_AG_REG_IND_DEL__A, 71, 0x0000);
break;
default:
status = -EINVAL;
}
if (status < 0)
break;
status = Write16(state, SC_RA_RAM_BAND__A, bandwidthParam, 0x0000);
if (status < 0)
break;
{
u16 sc_config;
status = Read16(state, SC_RA_RAM_CONFIG__A, &sc_config, 0);
if (status < 0)
break;
/* enable SLAVE mode in 2k 1/32 to
prevent timing change glitches */
if ((p->transmission_mode == TRANSMISSION_MODE_2K) &&
(p->guard_interval == GUARD_INTERVAL_1_32)) {
/* enable slave */
sc_config |= SC_RA_RAM_CONFIG_SLAVE__M;
} else {
/* disable slave */
sc_config &= ~SC_RA_RAM_CONFIG_SLAVE__M;
}
status = Write16(state, SC_RA_RAM_CONFIG__A, sc_config, 0);
if (status < 0)
break;
}
status = SetCfgNoiseCalibration(state, &state->noise_cal);
if (status < 0)
break;
if (state->cscd_state == CSCD_INIT) {
/* switch on SRMM scan in SC */
status = Write16(state, SC_RA_RAM_SAMPLE_RATE_COUNT__A, DRXD_OSCDEV_DO_SCAN, 0x0000);
if (status < 0)
break;
/* CHK_ERROR(Write16(SC_RA_RAM_SAMPLE_RATE_STEP__A, DRXD_OSCDEV_STEP, 0x0000));*/
state->cscd_state = CSCD_SET;
}
/* Now compute FE_IF_REG_INCR */
/*((( SysFreq/BandWidth)/2)/2) -1) * 2^23) =>
((SysFreq / BandWidth) * (2^21) ) - (2^23) */
feIfIncr = MulDiv32(state->sys_clock_freq * 1000,
(1ULL << 21), bandwidth) - (1 << 23);
status = Write16(state, FE_IF_REG_INCR0__A, (u16) (feIfIncr & FE_IF_REG_INCR0__M), 0x0000);
if (status < 0)
break;
status = Write16(state, FE_IF_REG_INCR1__A, (u16) ((feIfIncr >> FE_IF_REG_INCR0__W) & FE_IF_REG_INCR1__M), 0x0000);
if (status < 0)
break;
/* Bandwidth setting done */
/* Mirror & frequency offset */
SetFrequencyShift(state, off, mirrorFreqSpect);
/* Start SC, write channel settings to SC */
/* Enable SC after setting all other parameters */
status = Write16(state, SC_COMM_STATE__A, 0, 0x0000);
if (status < 0)
break;
status = Write16(state, SC_COMM_EXEC__A, 1, 0x0000);
if (status < 0)
break;
/* Write SC parameter registers, operation mode */
#if 1
operationMode = (SC_RA_RAM_OP_AUTO_MODE__M |
SC_RA_RAM_OP_AUTO_GUARD__M |
SC_RA_RAM_OP_AUTO_CONST__M |
SC_RA_RAM_OP_AUTO_HIER__M |
SC_RA_RAM_OP_AUTO_RATE__M);
#endif
status = SC_SetPrefParamCommand(state, 0x0000, transmissionParams, operationMode);
if (status < 0)
break;
/* Start correct processes to get in lock */
status = SC_ProcStartCommand(state, SC_RA_RAM_PROC_LOCKTRACK, SC_RA_RAM_SW_EVENT_RUN_NMASK__M, SC_RA_RAM_LOCKTRACK_MIN);
if (status < 0)
break;
status = StartOC(state);
if (status < 0)
break;
if (state->operation_mode != OM_Default) {
status = StartDiversity(state);
if (status < 0)
break;
}
state->drxd_state = DRXD_STARTED;
} while (0);
return status;
}
static int CDRXD(struct drxd_state *state, u32 IntermediateFrequency)
{
u32 ulRfAgcOutputLevel = 0xffffffff;
u32 ulRfAgcSettleLevel = 528; /* Optimum value for MT2060 */
u32 ulRfAgcMinLevel = 0; /* Currently unused */
u32 ulRfAgcMaxLevel = DRXD_FE_CTRL_MAX; /* Currently unused */
u32 ulRfAgcSpeed = 0; /* Currently unused */
u32 ulRfAgcMode = 0; /*2; Off */
u32 ulRfAgcR1 = 820;
u32 ulRfAgcR2 = 2200;
u32 ulRfAgcR3 = 150;
u32 ulIfAgcMode = 0; /* Auto */
u32 ulIfAgcOutputLevel = 0xffffffff;
u32 ulIfAgcSettleLevel = 0xffffffff;
u32 ulIfAgcMinLevel = 0xffffffff;
u32 ulIfAgcMaxLevel = 0xffffffff;
u32 ulIfAgcSpeed = 0xffffffff;
u32 ulIfAgcR1 = 820;
u32 ulIfAgcR2 = 2200;
u32 ulIfAgcR3 = 150;
u32 ulClock = state->config.clock;
u32 ulSerialMode = 0;
u32 ulEcOcRegOcModeLop = 4; /* Dynamic DTO source */
u32 ulHiI2cDelay = HI_I2C_DELAY;
u32 ulHiI2cBridgeDelay = HI_I2C_BRIDGE_DELAY;
u32 ulHiI2cPatch = 0;
u32 ulEnvironment = APPENV_PORTABLE;
u32 ulEnvironmentDiversity = APPENV_MOBILE;
u32 ulIFFilter = IFFILTER_SAW;
state->if_agc_cfg.ctrlMode = AGC_CTRL_AUTO;
state->if_agc_cfg.outputLevel = 0;
state->if_agc_cfg.settleLevel = 140;
state->if_agc_cfg.minOutputLevel = 0;
state->if_agc_cfg.maxOutputLevel = 1023;
state->if_agc_cfg.speed = 904;
if (ulIfAgcMode == 1 && ulIfAgcOutputLevel <= DRXD_FE_CTRL_MAX) {
state->if_agc_cfg.ctrlMode = AGC_CTRL_USER;
state->if_agc_cfg.outputLevel = (u16) (ulIfAgcOutputLevel);
}
if (ulIfAgcMode == 0 &&
ulIfAgcSettleLevel <= DRXD_FE_CTRL_MAX &&
ulIfAgcMinLevel <= DRXD_FE_CTRL_MAX &&
ulIfAgcMaxLevel <= DRXD_FE_CTRL_MAX &&
ulIfAgcSpeed <= DRXD_FE_CTRL_MAX) {
state->if_agc_cfg.ctrlMode = AGC_CTRL_AUTO;
state->if_agc_cfg.settleLevel = (u16) (ulIfAgcSettleLevel);
state->if_agc_cfg.minOutputLevel = (u16) (ulIfAgcMinLevel);
state->if_agc_cfg.maxOutputLevel = (u16) (ulIfAgcMaxLevel);
state->if_agc_cfg.speed = (u16) (ulIfAgcSpeed);
}
state->if_agc_cfg.R1 = (u16) (ulIfAgcR1);
state->if_agc_cfg.R2 = (u16) (ulIfAgcR2);
state->if_agc_cfg.R3 = (u16) (ulIfAgcR3);
state->rf_agc_cfg.R1 = (u16) (ulRfAgcR1);
state->rf_agc_cfg.R2 = (u16) (ulRfAgcR2);
state->rf_agc_cfg.R3 = (u16) (ulRfAgcR3);
state->rf_agc_cfg.ctrlMode = AGC_CTRL_AUTO;
/* rest of the RFAgcCfg structure currently unused */
if (ulRfAgcMode == 1 && ulRfAgcOutputLevel <= DRXD_FE_CTRL_MAX) {
state->rf_agc_cfg.ctrlMode = AGC_CTRL_USER;
state->rf_agc_cfg.outputLevel = (u16) (ulRfAgcOutputLevel);
}
if (ulRfAgcMode == 0 &&
ulRfAgcSettleLevel <= DRXD_FE_CTRL_MAX &&
ulRfAgcMinLevel <= DRXD_FE_CTRL_MAX &&
ulRfAgcMaxLevel <= DRXD_FE_CTRL_MAX &&
ulRfAgcSpeed <= DRXD_FE_CTRL_MAX) {
state->rf_agc_cfg.ctrlMode = AGC_CTRL_AUTO;
state->rf_agc_cfg.settleLevel = (u16) (ulRfAgcSettleLevel);
state->rf_agc_cfg.minOutputLevel = (u16) (ulRfAgcMinLevel);
state->rf_agc_cfg.maxOutputLevel = (u16) (ulRfAgcMaxLevel);
state->rf_agc_cfg.speed = (u16) (ulRfAgcSpeed);
}
if (ulRfAgcMode == 2)
state->rf_agc_cfg.ctrlMode = AGC_CTRL_OFF;
if (ulEnvironment <= 2)
state->app_env_default = (enum app_env)
(ulEnvironment);
if (ulEnvironmentDiversity <= 2)
state->app_env_diversity = (enum app_env)
(ulEnvironmentDiversity);
if (ulIFFilter == IFFILTER_DISCRETE) {
/* discrete filter */
state->noise_cal.cpOpt = 0;
state->noise_cal.cpNexpOfs = 40;
state->noise_cal.tdCal2k = -40;
state->noise_cal.tdCal8k = -24;
} else {
/* SAW filter */
state->noise_cal.cpOpt = 1;
state->noise_cal.cpNexpOfs = 0;
state->noise_cal.tdCal2k = -21;
state->noise_cal.tdCal8k = -24;
}
state->m_EcOcRegOcModeLop = (u16) (ulEcOcRegOcModeLop);
state->chip_adr = (state->config.demod_address << 1) | 1;
switch (ulHiI2cPatch) {
case 1:
state->m_HiI2cPatch = DRXD_HiI2cPatch_1;
break;
case 3:
state->m_HiI2cPatch = DRXD_HiI2cPatch_3;
break;
default:
state->m_HiI2cPatch = NULL;
}
/* modify tuner and clock attributes */
state->intermediate_freq = (u16) (IntermediateFrequency / 1000);
/* expected system clock frequency in kHz */
state->expected_sys_clock_freq = 48000;
/* real system clock frequency in kHz */
state->sys_clock_freq = 48000;
state->osc_clock_freq = (u16) ulClock;
state->osc_clock_deviation = 0;
state->cscd_state = CSCD_INIT;
state->drxd_state = DRXD_UNINITIALIZED;
state->PGA = 0;
state->type_A = 0;
state->tuner_mirrors = 0;
/* modify MPEG output attributes */
state->insert_rs_byte = state->config.insert_rs_byte;
state->enable_parallel = (ulSerialMode != 1);
/* Timing div, 250ns/Psys */
/* Timing div, = ( delay (nano seconds) * sysclk (kHz) )/ 1000 */
state->hi_cfg_timing_div = (u16) ((state->sys_clock_freq / 1000) *
ulHiI2cDelay) / 1000;
/* Bridge delay, uses oscilator clock */
/* Delay = ( delay (nano seconds) * oscclk (kHz) )/ 1000 */
state->hi_cfg_bridge_delay = (u16) ((state->osc_clock_freq / 1000) *
ulHiI2cBridgeDelay) / 1000;
state->m_FeAgRegAgPwd = DRXD_DEF_AG_PWD_CONSUMER;
/* state->m_FeAgRegAgPwd = DRXD_DEF_AG_PWD_PRO; */
state->m_FeAgRegAgAgcSio = DRXD_DEF_AG_AGC_SIO;
return 0;
}
static int DRXD_init(struct drxd_state *state, const u8 *fw, u32 fw_size)
{
int status = 0;
u32 driverVersion;
if (state->init_done)
return 0;
CDRXD(state, state->config.IF ? state->config.IF : 36000000);
do {
state->operation_mode = OM_Default;
status = SetDeviceTypeId(state);
if (status < 0)
break;
/* Apply I2c address patch to B1 */
if (!state->type_A && state->m_HiI2cPatch) {
status = WriteTable(state, state->m_HiI2cPatch);
if (status < 0)
break;
}
if (state->type_A) {
/* HI firmware patch for UIO readout,
avoid clearing of result register */
status = Write16(state, 0x43012D, 0x047f, 0);
if (status < 0)
break;
}
status = HI_ResetCommand(state);
if (status < 0)
break;
status = StopAllProcessors(state);
if (status < 0)
break;
status = InitCC(state);
if (status < 0)
break;
state->osc_clock_deviation = 0;
if (state->config.osc_deviation)
state->osc_clock_deviation =
state->config.osc_deviation(state->priv, 0, 0);
{
/* Handle clock deviation */
s32 devB;
s32 devA = (s32) (state->osc_clock_deviation) *
(s32) (state->expected_sys_clock_freq);
/* deviation in kHz */
s32 deviation = (devA / (1000000L));
/* rounding, signed */
if (devA > 0)
devB = (2);
else
devB = (-2);
if ((devB * (devA % 1000000L) > 1000000L)) {
/* add +1 or -1 */
deviation += (devB / 2);
}
state->sys_clock_freq =
(u16) ((state->expected_sys_clock_freq) +
deviation);
}
status = InitHI(state);
if (status < 0)
break;
status = InitAtomicRead(state);
if (status < 0)
break;
status = EnableAndResetMB(state);
if (status < 0)
break;
if (state->type_A) {
status = ResetCEFR(state);
if (status < 0)
break;
}
if (fw) {
status = DownloadMicrocode(state, fw, fw_size);
if (status < 0)
break;
} else {
status = DownloadMicrocode(state, state->microcode, state->microcode_length);
if (status < 0)
break;
}
if (state->PGA) {
state->m_FeAgRegAgPwd = DRXD_DEF_AG_PWD_PRO;
SetCfgPga(state, 0); /* PGA = 0 dB */
} else {
state->m_FeAgRegAgPwd = DRXD_DEF_AG_PWD_CONSUMER;
}
state->m_FeAgRegAgAgcSio = DRXD_DEF_AG_AGC_SIO;
status = InitFE(state);
if (status < 0)
break;
status = InitFT(state);
if (status < 0)
break;
status = InitCP(state);
if (status < 0)
break;
status = InitCE(state);
if (status < 0)
break;
status = InitEQ(state);
if (status < 0)
break;
status = InitEC(state);
if (status < 0)
break;
status = InitSC(state);
if (status < 0)
break;
status = SetCfgIfAgc(state, &state->if_agc_cfg);
if (status < 0)
break;
status = SetCfgRfAgc(state, &state->rf_agc_cfg);
if (status < 0)
break;
state->cscd_state = CSCD_INIT;
status = Write16(state, SC_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
status = Write16(state, LC_COMM_EXEC__A, SC_COMM_EXEC_CTL_STOP, 0);
if (status < 0)
break;
driverVersion = (((VERSION_MAJOR / 10) << 4) +
(VERSION_MAJOR % 10)) << 24;
driverVersion += (((VERSION_MINOR / 10) << 4) +
(VERSION_MINOR % 10)) << 16;
driverVersion += ((VERSION_PATCH / 1000) << 12) +
((VERSION_PATCH / 100) << 8) +
((VERSION_PATCH / 10) << 4) + (VERSION_PATCH % 10);
status = Write32(state, SC_RA_RAM_DRIVER_VERSION__AX, driverVersion, 0);
if (status < 0)
break;
status = StopOC(state);
if (status < 0)
break;
state->drxd_state = DRXD_STOPPED;
state->init_done = 1;
status = 0;
} while (0);
return status;
}
static int DRXD_status(struct drxd_state *state, u32 *pLockStatus)
{
DRX_GetLockStatus(state, pLockStatus);
/*if (*pLockStatus&DRX_LOCK_MPEG) */
if (*pLockStatus & DRX_LOCK_FEC) {
ConfigureMPEGOutput(state, 1);
/* Get status again, in case we have MPEG lock now */
/*DRX_GetLockStatus(state, pLockStatus); */
}
return 0;
}
/****************************************************************************/
/****************************************************************************/
/****************************************************************************/
static int drxd_read_signal_strength(struct dvb_frontend *fe, u16 * strength)
{
struct drxd_state *state = fe->demodulator_priv;
u32 value;
int res;
res = ReadIFAgc(state, &value);
if (res < 0)
*strength = 0;
else
*strength = 0xffff - (value << 4);
return 0;
}
static int drxd_read_status(struct dvb_frontend *fe, enum fe_status *status)
{
struct drxd_state *state = fe->demodulator_priv;
u32 lock;
DRXD_status(state, &lock);
*status = 0;
/* No MPEG lock in V255 firmware, bug ? */
#if 1
if (lock & DRX_LOCK_MPEG)
*status |= FE_HAS_LOCK;
#else
if (lock & DRX_LOCK_FEC)
*status |= FE_HAS_LOCK;
#endif
if (lock & DRX_LOCK_FEC)
*status |= FE_HAS_VITERBI | FE_HAS_SYNC;
if (lock & DRX_LOCK_DEMOD)
*status |= FE_HAS_CARRIER | FE_HAS_SIGNAL;
return 0;
}
static int drxd_init(struct dvb_frontend *fe)
{
struct drxd_state *state = fe->demodulator_priv;
return DRXD_init(state, NULL, 0);
}
static int drxd_config_i2c(struct dvb_frontend *fe, int onoff)
{
struct drxd_state *state = fe->demodulator_priv;
if (state->config.disable_i2c_gate_ctrl == 1)
return 0;
return DRX_ConfigureI2CBridge(state, onoff);
}
static int drxd_get_tune_settings(struct dvb_frontend *fe,
struct dvb_frontend_tune_settings *sets)
{
sets->min_delay_ms = 10000;
sets->max_drift = 0;
sets->step_size = 0;
return 0;
}
static int drxd_read_ber(struct dvb_frontend *fe, u32 * ber)
{
*ber = 0;
return 0;
}
static int drxd_read_snr(struct dvb_frontend *fe, u16 * snr)
{
*snr = 0;
return 0;
}
static int drxd_read_ucblocks(struct dvb_frontend *fe, u32 * ucblocks)
{
*ucblocks = 0;
return 0;
}
static int drxd_sleep(struct dvb_frontend *fe)
{
struct drxd_state *state = fe->demodulator_priv;
ConfigureMPEGOutput(state, 0);
return 0;
}
static int drxd_i2c_gate_ctrl(struct dvb_frontend *fe, int enable)
{
return drxd_config_i2c(fe, enable);
}
static int drxd_set_frontend(struct dvb_frontend *fe)
{
struct dtv_frontend_properties *p = &fe->dtv_property_cache;
struct drxd_state *state = fe->demodulator_priv;
s32 off = 0;
state->props = *p;
DRX_Stop(state);
if (fe->ops.tuner_ops.set_params) {
fe->ops.tuner_ops.set_params(fe);
if (fe->ops.i2c_gate_ctrl)
fe->ops.i2c_gate_ctrl(fe, 0);
}
msleep(200);
return DRX_Start(state, off);
}
static void drxd_release(struct dvb_frontend *fe)
{
struct drxd_state *state = fe->demodulator_priv;
kfree(state);
}
static const struct dvb_frontend_ops drxd_ops = {
.delsys = { SYS_DVBT},
.info = {
.name = "Micronas DRXD DVB-T",
.frequency_min_hz = 47125 * kHz,
.frequency_max_hz = 855250 * kHz,
.frequency_stepsize_hz = 166667,
.caps = FE_CAN_FEC_1_2 | FE_CAN_FEC_2_3 |
FE_CAN_FEC_3_4 | FE_CAN_FEC_5_6 | FE_CAN_FEC_7_8 |
FE_CAN_FEC_AUTO |
FE_CAN_QAM_16 | FE_CAN_QAM_64 |
FE_CAN_QAM_AUTO |
FE_CAN_TRANSMISSION_MODE_AUTO |
FE_CAN_GUARD_INTERVAL_AUTO |
FE_CAN_HIERARCHY_AUTO | FE_CAN_RECOVER | FE_CAN_MUTE_TS},
.release = drxd_release,
.init = drxd_init,
.sleep = drxd_sleep,
.i2c_gate_ctrl = drxd_i2c_gate_ctrl,
.set_frontend = drxd_set_frontend,
.get_tune_settings = drxd_get_tune_settings,
.read_status = drxd_read_status,
.read_ber = drxd_read_ber,
.read_signal_strength = drxd_read_signal_strength,
.read_snr = drxd_read_snr,
.read_ucblocks = drxd_read_ucblocks,
};
struct dvb_frontend *drxd_attach(const struct drxd_config *config,
void *priv, struct i2c_adapter *i2c,
struct device *dev)
{
struct drxd_state *state = NULL;
state = kzalloc(sizeof(*state), GFP_KERNEL);
if (!state)
return NULL;
state->ops = drxd_ops;
state->dev = dev;
state->config = *config;
state->i2c = i2c;
state->priv = priv;
mutex_init(&state->mutex);
if (Read16(state, 0, NULL, 0) < 0)
goto error;
state->frontend.ops = drxd_ops;
state->frontend.demodulator_priv = state;
ConfigureMPEGOutput(state, 0);
/* add few initialization to allow gate control */
CDRXD(state, state->config.IF ? state->config.IF : 36000000);
InitHI(state);
return &state->frontend;
error:
printk(KERN_ERR "drxd: not found\n");
kfree(state);
return NULL;
}
EXPORT_SYMBOL(drxd_attach);
MODULE_DESCRIPTION("DRXD driver");
MODULE_AUTHOR("Micronas");
MODULE_LICENSE("GPL");